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+The Project Gutenberg EBook of Outlines of the Earth's History, by 
+Nathaniel Southgate Shaler
+
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever.  You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at www.gutenberg.org
+
+
+Title: Outlines of the Earth's History
+       A Popular Study in Physiography
+
+Author: Nathaniel Southgate Shaler
+
+Release Date: June 12, 2006 [EBook #18562]
+
+Language: English
+
+Character set encoding: ISO-8859-1
+
+*** START OF THIS PROJECT GUTENBERG EBOOK OUTLINES OF THE EARTH'S HISTORY ***
+
+
+
+
+Produced by Brendan Lane, Riikka Talonpoika, Jeroen van
+Luin and the Online Distributed Proofreading Team at
+http://www.pgdp.net
+
+
+
+
+
+[Illustration: _Dunes at Ipswich Light, Massachusetts. Note the
+effect of bushes in arresting the movement of the wind-blown sand._]
+
+
+
+
+                           OUTLINES OF THE
+                           EARTH'S HISTORY
+
+
+                           A POPULAR STUDY
+                           IN PHYSIOGRAPHY
+
+                                 BY
+
+                      NATHANIEL SOUTHGATE SHALER
+
+               PROFESSOR OF GEOLOGY IN HARVARD UNIVERSITY
+                   DEAN OF LAWRENCE SCIENTIFIC SCHOOL
+
+                        ILLUSTRATED WITH INDEX
+
+                          NEW YORK AND LONDON
+                        D. APPLETON AND COMPANY
+
+                              1898, 1910
+
+
+
+
+
+                               PREFACE.
+
+
+The object of this book is to provide the beginner in the study of the
+earth's history with a general account of those actions which can be
+readily understood and which will afford him clear understandings as
+to the nature of the processes which have made this and other
+celestial spheres. It has been the writer's purpose to select those
+series of facts which serve to show the continuous operations of
+energy, so that the reader might be helped to a truer conception of
+the nature of this sphere than he can obtain from ordinary text-books.
+
+In the usual method of presenting the elements of the earth's history
+the facts are set forth in a manner which leads the student to
+conceive that history as in a way completed. The natural prepossession
+to the effect that the visible universe represents something done,
+rather than something endlessly doing, is thus re-enforced, with the
+result that one may fail to gain the largest and most educative
+impression which physical science can afford him in the sense of the
+swift and unending procession of events.
+
+It is well known to all who are acquainted with the history of geology
+that the static conception of the earth--the idea that its existing
+condition is the finished product of forces no longer in action--led
+to prejudices which have long retarded, and indeed still retard, the
+progress of that science. This fact indicates that at the outset of a
+student's work in this field he should be guarded against such
+misconceptions. The only way to attain the end is by bringing to the
+understanding of the beginner a clear idea of successions of events
+which are caused by the forces operating in and on this sphere. Of all
+the chapters of this great story, that which relates to the history of
+the work done by the heat of the sun is the most interesting and
+awakening. Therefore an effort has been made to present the great
+successive steps by which the solar energy acts in the processes of
+the air and the waters.
+
+The interest of the beginner in geology is sure to be aroused when he
+comes to see how very far the history of the earth has influenced the
+fate of men. Therefore the aim has been, where possible, to show the
+ways in which geological processes and results are related to
+ourselves; how, in a word, this earth has been the well-appointed
+nursery of our kind.
+
+All those who are engaged in teaching elementary science learn the
+need of limiting the story they have to tell to those truths which can
+be easily understood by beginners. It is sometimes best, as in stating
+such difficult matters as those concerning the tides, to give
+explanations which are far from complete, and which, as to their mode
+of presentation, would be open to criticism were it not for the fact
+that any more elaborate statements would most likely be
+incomprehensible to the novice, thus defeating the teacher's aim.
+
+It will be observed that no account is here given of the geological
+ages or of the successions of organic life. Chapters on these subjects
+were prepared, but were omitted for the reason that they made the
+story too long, and also because they carried the reader into a field
+of much greater difficulty than that which is found in the physical
+history of the earth.
+
+                                                  N.S.S.
+_March, 1898._
+
+
+
+
+                            CONTENTS.
+
+
+    CHAPTER                                                   PAGE
+
+       I.--INTRODUCTION TO THE STUDY OF NATURE                   1
+      II.--WAYS AND MEANS OF STUDYING NATURE                     9
+     III.--THE STELLAR REALM                                    31
+      IV.--THE EARTH                                            81
+       V.--THE ATMOSPHERE                                       97
+      VI.--GLACIERS                                            207
+     VII.--THE WORK OF UNDERGROUND WATER                       250
+    VIII.--THE SOIL                                            313
+      IX.--THE ROCKS AND THEIR ORDER                           349
+
+
+
+
+                 LIST OF FULL-PAGE ILLUSTRATIONS.
+
+                                                        FACING PAGE
+
+    Dunes at Ipswich Light, Massachusetts            _Frontispiece_
+    Seal Rocks near San Francisco, California                   33
+    Lava stream, in Hawaiian Islands, flowing into the sea      72
+    Waterfall near Gadsden, Alabama                             90
+    South shore, Martha's Vineyard, Massachusetts              121
+    Pocket Creek, Cape Ann, Massachusetts                      163
+    Muir Glacier, Alaska                                       207
+    Front of Muir Glacier                                      240
+    Mount Ætna, seen from near Catania                         201
+    Mountain gorge, Himalayas, India                           330
+
+
+
+
+
+                   OUTLINES OF THE EARTH'S HISTORY.
+
+
+                             CHAPTER I.
+
+               AN INTRODUCTION TO THE STUDY OF NATURE.
+
+
+The object of this book is to give the student who is about to enter
+on the study of natural science some general idea as to the conditions
+of the natural realm. As this field of inquiry is vast, it will be
+possible only to give the merest outline of its subject-matter, noting
+those features alone which are of surpassing interest, which are
+demanded for a large understanding of man's place in this world, or
+which pertain to his duties in life.
+
+In entering on any field of inquiry, it is most desirable that the
+student should obtain some idea as to the ways in which men have been
+led to the knowledge which they possess concerning the world about
+them. Therefore it will be well briefly to sketch the steps by which
+natural science has come to be what it is. By so doing we shall
+perceive how much we owe to the students of other generations; and by
+noting the difficulties which they encountered, and how they avoided
+them, we shall more easily find our own way to knowledge.
+
+The primitive savages, who were the ancestors of all men, however
+civilized they may be, were students of Nature. The remnants of these
+lowly people who were left in different parts of the world show us
+that man was not long in existence before he began to devise some
+explanation concerning the course of events in the outer world.
+Seeing the sun rise and set, the changes of the moon, the alternation
+of the seasons, the incessant movement of the streams and sea, and the
+other more or less orderly successions of events, our primitive
+forefathers were driven to invent some explanation of them. This,
+independently, and in many different times and places, they did in a
+simple and natural way by supposing that the world was controlled by a
+host of intelligent beings, each of which had some part in ordering
+material things. Sometimes these invisible powers were believed to be
+the spirits of great chieftains, who were active when on earth, and
+who after death continued to exercise their power in the larger realms
+of Nature. Again, and perhaps more commonly, these movements of Nature
+were supposed to be due to the action of great though invisible
+beasts, much like those which the savage found about him. Thus among
+our North American Indians the winds are explained by the supposition
+that the air is fanned by the wings of a great unseen bird, whose duty
+it is to set the atmosphere into motion. That no one has ever seen the
+bird doing the work, or that the task is too great for any conceivable
+bird, is to the simple, uncultivated man no objection to this view. It
+is long, indeed, before education brings men to the point where they
+can criticise their first explanations of Nature.
+
+As men in their advance come to see how much nobler are their own
+natures than those of the lower animals, they gradually put aside the
+explanation of events by the actions of beasts, and account for the
+order of the world by the supposition that each and every important
+detail is controlled by some immortal creature essentially like a man,
+though much more powerful than those of their own kind. This stage of
+understanding is perhaps best shown by the mythology of the Greeks,
+where there was a great god over all, very powerful but not
+omnipotent; and beneath him, in endless successions of command,
+subordinate powers, each with a less range of duties and capacities
+than those of higher estate, until at the bottom of the system there
+were minor deities and demigods charged with the management of the
+trees, the flowers, and the springs--creatures differing little from
+man, except that they were immortal, and generally invisible, though
+they, like all the other deities, might at their will display
+themselves to the human beings over whom they watched, and whose path
+in life they guided.
+
+Among only one people do we find that the process of advance led
+beyond this early and simple method of accounting for the processes of
+Nature, bringing men to an understanding such as we now possess. This
+great task was accomplished by the Greeks alone. About twenty-five
+hundred years ago the philosophers of Greece began to perceive that
+the early notion as to the guidance of the world by creatures
+essentially like men could not be accepted, and must be replaced by
+some other view which would more effectively account for the facts.
+This end they attained by steps which can not well be related here,
+but which led them to suppose separate powers behind each of the
+natural series--powers having no relation to the qualities of mankind,
+but ever acting to a definite end. Thus Plato, who represents most
+clearly this advance in the interpretation of facts, imagined that
+each particular kind of plant or animal had its shape inevitably
+determined by something which he termed an idea, a shape-giving power
+which existed before the object was created, and which would remain
+after it had been destroyed, ever ready again to bring matter to the
+particular form. From this stage of understanding it was but a short
+step to the modern view of natural law. This last important advance
+was made by the great philosopher Aristotle, who, though he died about
+twenty-two hundred years ago, deserves to be accounted the first and
+in many ways the greatest of the ancient men of science who were
+informed with the modern spirit.
+
+With Aristotle, as with all his intellectual successors, the
+operations of Nature were conceived as to be accounted for by the
+action of forces which we commonly designate as natural laws, of which
+perhaps the most familiar and universal is that of gravitation, which
+impels all bodies to move toward each other with a degree of intensity
+which is measured by their weight and the distance by which they are
+separated.
+
+For many centuries students used the term law in somewhat the same way
+as the more philosophical believers in polytheism spoke of their gods,
+or as Plato of the ideas which he conceived to control Nature. We see
+by this instance how hard it is to get rid of old ways of thinking.
+Even when the new have been adopted we very often find that something
+of the ancient and discarded notions cling in our phrases. The more
+advanced of our modern philosophers are clear in their mind that all
+we know as to the order of Nature is that, given certain conditions,
+certain consequences inevitably follow.
+
+Although the limitations which modern men of science perceive to be
+put upon their labours may seem at first sight calculated to confine
+our understanding within a narrow field of things which can be seen,
+or in some way distinctly proved to exist, the effect of this
+limitation has been to make science what it is--a realm of things
+known as distinct from things which may be imagined. All the
+difference between ancient science and modern consists in the fact
+that in modern science inquirers demand a businesslike method in the
+interpretation of Nature. Among the Greeks the philosopher who taught
+explanations of any feature in the material world which interested him
+was content if he could imagine some way which would account for the
+facts. It is the modern custom now to term the supposition of an
+explanation a _working hypothesis_, and only to give it the name of
+theory after a very careful search has shown that all the facts which
+can be gathered are in accordance with the view. Thus when Newton made
+his great suggestion concerning the law of gravitation, which was to
+the effect that all bodies attracted each other in proportion to
+their masses, and inversely as the square of their distance from each
+other, he did not rest content, as the old Greeks would have done,
+with the probable truth of the explanation, but carefully explored the
+movements of the planets and satellites of the solar system to see if
+the facts accorded with the hypothesis. Even the perfect
+correspondence which he found did not entirely content inquirers, and
+in this century very important experiments have been made which have
+served to show that a ball suspended in front of a precipice will be
+attracted toward the steep, and that even a mass of lead some tons in
+weight will attract toward itself a small body suspended in the manner
+of a pendulum.
+
+It is this incessant revision of the facts, in order to see if they
+accord with the assumed rule or law, which has given modern science
+the sound footing that it lacked in earlier days, and which has
+permitted our learning to go on step by step in a safe way up the
+heights to which it has climbed. All explanations of Nature begin with
+the work of the imagination. In common phrase, they all are guesses
+which have at first but little value, and only attain importance in
+proportion as they are verified by long-continued criticism, which has
+for its object to see whether the facts accord with the theory. It is
+in this effort to secure proof that modern science has gathered the
+enormous store of well-ascertained facts which constitutes its true
+wealth, and which distinguishes it from the earlier imaginative and to
+a great extent unproved views.
+
+In the original state of learning, natural science was confounded with
+political and social tradition, with the precepts of duty which
+constitute the law of the people, as well as with their religion, the
+whole being in the possession of the priests or wise men. So long as
+natural action was supposed to be in the immediate control of numerous
+gods and demigods, so long, in a word, as the explanation of Nature
+was what we term polytheistic, this association of science with other
+forms of learning was not only natural but inevitable. Gradually,
+however, as the conception of natural law replaced the earlier idea as
+to the intervention of a spirit, science departed from other forms of
+lore and came to possess a field to itself. At first it was one body
+of learning. The naturalists of Aristotle's time, and from his day
+down to near our own, generally concerned themselves with the whole
+field of Nature. For a time it was possible for any one able and
+laborious man to know all which had been ascertained concerning
+astronomy, chemistry, geology, as well as the facts relating to living
+beings. The more, however, as observation accumulated, and the store
+of facts increased, it became difficult for any one man to know the
+whole. Hence it has come about that in our own time natural learning
+is divided into many distinct provinces, each of which demands a
+lifetime of labour from those who would know what has already been
+done in the field, and what it is now important to do in the way of
+new inquiries.
+
+The large divisions which naturalists have usually made of their tasks
+rest in the main on the natural partitions which we may readily
+observe in the phenomenal world. First of all comes astronomy,
+including the phenomena exhibited in the heavens, beyond the limits of
+the earth's atmosphere. Second, geology, which takes account of all
+those actions which in process of time have been developed in our own
+sphere. Third, physics, which is concerned with the laws of energy, or
+those conditions which affect the motion of bodies, and the changes
+which are impressed upon them by the different natural forces. Fourth,
+chemistry, which seeks to interpret the principles which determine the
+combination of atoms and the molecules which are built of them under
+the influence of the chemical affinities. Fifth, biology, or the laws
+of life, a study which pertains to the forms and structures of animals
+and plants, and their wonderful successions in the history of the
+world. Sixth, mathematics, or the science of space and number, that
+deals with the principles which underlie the order of Nature as
+expressed at once in the human understanding and in the material
+universe. By its use men were made able to calculate, as in
+arithmetic, the problems which concern their ordinary business, as
+well as to compute the movements of the celestial bodies, and a host
+of actions which take place on the earth that would be inexplicable
+except by the aid of this science. Last of all among the primary
+sciences we may name that of psychology, which takes account of mental
+operations among man and his lower kindred, the animals.
+
+In addition to the seven sciences above mentioned, which rest in a
+great measure on the natural divisions of phenomena, there are many,
+indeed, indefinitely numerous, subdivisions which have been made to
+suit the convenience of students. Thus astronomy is often separated
+into physical and mathematical divisions, which take account either of
+the physical phenomena exhibited by the heavenly bodies or of their
+motions. In geology there are half a dozen divisions relating to
+particular branches of that subject. In the realm of organic life, in
+chemistry, and in physics there are many parts of these sciences which
+have received particular names.
+
+It must not be supposed that these sciences have the independence of
+each other which their separate names would imply. In fact, the
+student of each, however, far he may succeed in separating his field
+from that of the other naturalists, as we may fitly term all students
+of Nature, is compelled from time to time to call in the aid of his
+brethren who cultivate other branches of learning. The modern
+astronomer needs to know much of chemistry, or else he can not
+understand many of his observations on the sun. The geologists have to
+share their work with the student of animal and vegetable life, with
+the physicists; they must, moreover, know something of the celestial
+spheres in order to interpret the history of the earth. In fact, day
+by day, with the advance of learning, we come more clearly to
+perceive that all the processes of Nature are in a way related to each
+other, and that in proportion as we understand any part of the great
+mechanism, we are forced in a manner to comprehend the whole. In other
+words, we are coming to understand that these divisions of the field
+of science depend upon the limitations of our knowledge, and not upon
+the order of Nature itself. For the purposes of education it is
+important that every one should know something of the great truths
+which each science has disclosed. No mortal man can compass the whole
+realm of this knowledge, but every one can gain some idea of the
+larger truths which may help him to understand the beauty and grandeur
+of the sphere in which he dwells, which will enable him the better to
+meet the ordinary duties of life, that in almost all cases are related
+to the facts of the world about us. It has been of late the custom to
+term this body of general knowledge which takes account of the more
+evident facts and important series of terrestrial actions
+physiography, or, as the term implies, a description of Nature, with
+the understanding that the knowledge chosen for the account is that
+which most intimately concerns the student who seeks information that
+is at once general and important. Therefore, in this book the effort
+is made first to give an account as to the ways and means which have
+led to our understanding of scientific problems, the methods by which
+each person may make himself an inquirer, and the outline of the
+knowledge that has been gathered since men first began to observe and
+criticise the revelations the universe may afford them.
+
+
+
+
+                             CHAPTER II.
+
+                  WAYS AND MEANS OF STUDYING NATURE.
+
+
+It is desirable that the student of Nature keep well in mind the means
+whereby he is able to perceive what goes on in the world about him. He
+should understand something as to the nature of his senses, and the
+extent to which these capacities enable him to discern the operations
+of Nature. Man, in common with his lower kindred, is, by the mechanism
+of the body, provided with five somewhat different ways by which he
+may learn something of the things about him. The simplest of these
+capacities is that of touch, a faculty that is common to the general
+surface of the body, and which informs us when the surface is affected
+by contact with some external object. It also enables us to discern
+differences of temperature. Next is the sense of taste, which is
+limited to the mouth and the parts about it. This sense is in a way
+related to that of touch, for the reason that it depends on the
+contact of our body with material things. Third is the sense of smell,
+so closely related to that of taste that it is difficult to draw the
+line between the two. Yet through the apparatus of the nose we can
+perceive the microscopically small parts of matter borne to us through
+the air, which could not be appreciated by the nerves of the mouth.
+Fourth in order of scope comes the hearing, which gives us an account
+of those waves of matter that we understand as sound. This power is
+much more far ranging than those before noted; in some cases, as in
+that of the volcanic explosions from the island of Krakatoa, in the
+eruption of 1883, the convulsions were audible at the distance of
+more than a thousand miles away. The greater cannon of modern days may
+be heard at the distance of more than a hundred miles, so that while
+the sense of touch, taste, and smell demand contact with the bodies
+which we appreciate, hearing gives us information concerning objects
+at a considerable distance. Last and highest of the senses, vastly the
+most important in all that relates to our understanding of Nature, is
+sight, or the capacity which enables us to appreciate the movement of
+those very small waves of ether which constitute light. The eminent
+peculiarity of sight is that it may give us information concerning
+things which are inconceivably far away; it enables us to discern the
+light of suns probably millions of times as remote from us as is the
+centre of our own solar system.
+
+Although much of the pleasure which the world affords us comes through
+the other senses, the basis of almost all our accurate knowledge is
+reported by sight. It is true that what we have observed with our eyes
+may be set forth in words, and thus find its way to the understanding
+through the ears; also that in many instances the sense of touch
+conveys information which extends our perceptions in many important
+ways; but science rests practically on sight, and on the insight that
+comes from the training of the mind which the eyes make possible.
+
+The early inquirers had no resources except those their bodies
+afforded; but man is a tool-making creature, and in very early days he
+began to invent instruments which helped him in inquiry. The earliest
+deliberate study was of the stars. Science began with astronomy, and
+the first instruments which men contrived for the purpose of
+investigation were astronomical. In the beginning of this search the
+stars were studied in order to measure the length of the year, and
+also for the reason that they were supposed in some way to control the
+fate of men. So far as we know, the first pieces of apparatus for this
+purpose were invented in Egypt, perhaps about four thousand years
+before the Christian era. These instruments were of a simple nature,
+for the magnifying glass was not yet contrived, and so the telescope
+was impossible. They consisted of arrangements of straight edges and
+divided circles, so that the observers, by sighting along the
+instruments, could in a rough way determine the changes in distance
+between certain stars, or the height of the sun above the horizon at
+the various seasons of the year. It is likely that each of the great
+pyramids of Egypt was at first used as an observatory, where the
+priests, who had some knowledge of astronomy, found a station for the
+apparatus by which they made the observations that served as a basis
+for casting the horoscope of the king.
+
+In the progress of science and of the mechanical invention attending
+its growth, a great number of inventions have been contrived which
+vastly increase our vision and add inconceivably to the precision it
+may attain. In fact, something like as much skill and labour has been
+given to the development of those inventions which add to our learning
+as to those which serve an immediate economic end. By far the greatest
+of these scientific inventions are those which depend upon the lens.
+By combining shaped bits of glass so as to control the direction in
+which the light waves move through them, naturalists have been able to
+create the telescope, which in effect may bring distant objects some
+thousand times nearer to view than they are to the naked eye; and the
+microscope, which so enlarges minute objects as to make them visible,
+as they were not before. The result has been enormously to increase
+our power of vision when applied to distant or to small objects. In
+fact, for purposes of learning, it is safe to say that those tools
+have altogether changed man's relation to the visible universe. The
+naked eye can see at best in the part of the heavens visible from any
+one point not more than thirty thousand stars. With the telescope
+somewhere near a hundred million are brought within the limits of
+vision. Without the help of the microscope an object a thousandth of
+an inch in diameter appears as a mere point, the existence of which we
+can determine only under favourable circumstances. With that
+instrument the object may reveal an extended and complicated structure
+which it may require a vast labour for the observer fully to explore.
+
+Next in importance to the aid of vision above noted come the
+scientific tools which are used in weighing and measuring. These
+balances and gauges have attained such precision that intervals so
+small as to be quite invisible, and weights as slight as a
+ten-thousandth of a grain, can be accurately measured. From these
+instruments have come all those precise examinations on which the
+accuracy of modern science intimately depends. All these instruments
+of precision are the inventions of modern days. The simplest
+telescopes were made only about two hundred and fifty years ago, and
+the earlier compound microscopes at a yet later date. Accurate
+balances and other forms of gauges of space, as well as good means of
+dividing time, such as our accurate astronomical clocks and
+chronometers, are only about a century old. The instruments have made
+science accurate, and have immensely extended its powers in nearly all
+the fields of inquiry.
+
+Although the most striking modern discoveries are in the field which
+was opened to us by the lens in its manifold applications, it is in
+the chemist's laboratory that we find that branch of science, long
+cultivated, but rapidly advanced only within the last two centuries,
+which has done the most for the needs of man. The ancients guessed
+that the substances which make up the visible world were more
+complicated in their organization than they appear to our vision. They
+even suggested the great truth that matter of all kinds is made up of
+inconceivably small indivisible bits which they and we term atoms. It
+is likely that in the classic days of Greece men began to make simple
+experiments of a chemical nature. A century or two after the time of
+Mohammed, the Arabians of his faith, a people who had acquired Greek
+science from the libraries which their conquests gave them, conducted
+extensive experiments, and named a good many familiar chemical
+products, such as alcohol, which still bears its Arabic name.
+
+These chemical studies were continued in Europe by the alchemists, a
+name also of Arabic origin, a set of inquirers who were to a great
+extent drawn away from scientific studies by vain though unending
+efforts to change the baser metals into gold and silver, as well as to
+find a compound which would make men immortal in the body. By the
+invention of the accurate balance, and by patient weighing of the
+matters which they submitted to experiment, by the invention of
+hypotheses or guesses at truth, which were carefully tested by
+experiment, the majestic science of modern chemistry has come forth
+from the confused and mystical studies of the alchemists. We have
+learned to know that there are seventy or more primitive or apparently
+unchangeable elements which make up the mass of this world, and
+probably constitute all the celestial spheres, and that these elements
+in the form of their separate atoms may group themselves in almost
+inconceivably varied combinations. In the inanimate realm these
+associations, composed of the atoms of the different substances,
+forming what are termed molecules, are generally composed of but few
+units. Thus carbonic-acid gas, as it is commonly called, is made up of
+an aggregation of molecules, each composed of one atom of carbon and
+two of oxygen; water, of two atoms of hydrogen and one of oxygen;
+ordinary iron oxide, of two atoms of iron and three of oxygen. In the
+realm of organic life, however, these combinations become vastly more
+complicated, and with each of them the properties of the substance
+thus produced differ from all others. A distinguished chemist has
+estimated that in one group of chemical compounds, that of carbon, it
+would be possible to make such an array of substances that it would
+require a library of many thousand ordinary volumes to contain their
+names alone.
+
+It is characteristic of chemical science that it takes account of
+actions which are almost entirely invisible. No contrivances have been
+or are likely to be invented which will show the observer what takes
+place when the atoms of any substance depart from their previous
+combination and enter on new arrangements. We only know that under
+certain conditions the old atomic associations break up, and new ones
+are formed. But though the processes are hidden, the results are
+manifest in the changes which are brought about upon the masses of
+material which are subjected to the altering conditions. Gradually the
+chemists of our day are learning to build up in their laboratories
+more and more complicated compounds; already they have succeeded in
+producing many of the materials which of old could only be obtained by
+extracting them from plants. Thus a number of the perfumes of flowers,
+and many of the dye-stuffs which a century ago were extracted from
+vegetables, and were then supposed to be only obtainable in that way,
+are now readily manufactured. In time it seems likely that important
+articles of food, for which we now depend upon the seeds of plants,
+may be directly built up from the mineral kingdom. Thus the result of
+chemical inquiry has been not only to show us much of the vast realm
+of actions which go on in the earth, but to give us control of many of
+these movements so that we may turn them to the needs of man.
+
+Animals and plants were at an early day very naturally the subjects of
+inquiry. The ancients perceived that there were differences of kind
+among these creatures, and even in Aristotle's time the sciences of
+zoölogy and botany had attained the point where there were
+considerable treatises on those subjects. It was not, however, until a
+little more than a century ago that men began accurately to describe
+and classify these species of the organic world. Since the time of
+Linnæus the growth of our knowledge has gone forward with amazing
+swiftness. Within a century we have come to know perhaps a hundred
+times as much concerning these creatures as was learned in all the
+earlier ages. This knowledge is divisible into two main branches: in
+one the inquirers have taken account of the different species, genera,
+families, orders, and classes of living forms with such effect that
+they have shown the existence at the present time of many hundred
+thousand distinct species, the vast assemblage being arranged in a
+classification which shows something as to the relationship which the
+forms bear to each other, and furthermore that the kinds now living
+have not been long in existence, but that at each stage in the history
+of the earth another assemblage of species peopled the waters and the
+lands.
+
+At first naturalists concerned themselves only with the external forms
+of living creatures; but they soon came to perceive that the way in
+which these organisms worked, their physiology, in a word, afforded
+matters for extended inquiry. These researches have developed the
+science of physiology, or the laws of bodily action, on many accounts
+the most modern and extensive of our new acquisitions of natural
+learning. Through these studies we have come to know something of the
+laws or principles by which life is handed on from generation to
+generation, and by which the gradations of structure have been
+advanced from the simple creatures which appear like bits of animated
+jelly to the body and mind of man.
+
+The greatest contribution which modern naturalists have made to
+knowledge concerns the origin of organic species. The students of a
+century ago believed that all these different kinds had been suddenly
+created either through natural law or by the immediate will of God. We
+now know that from the beginning of organic life in the remote past to
+the present day one kind of animal or plant has been in a natural and
+essentially gradual way converted into the species which was to be its
+successor, so that all the vast and complicated assemblage of kinds
+which now exists has been derived by a process of change from the
+forms which in earlier ages dwelt upon this planet. The exact manner
+in which these alterations were produced is not yet determined, but in
+large part it has evidently been brought about by the method indicated
+by Mr. Darwin, through the survival of the fittest individuals in the
+struggle for existence.
+
+Until men came to have a clear conception as to the spherical form of
+the earth, it was impossible for them to begin any intelligent
+inquiries concerning its structure or history. The Greeks knew the
+earth to be a sphere, but this knowledge was lost among the early
+Christian people, and it was not until about four hundred years ago
+that men again came to see that they dwelt upon a globe. On the basis
+of this understanding the science of geology, which had in a way been
+founded by the Greeks, was revived. As this science depends upon the
+knowledge which we have gained of astronomy, physics, chemistry, and
+biology, all of which branches of learning have to be used in
+explaining the history of the earth, the advance which has been made
+has been relatively slow. Geology as a whole is the least perfectly
+organized of all the divisions of learning. A special difficulty
+peculiar to this science has also served to hinder its development.
+All the other branches of learning deal mainly, if not altogether,
+with the conditions of Nature as they now exist. In this alone is it
+necessary at every step to take account of actions which have been
+performed in the remote past.
+
+It is an easy matter for the students of to-day to imagine that the
+earth has long endured; but to our forefathers, who were educated in
+the view that it had been brought from nothingness into existence
+about seven thousand years ago, it was most difficult and for a time
+impossible to believe in its real antiquity. Endeavouring, as they
+naturally did, to account for all the wonderful revolutions, the
+history of which is written in the pages of the great stone book, the
+early geologists supposed this planet to have been the seat of
+frequent and violent changes, each of which revolutionized its shape
+and destroyed its living tenants. It was only very gradually that
+they became convinced that a hundred million years or more have
+elapsed since the dawn of life on the earth, and that in this vast
+period the march of events has been steadfast, the changes taking
+place at about the same rate in which they are now going on. As yet
+this conception as to the history of our sphere has not become the
+general property of the people, but the fact of it is recognised by
+all those who have attentively studied the matter. It is now as well
+ascertained as any of the other truths which science has disclosed to
+us.
+
+It is instructive to note the historic outlines of scientific
+development. The most conspicuous truth which this history discloses
+is that all science has had its origin and almost all its development
+among the peoples belonging to the Aryan race. This body of folk
+appears to have taken on its race characteristics, acquired its
+original language, its modes of action, and the foundations of its
+religion in that part of northern Europe which is about the Baltic
+Sea. Thence the body of this people appear to have wandered toward
+central Asia, where after ages of pastoral life in the high table
+lands and mountains of their country it sent forth branches to India,
+Asia Minor and Greece, to Persia, and to western Europe. It seems ever
+to have been a characteristic of these Aryan peoples that they had an
+extreme love for Nature; moreover, they clearly perceived the need of
+accounting for the things that happened in the world about them. In
+general they inclined to what is called the pantheistic explanation of
+the universe. They believed a supreme God in many different forms to
+be embodied in all the things they saw. Even their own minds and
+bodies they conceived as manifestations of this supreme power. Among
+the Aryans who came to dwell in Europe and along the eastern
+Mediterranean this method of explaining Nature was in time changed to
+one in which humanlike gods were supposed to control the visible and
+invisible worlds. In that marvellous centre of culture which was
+developed among the Greeks this conception of humanlike deities was in
+time replaced by that of natural law, and in their best days the
+Greeks were men of science essentially like those of to-day, except
+that they had not learned by experience how important it was to
+criticise their theories by patiently comparing them with the facts
+which they sought to explain. The last of the important Greek men of
+science, Strabo, who was alive when Christ was born, has left us
+writings which in quality are essentially like many of the able works
+of to-day. But for the interruption in the development of Greek
+learning, natural science would probably have been fifteen hundred
+years ahead of its present stage. This interruption came in two ways.
+In one, through the conquest of Greece and the destruction of its
+intellectual life by the Romans, a people who were singularly
+incapable of appreciating natural science, and who had no other
+interest in it except now and then a vacant and unprofitable curiosity
+as to the processes of the natural world. A second destructive
+influence came through the fact that Christianity, in its energetic
+protest against the sins of the pagan civilization, absolutely
+neglected and in a way despised all forms of science.
+
+The early indifference of Christians to natural learning is partly to
+be explained by the fact that their religion was developed among the
+Hebrews, a people remarkable for their lack of interest in the
+scientific aspects of Nature. To them it was a sufficient explanation
+that one omnipotent God ruled all things at his will, the heavens and
+the earth alike being held in the hollow of his hand.
+
+Finding the centre of its development among the Romans, Christianity
+came mainly into the control of a people who, as we have before
+remarked, had no scientific interest in the natural world. This
+condition prolonged the separation of our faith from science for
+fifteen hundred years after its beginning. In this time the records of
+Greek scientific learning mostly disappeared. The writings of
+Aristotle were preserved in part for the reason that the Church
+adopted many of his views concerning questions in moral philosophy and
+in politics. The rest of Greek learning was, so far as Europe was
+concerned, quite neglected.
+
+A large part of Greek science which has come down to us owes its
+preservation to a very singular incident in the history of learning.
+In the ninth century, after the Arabs had been converted to
+Mohammedanism, and on the basis of that faith had swiftly organized a
+great and cultivated empire, the scholars of that folk became deeply
+interested in the remnants of Greek learning which had survived in the
+monastic and other libraries about the eastern Mediterranean. So
+greatly did they prize these records, which were contemned by the
+Christians, that it was their frequent custom to weigh the old
+manuscripts in payment against the coin of their realm. In astronomy,
+mathematics, chemistry, and geology the Arabian students, building on
+the ancient foundations, made notable and for a time most important
+advances. In the tenth century of our era they seemed fairly in the
+way to do for science what western Europe began five centuries later
+to accomplish. In the fourteenth century the centre of Mohammedan
+strength was transferred from the Arabians to the Turks, from a people
+naturally given to learning to a folk of another race, who despised
+all such culture. Thenceforth in place of the men who had treasured
+and deciphered with infinite pains all the records of earlier
+learning, the followers of Mohammed zealously destroyed all the
+records of the olden days. Some of these records, however, survived
+among the Arabs of Spain, and others were preserved by the Christian
+scholars who dwelt in Byzantium, or Constantinople, and were brought
+into western Europe when that city was captured by the Turks in the
+fifteenth century.
+
+Already the advance of the fine arts in Italy and the general tendency
+toward the study of Nature, such as painting and sculpture indicate,
+had made a beginning, or rather a proper field for a beginning, of
+scientific inquiry. The result was a new interest in Greek learning in
+all its branches, and a very rapid awakening of the scientific spirit.
+At first the Roman Church made no opposition to this new interest
+which developed among its followers, but in the course of a few years,
+animated with the fear that science would lead men to doubt many of
+the dogmas of the Church, it undertook sternly to repress the work of
+all inquirers.
+
+The conflict between those of the Roman faith and the men of science
+continued for above two hundred years. In general, the part which the
+Church took was one of remonstrance, but in a few cases the spirit of
+fanaticism led to the persecution of the men who did not obey its
+mandates and disavow all belief in the new opinions which were deemed
+contrary to the teachings of Scripture. The last instance of such
+oppression occurred in France in the year 1756, when the great Buffon
+was required to recant certain opinions concerning the antiquity of
+the earth which he had published in his work on Natural History. This
+he promptly did, and in almost servile language withdrew all the
+opinions to which the fathers had objected. A like conflict between
+the followers of science and the clerical authorities occurred in
+Protestant countries. Although in no case were the men of science
+physically tortured or executed for their opinions, they were
+nevertheless subjected to great religious and social pressure: they
+were almost as effectively disciplined as were those who fell under
+the ban of the Roman Church.
+
+Some historians have criticised the action of the clerical authorities
+toward science as if the evil which was done had been performed in our
+own day. It should be remembered, however, that in the earlier
+centuries the churches regarded themselves as bound to protect all men
+from the dangers of heresy. For centuries in the early history of
+Christianity the defenders of the faith had been engaged in a
+life-and-death struggle with paganism, the followers of which held all
+that was known of Nature. Quite naturally the priestly class feared
+that the revival of scientific inquiry would bring with it the evils
+from which the world had suffered in pagan times. There is no doubt
+that these persecutions of science were done under what seemed the
+obligations of duty. They may properly be explained particularly by
+men of science as one of the symptoms of development in the day in
+which they were done. It is well for those who harshly criticise the
+relations of the Church to science to remember that in our own
+country, about two centuries ago, among the most enlightened and
+religious people of the time, Quakers were grievously persecuted, and
+witches hanged, all in the most dutiful and God-fearing way. In
+considering these relations of science to our faith, the matter should
+be dealt with in a philosophical way, and with a sense of the
+differences between our own and earlier ages.
+
+To the student of the relations between Christianity and science it
+must appear doubtful whether the criticism or the other consequences
+which the men of science had to meet from the Church was harmful to
+their work. The early naturalists, like the Greeks whom they followed,
+were greatly given to speculations concerning the processes of Nature,
+which, though interesting, were unprofitable. They also showed a
+curious tendency to mingle their scientific speculations with ancient
+and base superstitions. They were often given to the absurdity
+commonly known as the "black art," or witchcraft, and held to the
+preposterous notions of the astrologists. Even the immortal astronomer
+Kepler, who lived in the sixteenth century, was a professional
+astrologer, and still held to the notion that the stars determined the
+destiny of men. Many other of the famous inquirers in those years
+which ushered in modern science believed in witchcraft. Thus for a
+time natural learning was in a way associated with ancient and
+pernicious beliefs which the Church was seeking to overthrow. One
+result of the clerical opposition to the advancement of science was
+that its votaries were driven to prove every step which led to their
+conclusions. They were forced to abandon the loose speculation of
+their intellectual guides, the Greeks, and to betake themselves to
+observation. Thus a part of the laborious fact-gathering habit on
+which the modern advance of science has absolutely depended was due to
+the care which men had to exercise in face of the religious
+authorities.
+
+In our own time, in the latter part of the nineteenth century, the
+conflict between the religious authority and the men of science has
+practically ceased. Even the Roman Church permits almost everywhere an
+untrammelled teaching of the established learning to which it was at
+one time opposed. Men have come to see that all truth is accordant,
+and that religion has nothing to fear from the faithful and devoted
+study of Nature.
+
+The advance of science in general in modern times has been greatly due
+to the development of mechanical inventions. Among the ancients, the
+tools which served in the arts were few in number, and these of
+exceeding simplicity. So far as we can ascertain, in the five hundred
+years during which the Greeks were in their intellectual vigour, not
+more than half a dozen new machines were invented, and these were
+exceedingly simple. The fact seems to be that a talent for mechanical
+invention is mainly limited to the peoples of France, Germany, and of
+the English-speaking folk. The first advances in these contrivances
+were made in those countries, and all our considerable gains have come
+from their people. Thus, while the spirit of science in general is
+clearly limited to the Aryan folk, that particular part of the motive
+which leads to the invention of tools is restricted to western and
+northern Europe, to the people to whom we give the name of Teutonic.
+
+Mechanical inventions have aided the development of our sciences in
+several ways. They have furnished inquirers with instruments of
+precision; they have helped to develop accuracy of observation; best
+of all, they have served ever to bring before the attention of men a
+spectacle of the conditions in Nature which we term cause and effect.
+The influence of these inventions on the development of learning has
+been particularly great where the machines, such as our wind and water
+mills, and our steam engine, make use of the forces of Nature,
+subjugating them to the needs of man. Such instruments give an
+unending illustration as to the presence in Nature of energy. They
+have helped men to understand that the machinery of the universe is
+propelled by the unending application of power. It was, in fact,
+through such machines that men of science first came to understand
+that energy, manifested in the natural forces, is something that
+eternally endures; that we may change its form in our arts as its form
+is changed in the operations of Nature, but the power endures forever.
+
+It is interesting to note that the first observation which led to this
+most important scientific conclusion that energy is indestructible
+however much it may change its form, was made by an American, Benjamin
+Thompson, who left this country at the time of the Revolution, and
+after a curious life became the executive officer, and in effect king,
+of Bavaria. While engaged in superintending the manufacture of cannon,
+he observed that in boring out the barrel of the gun an amount of heat
+was produced which evaporated a certain amount of water. He therefore
+concluded that the energy required to do the boring of the metal
+passed into the state of heat, and thus only changed its state, in no
+wise disappearing from the earth. Other students pursuing the same
+line of inquiry have clearly demonstrated what is called the law of
+the conservation of energy, which more than anything has helped us to
+understand the large operations of Nature. Through these studies we
+have come to see that, while the universe is a place of ceaseless
+change, the quantities of energy and of matter remain unaltered.
+
+The foregoing brief sketch, which sets forth some of the important
+conditions which have affected the development of science, may in a
+way serve to show the student how he can himself become an interpreter
+of Nature. The evidence indicates that the people of our race have
+been in a way chosen among all the varieties of mankind to lead in
+this great task of comprehending the visible universe. The facts,
+moreover, show that discovery usually begins with the interest which
+men feel in the world immediately about them, or which is presented to
+their senses in a daily spectacle. Thus Benjamin Franklin, in the
+midst of a busy life, became deeply interested in the phenomena of
+lightning, and by a very simple experiment proved that this wonder of
+the air was due to electrical action such as we may arouse by rubbing
+a stick of sealing-wax or a piece of amber with a cloth. All
+discoveries, in a word, have had their necessary beginnings in an
+interest in the facts which daily experience discloses. This desire to
+know something more than the first sight exhibits concerning the
+actions in the world about us is native in every human soul--at least,
+in all those who are born with the heritage of our race. It is
+commonly strong in childhood; if cultivated by use, it will grow
+throughout a lifetime, and, like other faculties, becomes the stronger
+and more effective by the exertions which it inspires. It is therefore
+most important that every one should obey this instinctive command to
+inquiry, and organize his life and work so that he may not lose but
+gain more and more as time goes on of this noble capacity to
+interrogate and understand the world about him.
+
+It is best that all study of Nature should begin not in laboratories,
+nor with the things which are remote from us, but in the field of
+Nature which is immediately about us. The student, even if he dwell in
+the unfavourable conditions of a great city, is surrounded by the
+world which has yielded immeasurable riches in the way of learning,
+which he can appropriate by a little study. He can readily come to
+know something of the movements of the air; the buildings will give
+him access to a great many different kinds of stone; the smallest
+park, a little garden, or even a few potted plants and captive
+animals, may tell him much concerning the forms and actions of living
+beings. By studying in this way he can come to know something of the
+differences between things and their relations to each other. He will
+thus have a standard by which he can measure and make familiar the
+body of learning concerning Nature which he may find in books. From
+printed pages alone, however well they be written, he can never hope
+to catch the spirit that animates the real inquirer, the true lover of
+Nature.
+
+On many accounts the most attractive way of beginning to form the
+habit of the naturalist is by the study of living animals and plants.
+To all of us life adds interest, and growth has a charm. Therefore it
+is well for the student to start on the way of inquiry by watching the
+actions of birds and insects or by rearing plants. It is fortunate if
+he can do both these agreeable things. When the habit of taking an
+account of that most important part of the world which is immediately
+about him has been developed in the student, he may profitably proceed
+to acquire the knowledge of the invisible universe which has been
+gathered by the host of inquirers of his race. However far he
+journeys, he should return to the home world that lies immediately and
+familiarly about him, for there alone can he acquire and preserve that
+personal acquaintance with things which is at once the inspiration and
+the test of all knowledge.
+
+Along with this study of the familiar objects about us the student may
+well combine some reading which may serve to show him how others have
+been successful in thus dealing with Nature at first hand. For this
+purpose there are, unfortunately, but few works which are well
+calculated to serve the needs of the beginner. Perhaps the best
+naturalist book, though its form is somewhat ancient, is White's
+Natural History of Selborne. Hugh Miller's works, particularly his Old
+Red Sandstone and My Schools and Schoolmasters, show well how a man
+may become a naturalist under difficulties. Sir John Lubbock's studies
+on Wasps, and Darwin's work on Animals and Plants under Domestication
+are also admirable to show how observation should be made. Dr. Asa
+Gray's little treatise on How Plants Grow will also be useful to the
+beginner who wishes to approach botany from its most attractive
+side--that of the development of the creature from the seed to seed.
+
+There is another kind of training which every beginner in the art of
+observing Nature should obtain, and which many naturalists of repute
+would do well to give themselves--namely, an education in what we may
+call the art of distance and geographical forms. With the primitive
+savage the capacity to remember and to picture to the eye the shape of
+a country which he knows is native and instinctive. Accustomed to
+range the woods, and to trust to his recollection to guide him through
+the wilderness to his home, the primitive man develops an important
+art which among civilized people is generally dormant. In fact, in our
+well-trodden ways people may go for many generations without ever
+being called upon to use this natural sense of geography. The easiest
+way to cultivate the geographic sense is by practising the art of
+making sketch maps. This the student, however untrained, can readily
+do by taking first his own dwelling house, on which he should practise
+until he can readily from memory make a tolerably correct and
+proportional plan of all its rooms. Then on a smaller scale he should
+begin to make also from recollection a map showing the distribution of
+the roads, streams, and hills with which his daily life makes him
+familiar. From time to time this work from memory should be compared
+with the facts. At first the record will be found to be very poor, but
+with a few months of occasional endeavour the observer will find that
+his mind takes account of geographic features in a way it did not
+before, and, moreover, that his mind becomes enriched with
+impressions of the country which are clear and distinct, in place of
+the shadowy recollections which he at first possessed.
+
+When the student has attained the point where, after walking or riding
+over a country, he can readily recall its physical features of the
+simpler sort, he will find it profitable to undertake the method of
+mapping with contour lines--that is, by pencilling in indications to
+show the exact shape of the elevations and depressions. The principle
+of contour lines is that each of them represents where water would
+come against the slope if the area were sunk step by step below the
+sea level--in other words, each contour line marks the intersection of
+a horizontal plane with the elevation of the country. Practice on this
+somewhat difficult task will soon give the student some idea as to the
+complication of the surface of a region, and afford him the basis for
+a better understanding of what geography means than all the reading he
+can do will effect. It is most desirable that training such as has
+been described should be a part of our ordinary school education.
+
+Very few people have clear ideas of distances. Even the men whose
+trade requires some such knowledge are often without that which a
+little training could give them. Without some capacity in this
+direction, the student is always at a disadvantage in his contact with
+Nature. He can not make a record of what he sees as long as the
+element of horizontal and vertical distance is not clearly in mind. To
+attain this end the student should begin by pacing some length of road
+where the distances are well known. In this way he will learn the
+length of his step, which with a grown man generally ranges between
+two and a half and three feet. Learning the average length of his
+stride by frequent counting, it is easy to repeat the trial until one
+can almost unconsciously keep the count as he walks. Properly to
+secure the training of this sort the observer should first attentively
+look across the distance which is to be determined. He should notice
+how houses, fences, people, and trees appear at that distance. He will
+quickly perceive that each hundred feet of additional interval
+somewhat changes their aspect. In training soldiers to measure with
+the eye the distances which they have to know in order effectively to
+use the modern weapons of war, a common device is to take a squad of
+men, or sometimes a company, under the command of an officer, who
+halts one man at each hundred yards until the detachment is strung out
+with that interval as far as the eye can see them. The men then walk
+to and fro so that the troops who are watching them may note the
+effects of increased distance on their appearance, whether standing or
+in motion. At three thousand yards a man appears as a mere dot, which
+is not readily distinguishable. Schoolboys may find this experiment
+amusing and instructive.
+
+After the student has gained, as he readily may, some sense of the
+divisions of distance within the range of ordinary vision, he should
+try to form some notion of greater intervals, as of ten, a hundred,
+and perhaps a thousand miles. The task becomes more difficult as the
+length of the line increases, but most persons can with a little
+address manage to bring before their eyes a tolerably clear image of a
+hundred miles of distance by looking from some elevation which
+commands a great landscape. It is doubtful, however, whether the
+best-trained man can get any clear notion of a thousand miles--that
+is, can present it to himself in imagination as he may readily do with
+shorter intervals.
+
+The most difficult part of the general education which the student has
+to give himself is begun when he undertakes to picture long intervals
+of time. Space we have opportunities to measure, and we come in a way
+to appreciate it, but the longest lived of men experiences at most a
+century of life, and this is too small a measure to give any notion as
+to the duration of such great events as are involved in the history of
+the earth, where the periods are to be reckoned by the millions of
+years. The only way in which we can get any aid in picturing to
+ourselves great lapses of time is by expressing them in units of
+distance. Let a student walk away on a straight road for the distance
+of a mile; let him call each step a year; when he has won the first
+milestone, he may consider that he has gone backward in time to the
+period of Christ's birth. Two miles more will take him to the station
+which will represent the age when the oldest pyramids were built. He
+is still, however, in the later days of man's history on this planet.
+To attain on the scale the time when man began, he might well have to
+walk fifty miles away, while a journey which would thus by successive
+steps describe the years of the earth's history since life appeared
+upon its surface would probably require him to circle the earth at
+least four times. We may accept it as impossible for any one to deal
+with such vast durations save with figures which are never really
+comprehended. It is well, however, to enlarge our view as to the age
+of the earth by such efforts as have just been indicated.
+
+When we go beyond the earth into the realm of the stars all efforts
+toward understanding the ranges of space or the durations of time are
+quite beyond the efforts of man. Even the distance of about two
+hundred and forty thousand miles which separates us from the moon can
+not be grasped by even the greater minds. No human intelligence,
+however cultivated, can conceive the distance of about ninety-five
+million miles which separates us from the sun. In the celestial realm
+we can only deal with relations of space and time in a general and
+comparative way. We can state the distances if we please in millions
+of miles, or we can reckon the ampler spaces by using the interval
+which separates the earth from the sun as we do a foot rule in our
+ordinary work, but the depths of the starry spaces can only be sounded
+by the winged imagination.
+
+Although the student has been advised to begin his studies of Nature
+on the field whereon he dwells, making that study the basis of his
+most valuable communications with Nature, it is desirable that he
+should at the same time gain some idea as to the range and scope of
+our knowledge concerning the visible universe. As an aid toward this
+end the following chapters of this book will give a very brief survey
+of some of the most important truths concerning the heavens and the
+earth which have rewarded the studies of scientific men. Of remoter
+things, such as the bodies in the stellar spaces, the account will be
+brief, for that which is known and important to the general student
+can be briefly told. So, too, of the earlier ages of the earth's
+history, although a vast deal is known, the greater part of the
+knowledge is of interest and value mainly to geologists who cultivate
+that field. That which is most striking and most important to the mass
+of mankind is to be found in the existing state of our earth, the
+conditions which make it a fit abode for our kind, and replete with
+lessons which he may study with his own eyes without having to travel
+the difficult paths of the higher sciences.
+
+Although physiography necessarily takes some account of the things
+which have been, even in the remote past, and this for the reason that
+everything in this day of the world depends on the events of earlier
+days, the accent of its teaching is on the immediate, visible, as we
+may say, living world, which is a part of the life of all its
+inhabitants.
+
+
+
+
+                            CHAPTER III.
+
+                         THE STELLAR REALM.
+
+
+Even before men came to take any careful account of the Nature
+immediately about them they began to conjecture and in a way to
+inquire concerning the stars and the other heavenly bodies. It is
+difficult for us to imagine how hard it was for students to gain any
+adequate idea of what those lights in the sky really are. At first men
+imagined the celestial bodies to be, as they seemed, small objects not
+very far away. Among the Greeks the view grew up that the heavens were
+formed of crystal spheres in which the lights were placed, much as
+lanterns may be hung upon a ceiling. These spheres were conceived to
+be one above the other; the planets were on the lower of them, and the
+fixed stars on the higher, the several crystal roofs revolving about
+the earth. So long as the earth was supposed to be a flat and
+limitless expanse, forming the centre of the universe, it was
+impossible for the students of the heavens to attain any more rational
+view as to their plan.
+
+The fact that the earth was globular in form was understood by the
+Greek men of science. They may, indeed, have derived the opinion from
+the Egyptian philosophers. The discovery rested upon the readily
+observed fact that on a given day the shadow of objects of a certain
+height was longer in high latitude than in low. Within the tropics,
+when the sun was vertical, there would be no shadow, while as far
+north as Athens it would be of considerable length. The conclusion
+that the earth was a sphere appears to have been the first large
+discovery made by our race. It was, indeed, one of the most important
+intellectual acquisitions of man.
+
+Understanding the globular form of the earth, the next and most
+natural step was to learn that the earth was not the centre of the
+planetary system, much less of the universe, but that that centre was
+the sun, around which the earth and the other planets revolved. The
+Greeks appear to have had some idea that this was the case, and their
+spirit of inquiry would probably have led them to the whole truth but
+for the overthrow of their thought by the Roman conquest and the
+spread of Christianity. It was therefore not until after the revival
+of learning that astronomers won their way to our modern understanding
+concerning the relation of the planets to the sun. With Galileo this
+opinion was affirmed. Although for a time the Church, resting its
+opposition on the interpretation of certain passages of Scripture,
+resisted this view, and even punished the men who held it, it
+steadfastly made its way, and for more than two centuries has been the
+foundation of all the great discoveries in the stellar realm. Yet long
+after the fact that the sun was the centre of the solar system was
+well established no one understood why the planets should move in
+their ceaseless, orderly procession around the central mass. To Newton
+we owe the studies on the law of gravitation which brought us to our
+present large conception as to the origin of this order. Starting with
+the view that bodies attracted each other in proportion to their
+weight, and in diminishing proportion as they are removed from each
+other, Newton proceeded by most laborious studies to criticise this
+view, and in the end definitely proved it by finding that the motions
+of the moon about the earth, as well as the paths of the planets,
+exactly agreed with the supposition.
+
+The last great path-breaking discovery which has helped us in our
+understanding of the stars was made by Fraunhofer and other
+physicists, who showed us that substances when in a heated, gaseous,
+or vaporous state produced, in a way which it is not easy to explain
+in a work such as this, certain dark lines in the spectrum, or streak
+of divided light which we may make by means of a glass prism, or, as
+in the rainbow, by drops of water. Carefully studying these very
+numerous lines, those naturalists found that they could with singular
+accuracy determine what substances there were in the flame which gave
+the light. So accurate is this determination that it has been made to
+serve in certain arts where there is no better means of ascertaining
+the conditions of a flaming substance except by the lines which its
+light exhibits under this kind of analysis. Thus, in the manufacture
+of iron by what is called the Bessemer process, it has been found very
+convenient to judge as to the state of the molten metal by such an
+analysis of the flame which comes forth from it.
+
+[Illustration: _Seal Rocks near San Francisco, California, showing
+slight effect of waves where there is no beach._]
+
+No sooner was the spectroscope invented than astronomers hastened by
+its aid to explore the chemical constitution of the sun. These studies
+have made it plain that the light of our solar centre comes forth from
+an atmosphere composed of highly heated substances, all of which are
+known among the materials forming the earth. Although for various
+reasons we have not been able to recognise in the sun all the elements
+which are found in our sphere, it is certain that in general the two
+bodies are alike in composition. An extension of the same method of
+inquiry to the fixed stars was gradually though with difficulty
+attained, and we now know that many of the elements common to the sun
+and earth exist in those distant spheres. Still further, this method
+of inquiry has shown us, in a way which it is not worth while here to
+describe, that among these remoter suns there are many aggregations of
+matter which are not consolidated as are the spheres of our own solar
+system, but remain in the gaseous state, receiving the name of nebulæ.
+
+Along with the growth of observational astronomy which has taken place
+since the discoveries of Galileo, there has been developed a view
+concerning the physical history of the stellar world, known as the
+nebular hypothesis, which, though not yet fully proved, is believed by
+most astronomers and physicists to give us a tolerably correct notion
+as to the way in which the heavenly spheres were formed from an
+earlier condition of matter. This majestic conception was first
+advanced, in modern times at least, by the German philosopher Immanuel
+Kant. It was developed by the French astronomer Laplace, and is often
+known by his name. The essence of this view rests upon the fact
+previously noted that in the realm of the fixed stars there are many
+faintly shining aggregations of matter which are evidently not solid
+after the manner of the bodies in our solar system, but are in the
+state where their substances are in the condition of dustlike
+particles, as are the bits of carbon in flame or the elements which
+compose the atmosphere. The view held by Laplace was to the effect
+that not only our own solar system, but the centres of all the other
+similar systems, the fixed stars, were originally in this gaseous
+state, the material being disseminated throughout all parts of the
+heavenly realm, or at least in that portion of the universe of which
+we are permitted to know something. In this ancient state of matter we
+have to suppose that the particles of it were more separated from each
+other than are the atoms of the atmospheric gases in the most perfect
+vacuum which we can produce with the air-pump. Still we have to
+suppose that each of these particles attract the other in the
+gravitative way, as in the present state of the universe they
+inevitably do.
+
+Under the influence of the gravitative attraction the materials of
+this realm of vapour inevitably tended to fall in toward the centre.
+If the process had been perfectly simple, the result would have been
+the formation of one vast mass, including all the matter which was in
+the original body. In some way, no one has yet been able to make a
+reasonable suggestion of just how, there were developed in the
+process of concentration a great many separate centres of aggregation,
+each of which became the beginning of a solar system. The student may
+form some idea of how readily local centres may be produced in
+materials disseminated in the vaporous state by watching how fog or
+the thin, even misty clouds of the sunrise often gather into the
+separate shapes which make what we term a "mackerel" sky. It is
+difficult to imagine what makes centres of attraction, but we readily
+perceive by this instance how they might have occurred.
+
+When the materials of each solar system were thus set apart from the
+original mass of star dust or vapour, they began an independent
+development which led step by step, in the case of our own solar
+system at least, and presumably also in the case of the other suns,
+the fixed stars, to the formation of planets and their moons or
+satellites, all moving around the central sun. At this stage of the
+explanation the nebular hypothesis is more difficult to conceive than
+in the parts of it which have already been described, for we have now
+to understand how the planets and satellites had their matter
+separated from each other and from the solar centre, and why they came
+to revolve around that central body. These problems are best
+understood by noting some familiar instances connected with the
+movement of fluids and gases toward a centre. First let us take the
+case of a basin in which the water is allowed to flow out through a
+hole in its centre. When we lift the stopper the fluid for a moment
+falls straight down through the opening. Very quickly, however, all
+the particles of the water start to move toward the centre, and almost
+at once the mass begins to whirl round with such speed that, although
+it is working toward the middle, it is by its movement pushed away
+from the centre and forms a conical depression. As often as we try the
+experiment, the effect is always the same. We thus see that there is
+some principle which makes particles of fluid that tend toward a
+centre fail directly to attain it, but win their way thereto in a
+devious, spinning movement.
+
+Although the fact is not so readily made visible to the eye, the same
+principle is illustrated in whirling storms, in which, as we shall
+hereafter note with more detail, the air next the surface of the earth
+is moving in toward a kind of chimney by which it escapes to the upper
+regions of the atmosphere. A study of cyclones and tornadoes, or even
+of the little air-whirls which in hot weather lift the dust of our
+streets, shows that the particles of the atmosphere in rushing in
+toward the centre of upward movement take on the same whirling motion
+as do the molecules of water in the basin--in fact, the two actions
+are perfectly comparable in all essential regards, except that the
+fluid is moving downward, while the air flows upward. Briefly stated,
+the reason for the movement of fluid and gas in the whirling way is as
+follows: If every particle on its way to the centre moved on a
+perfectly straight line toward the point of escape, the flow would be
+directly converging, and the paths followed would resemble the spokes
+of a wheel. But when by chance one of the particles sways ever so
+little to one side of the direct way, a slight lateral motion would
+necessarily be established. This movement would be due to the fact
+that the particle which pursued the curved line would press against
+the particles on the out-curved side of its path--or, in other words,
+shove them a little in that direction--to the extent that they
+departed from the direct line they would in turn communicate the
+shoving to the next beyond. When two particles are thus shoving on one
+side of their paths, the action which makes for revolution is doubled,
+and, as we readily see, the whole mass may in this way become quickly
+affected, the particles driven out of their path, moving in a curve
+toward the centre. We also see that the action is accumulative: the
+more curved the path of each particle, the more effectively it shoves;
+and so, in the case of the basin, we see the whirling rapidly
+developed before our eyes.
+
+In falling in toward the centre the particles of star dust or vapour
+would no more have been able one and all to pursue a perfectly
+straight line than the particles of water in the basin. If a man
+should spend his lifetime in filling and emptying such a vessel, it is
+safe to say that he would never fail to observe the whirling movement.
+As the particles of matter in the nebular mass which was to become a
+solar system are inconceivably greater than those of water in the
+basin, or those of air in the atmospheric whirl, the chance of the
+whirling taking place in the heavenly bodies is so great that we may
+assume that it would inevitably occur.
+
+As the vapours in the olden day tended in toward the centre of our
+solar system, and the mass revolved, there is reason to believe that
+ringlike separations took place in it. Whirling in the manner
+indicated, the mass of vapour or dust would flatten into a disk or a
+body of circular shape, with much the greater diameter in the plane of
+its whirling. As the process of concentration went on, this disk is
+supposed to have divided into ringlike masses, some approach to which
+we can discern in the existing nebulæ, which here and there among the
+farther fixed stars appear to be undergoing such stages of development
+toward solar systems. It is reasonably supposed that after these rings
+had been developed they would break to pieces, the matter in them
+gathering into a sphere, which in time was to become a planet. The
+outermost of these rings led to the formation of the planet farthest
+from the sun, and was probably the first to separate from the parent
+mass. Then in succession rings were formed inwardly, each leading in
+turn to the creation of another planet, the sun itself being the
+remnant, by far the greater part of the whole mass of matter, which
+did not separate in the manner described, but concentrated on its
+centre. Each of these planetary aggregations of vapour tended to
+develop, as it whirled upon its centre, rings of its own, which in
+turn formed, by breaking and concentrating, the satellites or moons
+which attend the earth, as they do all the planets which lie farther
+away from the sun than our sphere.
+
+[Illustration: Fig. 1.--Saturn, Jan. 26, 1889 (Antoniadi).]
+
+As if to prove that the planets and moons of the solar system were
+formed somewhat in the manner in which we have described it, one of
+these spheres, Saturn, retains a ring, or rather a band which appears
+to be divided obscurely into several rings which lie between its group
+of satellites and the main sphere. How this ring has been preserved
+when all the others have disappeared, and what is the exact
+constitution of the mass, is not yet well ascertained. It seems clear,
+however, that it can not be composed of solid matter. It is either in
+the form of dust or of small spheres, which are free to move on each
+other; otherwise, as computation shows, the strains due to the
+attraction which Saturn itself and its moons exercise upon it would
+serve to break it in pieces. Although this ring theory of the
+formation of the planets and satellites is not completely proved, the
+occurrence of such a structure as that which girdles Saturn affords
+presumptive evidence that it is true. Taken in connection with what we
+know of the nebulæ, the proof of Laplace's nebular hypothesis may
+fairly be regarded as complete.
+
+It should be said that some of the fixed stars are not isolated suns
+like our own, but are composed of two great spheres revolving about
+one another; hence they are termed double stars. The motions of these
+bodies are very peculiar, and their conditions show us that it is not
+well to suppose that the solar system in which we dwell is the only
+type of order which prevails in the celestial families; there may,
+indeed, be other variations as yet undetected. Still, these
+differences throw no doubt on the essential truth of the theory as to
+the process of development of the celestial systems. Though there is
+much room for debate as to the details of the work there, the general
+truth of the theory is accepted by nearly all the students of the
+problem.
+
+A peculiar advantage of the nebular hypothesis is that it serves to
+account for the energy which appears as light and heat in the sun and
+the fixed stars, as well as that which still abides in the mass of our
+earth, and doubtless also in the other large planets. When the matter
+of which these spheres were composed was disseminated through the
+realms of space, it is supposed to have had no positive temperature,
+and to have been dark, realizing the conception which appears in the
+first chapter of Genesis, "without form, and void." With each stage of
+the falling in toward the solar centres what is called the "energy of
+position" of this original matter became converted into light and
+heat. To understand how this took place, the reader should consider
+certain simple yet noble generalizations of physics. We readily
+recognise the fact that when a hammer falls often on an anvil it heats
+itself and the metal on which it strikes. Those who have been able to
+observe the descent of meteoric stones from the heavens have remarked
+that when they came to the earth they were, on their surfaces at
+least, exceedingly hot. Any one may observe shining meteors now and
+then flashing in the sky. These are known commonly to be very small
+bits of matter, probably not larger than grains of sand, which,
+rushing into our atmosphere, are so heated by the friction which they
+encounter that they burn to a gas or vapour before they attain the
+earth. As we know that these particles come from the starry spaces,
+where the temperature is somewhere near 500° below 0° Fahr., it is
+evident that the light and heat are not brought with them into the
+atmosphere; it can only be explained by the fact that when they enter
+the air they are moving at an average speed of about twenty miles a
+second, and that the energy which this motion represents is by the
+resistance which the body encounters converted into heat. This fact
+will help us to understand how, as the original star dust fell in
+toward the centre of attraction, it was able to convert what we have
+termed the energy of position into temperature. We see clearly that
+every such particle of dust or larger bit of matter which falls upon
+the earth brings about the development of heat, even though it does
+not actually strike upon the solid mass of our sphere. The conception
+of what took place in the consolidation of the originally disseminated
+materials of the sun and planets can be somewhat helped by a simple
+experiment. If we fit a piston closely into a cylinder, and then
+suddenly drive it down with a heavy blow, the compressed air is so
+heated that it may be made to communicate fire. If the piston should
+be slowly moved, the same amount of heat would be generated, or, as we
+may better say, liberated by the compression, though the effect would
+not be so striking. A host of experiments show that when a given mass
+of matter is brought to occupy a less space the effect is in
+practically all cases to increase the temperature. The energy which
+kept the particles apart is, when they are driven together, converted
+into heat. These two classes of actions are somewhat different in
+their nature; in the case of the meteors, or the equivalent star dust,
+the coming together of the particles is due to gravitation. In the
+experiment with the cylinder above described, the compression is due
+to mechanical energy, a force of another nature.
+
+There is reason for believing that all our planets, as well as the sun
+itself, and also the myriad other orbs of space, have all passed
+through the stages of a transition in which a continually
+concentrating vapour, drawn together by gravitation, became
+progressively hotter and more dense until it assumed the condition of
+a fluid. This fluid gradually parted with its heat to the cold spaces
+of the heavens, and became more and more concentrated and of a lower
+temperature until in the end, as in the case of our earth and of other
+planets, it ceased to glow on the outside, though it remained
+intensely heated in the inner parts. It is easy to see that the rate
+of this cooling would be in some proportion to the size of the sphere.
+Thus the earth, which is relatively small, has become relatively cold,
+while the sun itself, because of its vastly greater mass, still
+retains an exceedingly high temperature. The reason for this can
+readily be conceived by making a comparison of the rate of cooling
+which occurs in many of our ordinary experiences. Thus a vial of hot
+water will quickly come down to the temperature of the air, while a
+large jug filled with the fluid at the same temperature will retain
+its heat many times as long. The reason for this rests upon the simple
+principle that the contents of a sphere increase with its enlargement
+more rapidly than the surface through which the cooling takes place.
+
+The modern studies on the physical history of the sun and other
+celestial bodies show that their original store of heat is constantly
+flowing away into the empty realms of space. The rate at which this
+form of energy goes away from the sun is vast beyond the powers of the
+imagination to conceive; thus, in the case of our earth, which viewed
+from the sun would appear no more than a small star, the amount of
+heat which falls upon it from the great centre is enough each day to
+melt, if it all could be put to such work, about eight thousand cubic
+miles of ice. Yet the earth receives only 1/2,170,000,000 part of the
+solar radiation. The greater part of this solar heat--in fact, we may
+say nearly all of it--slips by the few and relatively small planets
+and disappears in the great void.
+
+The destiny of all the celestial spheres seems in time to be that
+they shall become cooled down to a temperature far below anything
+which is now experienced on this earth. Even the sun, though its heat
+will doubtless endure for millions of years to come, must in time, so
+far as we can see, become dark and cold. So far as we know, we can
+perceive no certain method by which the life of the slowly decaying
+suns can be restored. It has, however, been suggested that in many
+cases a planetary system which has attained the lifeless and lightless
+stage may by collision with some other association of spheres be by
+the blow restored to its previous state of vapour, the joint mass of
+the colliding systems once again to resume the process of
+concentration through which it had gone before. Now and then stars
+have been seen to flash suddenly into great brilliancy in a way which
+suggests that possibly their heat had been refreshed by a collision
+with some great mass which had fallen into them from the celestial
+spaces. There is room for much speculation in this field, but no
+certainty appears to be attainable.
+
+The ancients believed that light and heat were emanations which were
+given off from the bodies that yielded them substantially as odours
+are given forth by many substances. Since the days of Newton inquiry
+has forced us to the conviction that these effects of temperature are
+produced by vibrations having the general character of waves, which
+are sent through the spaces with great celerity. When a ray of light
+departs from the sun or other luminous body, it does not convey any
+part of the mass; it transmits only motion. A conception of the action
+can perhaps best be formed by suspending a number of balls of ivory,
+stone, or other hard substance each by a cord, the series so arranged
+that they touch each other. Then striking a blow against one end of
+the line, we observe that the ball at the farther end of the line is
+set in motion, swinging a little away from the place it occupied
+before. The movement of the intermediate balls may be so slight as to
+escape attention. We thus perceive that energy can be transmitted
+from one to another of these little spheres. Close observation shows
+us that under the impulse which the blow gives each separate body is
+made to sway within itself much in the manner of a bell when it is
+rung, and that the movement is transmitted to the object with which it
+is in contact. In passing from the sun to the earth, the light and
+heat traverse a space which we know to be substantially destitute of
+any such materials as make up the mass of the earth or the sun. Judged
+by the standards which we can apply, this space must be essentially
+empty. Yet because motions go through it, we have to believe that it
+is occupied by something which has certain of the properties of
+matter. It has, indeed, one of the most important properties of all
+substances, in that it can vibrate. This practically unknown thing is
+called ether.
+
+The first important observational work done by the ancients led them
+to perceive that there was a very characteristic difference between
+the planets and the fixed stars. They noted the fact that the planets
+wandered in a ceaseless way across the heavens, while the fixed stars
+showed little trace of changing position in relation to one another.
+For a long time it was believed that these, as well as the remoter
+fixed stars, revolved about the earth. This error, though great, is
+perfectly comprehensible, for the evident appearance of the movement
+is substantially what would be brought about if they really coursed
+around our sphere. It was only when the true nature of the earth and
+its relations to the sun were understood that men could correct this
+first view. It was not, indeed, until relatively modern times that the
+solar system came to be perceived as something independent and widely
+detached from the fixed stars system; that the spaces which separate
+the members of our own solar family, inconceivably great as they are,
+are but trifling as compared with the intervals which part us from the
+nearer fixed stars. At this stage of our knowledge men came to the
+noble suggestion that each of the fixed stars was itself a sun, each
+of the myriad probably attended by planetary bodies such as exist
+about our own luminary.
+
+It will be well for the student to take an imaginary journey from the
+sun forth into space, along the plane in which extends that vast
+aggregation of stars which we term the Milky Way. Let him suppose that
+his journey could be made with something like the speed of light, or,
+say, at the rate of about two hundred thousand miles a second. It is
+fit that the imagination, which is free to go through all things,
+should essay such excursions. On the fancied outgoing, the observer
+would pass the interval between the sun and the earth in about eight
+minutes. It would require some hours before he attained to the outer
+limit of the solar system. On his direct way he would pass the orbits
+of the several planets. Some would have their courses on one side or
+the other of his path; we should say above or below, but for the fact
+that we leave these terms behind in the celestial realm. On the margin
+of the solar system the sun would appear shrunken to the state where
+it was hardly greater than the more brilliant of the other fixed
+stars. The onward path would then lead through a void which it would
+require years to traverse. Gradually the sun which happened to lie
+most directly in his path would grow larger; with nearer approach, it
+would disclose its planets. Supposing that the way led through this
+solar system, there would doubtless be revealed planets and satellites
+in their order somewhat resembling those of our own solar family, yet
+there would doubtless be many surprises in the view. Arriving near the
+first sun to be visited, though the heavens would have changed their
+shape, all the existing constellations having altered with the change
+in the point of view, there would still be one familiar element in
+that the new-found planets would be near by, and the nearest fixed
+stars far away in the firmament.
+
+With the speed of light a stellar voyage could be taken along the path
+of the Milky Way, which would endure for thousands of years. Through
+all the course the journeyer would perceive the same vast girdle of
+stars, faint because they were far away, which gives the dim light of
+our galaxy. At no point is it probable that he would find the separate
+suns much more aggregated or greatly farther apart than they are in
+that part of the Milky Way which our sun now occupies. Looking forth
+on either side of the "galactic plane," there would be the same
+scattering of stars which we now behold when we gaze at right angles
+to the way we are supposing the spirit to traverse.
+
+As the form of the Milky Way is irregular, the mass, indeed, having
+certain curious divisions and branches, it well might be that the
+supposed path would occasionally pass on one or the other side of the
+vast star layer. In such positions the eye would look forth into an
+empty firmament, except that there might be in the far away, tens of
+thousands of years perhaps at the rate that light travels away from
+the observer, other galaxies or Milky Ways essentially like that which
+he was traversing. At some point the journeyer would attain the margin
+of our star stratum, whence again he would look forth into the
+unpeopled heavens, though even there he might discern other remote
+star groups separated from his own by great void intervals.
+
+                  *       *       *       *       *
+
+The revelations of the telescope show us certain features in the
+constitution and movements of the fixed stars which now demand our
+attention. In the first place, it is plain that not all of these
+bodies are in the same physical condition. Though the greater part of
+these distant luminous masses are evidently in the state of
+aggregation displayed by our own sun, many of them retain more or less
+of that vaporous, it may be dustlike, character which we suppose to
+have been the ancient state of all the matter in the universe. Some of
+these masses appear as faint, almost indistinguishable clouds, which
+even to the greatest telescope and the best-trained vision show no
+distinct features of structure. In other cases the nebulous
+appearance is hardly more than a mist about a tolerably distinct
+central star. Yet again, and most beautifully in the great nebula of
+the constellation of Orion, the cloudy mass, though hardly visible to
+the naked eye, shows a division into many separate parts, the whole
+appearing as if in process of concentration about many distinct
+centres.
+
+The nebulas are reasonably believed by many astronomers to be examples
+of the ancient condition of the physical universe, masses of matter
+which for some reason as yet unknown have not progressed in their
+consolidation to the point where they have taken on the
+characteristics of suns and their attendant planets.
+
+Many of the fixed stars, the incomplete list of which now amounts to
+several hundred, are curiously variable in the amount of light which
+they send out to the earth. Sometimes these variations are apparently
+irregular, but in the greater number of cases they have fixed periods,
+the star waxing and waning at intervals varying from a few months to a
+few years. Although some of the sudden flashings forth of stars from
+apparent small size to near the greatest brilliancy may be due to
+catastrophes such as might be brought about by the sudden falling in
+of masses of matter upon the luminous spheres, it is more likely that
+the changes which we observe are due to the fact that two suns
+revolving around a common centre are in different stages of
+extinction. It may well be that one of these orbs, presumably the
+smaller, has so far lost temperature that it has ceased to glow. If in
+its revolution it regularly comes between the earth and its luminous
+companion, the effect would be to give about such a change in the
+amount of light as we observe.
+
+The supposition that a bright sun and a relatively dark sun might
+revolve around a common centre of gravity may at first sight seem
+improbable. The fact is, however, that imperfect as our observations
+on the stars really are, we know many instances in which this kind of
+revolution of one star about another takes place. In some cases these
+stars are of the same brilliancy, but in others one of the lights is
+much brighter than the other. From this condition to the state where
+one of the stars is so nearly dark as to be invisible, the transition
+is but slight. In a word, the evidence goes to show that while we see
+only the luminous orbs of space, the dark bodies which people the
+heavens are perhaps as numerous as those which send us light, and
+therefore appear as stars.
+
+Besides the greater spheres of space, there is a vast host of lesser
+bodies, the meteorites and comets, which appear to be in part members
+of our solar system, and perhaps of other similar systems, and in part
+wanderers in the vast realm which intervenes between the solar
+systems. Of these we will first consider the meteors, of which we know
+by far the most; though even of them, as we shall see, our knowledge
+is limited.
+
+From time to time on any starry night, and particularly in certain
+periods of the year, we may behold, at the distance of fifty or more
+miles above the surface of the earth, what are commonly called
+"shooting stars." The most of these flashing meteors are evidently
+very small, probably not larger than tiny sand grains, possibly no
+greater than the fragments which would be termed dust. They enter the
+air at a speed of about thirty miles a second. They are so small that
+they burn to vapour in the very great heat arising from their friction
+on the air, and do not attain the surface of the earth. These are so
+numerous that, on the average, some hundreds of thousands probably
+strike the earth's atmosphere each day. From time to time larger
+bodies fall--bodies which are of sufficient bulk not to be burned up
+in the air, but which descend to the ground. These may be from the
+smallest size which may be observed to masses of many hundred pounds
+in weight. These are far less numerous than the dust meteorites; it is
+probable, however, that several hundred fragments each year attain the
+earth's surface. They come from various directions of space, and
+there is as yet no means of determining whether they were formed in
+some manner within our planetary system or whether they wander to us
+from remoter realms. We know that they are in part composed of
+metallic iron commingled with nickel and carbon (sometimes as very
+small diamonds) in a way rarely if ever found on the surface of our
+sphere, and having a structure substantially unknown in its deposits.
+In part they are composed of materials which somewhat resemble certain
+lavas. It is possible that these fragments of iron and stone which
+constitute the meteorites have been thrown into the planetary spaces
+by the volcanic eruption of our own and other planets. If hurled forth
+with a sufficient energy, the fragments would escape from the control
+of the attraction of the sphere whence they came, and would become
+independent wanderers in space, moving around the sun in varied orbits
+until they were again drawn in by some of the greater planets.
+
+As they come to us these meteorites often break up in the atmosphere,
+the bits being scattered sometimes over a wide area of country. Thus,
+in the case of the Cocke County meteorite of Tennessee, one of the
+iron species, the fragments, perhaps thousands in number, which came
+from the explosion of the body were scattered over an area of some
+thousand square miles. When they reach the surface in their natural
+form, these meteors always have a curious wasted and indented
+appearance, which makes it seem likely that they have been subject to
+frequent collisions in their journeys after they were formed by some
+violent rending action.
+
+In some apparent kinship with the meteorites may be classed the
+comets. The peculiarity of these bodies is that they appear in most
+cases to be more or less completely vaporous. Rushing down from the
+depths of the heavens, these bodies commonly appear as faintly
+shining, cloudlike masses. As they move in toward the sun long trails
+of vapour stream back from the somewhat consolidated head. Swinging
+around that centre, they journey again into the outer realm. As they
+retreat, their tail-like streamers appear to gather again upon their
+centres, and when they fade from view they are again consolidated. In
+some cases it has been suspected that a part at least of the cometary
+mass was solid. The evidence goes to show, however, that the matter is
+in a dustlike or vaporous condition, and that the weight of these
+bodies is relatively very small.
+
+[Illustration: Fig. 2.--The Great Comet of 1811, one of the many
+varied forms of these bodies.]
+
+Owing to their strange appearance, comets were to the ancients omens
+of calamity. Sometimes they were conceived as flaming swords; their
+forms, indeed, lend themselves to this imagining. They were thought to
+presage war, famine, and the death of kings. Again, in more modern
+times, when they were not regarded as portents of calamity, it was
+feared that these wanderers moving vagariously through our solar
+system might by chance come in contact with the earth with disastrous
+results. Such collisions are not impossible, for the reason that the
+planets would tend to draw these errant bodies toward them if they
+came near their spheres; yet the chance of such collisions happening
+to the earth is so small that they may be disregarded.
+
+
+                      MOTIONS OF THE SPHERES.
+
+Although little is known of the motions which occur among the
+celestial bodies beyond the sphere of our solar family, that which has
+been ascertained is of great importance, and serves to make it likely
+that all the suns in space are upon swift journeys which in their
+speed equal, if they do not exceed, the rate of motion among the
+planetary spheres, which may, in general, be reckoned at about twenty
+miles a second. Our whole solar system is journeying away from certain
+stars, and in the direction of others which are situated in the
+opposite part of the heavens. The proof of this fact is found in the
+observations which show that on one side of us the stars are
+apparently coming closer together, while on the other side they are
+going farther apart. The phenomenon, in a word, is one of perspective,
+and may be made real to the understanding by noting what takes place
+when we travel down a street along which there are lights. We readily
+note that these lights appear to close in behind us, and widen their
+intervals in the direction in which we journey. By such evidence
+astronomers have become convinced that our sphere, along with the sun
+which controls it, is each second a score of miles away from the point
+where it was before.
+
+There is yet other and most curious evidence which serves to show that
+certain of the stars are journeying toward our part of the heavens at
+great speed, while others are moving away from us by their own proper
+motion. These indications are derived from the study of the lines in
+the light which the spectrum reveals to us when critically examined.
+The position of these cross lines is, as we know, affected by the
+motion of the body whence the light comes, and by close analysis of
+the facts it has been pretty well determined that the distortion in
+their positions is due to very swift motions of the several stars. It
+is not yet certain whether these movements of our sun and of other
+solar bodies are in straight lines or in great circles.
+
+It should be noted that, although the evidence from the spectroscope
+serves to show that the matter in the stars is akin to that of our own
+earth, there is reason to believe that those great spheres differ much
+from each other in magnitude.
+
+We have now set forth some of the important facts exhibited by the
+stellar universe. The body of details concerning that realm is vast,
+and the conclusions drawn from it important; only a part, however, of
+the matter with which it deals is of a nature to be apprehended by the
+student who does not approach it in a somewhat professional way. We
+shall therefore now turn to a description of the portion of the starry
+world which is found in the limits of our solar system. There the
+influences of the several spheres upon our planet are matters of vital
+importance; they in a way affect, if they do not control, all the
+operations which go on upon the surface of the earth.
+
+
+                          THE SOLAR SYSTEM.
+
+We have seen that the matter in the visible universe everywhere tends
+to gather into vast associations which appear to us as stars, and that
+these orbs are engaged in ceaseless motion in journeys through space.
+In only one of these aggregations--that which makes our own solar
+system--are the bodies sufficiently near to our eyes for us, even with
+the resources of our telescopes and other instruments, to divine
+something of the details which they exhibit. In studying what we may
+concerning the family of the sun, the planets, and their satellites,
+we may reasonably be assured that we are tracing a history which with
+many differences is in general repeated in the development of each
+star in the firmament. Therefore the inquiry is one of vast range and
+import.
+
+Following, as we may reasonably do, the nebular hypothesis--a view
+which, though not wholly proved, is eminently probable--we may regard
+our solar system as having begun when the matter of which it is
+composed, then in a finely divided, cloudy state, was separated from
+the similar material which went to make the neighbouring fixed stars.
+The period when our solar system began its individual life was remote
+beyond the possibility of conception. Naturalists are pretty well
+agreed that living beings began to exist upon the earth at least a
+hundred million years ago; but the beginnings of our solar system must
+be placed at a date very many times as remote from the present day.[1]
+
+[Footnote 1: Some astronomers, particularly the distinguished Professor
+Newcomb, hold that the sun can not have been supplying heat as at
+present for more than about ten million years, and that all geological
+time must be thus limited. The geologist believes that this reckoning is
+far too short.]
+
+According to the nebular theory, the original vapour of the solar
+system began to fall in toward its centre and to whirl about that
+point at a time long before the mass had shrunk to the present limits
+of the solar system as defined by the path of the outermost planets.
+At successive stages of the concentration, rings after the manner of
+those of Saturn separated from the disklike mass, each breaking up and
+consolidating into a body of nebulous matter which followed in the
+same path, generally forming rings which became by the same process
+the moons or satellites of the sphere. In this way the sun produced
+eight planets which are known, and possibly others of small size on
+the outer verge of the system which have eluded discovery. According
+to this view, the planetary masses were born in succession, the
+farthest away being the oldest. It is, however, held by an able
+authority that the mass of the solar system would first form a rather
+flat disk, the several rings forming and breaking into planets at
+about the same time. The conditions in Saturn, where the inner ring
+remains parted, favours the view just stated.
+
+Before making a brief statement of the several planets, the asteroids,
+and the satellites, it will be well to consider in a general way the
+motions of these bodies about their centres and about the sun. The
+most characteristic and invariable of these movements is that by which
+each of the planetary spheres, as well as the satellites, describes an
+orbit around the gravitative centre which has the most influence upon
+it--the sun. To conceive the nature of this movement, it will be well
+to imagine a single planet revolving around the sun, each of these
+bodies being perfect spheres, and the two the only members of the
+solar system. In this condition the attraction of the two bodies would
+cause them to circle around a common centre of gravity, which, if the
+planet were not larger or the sun smaller than is the case in our
+solar system, would lie within the mass of the sun. In proportion as
+the two bodies might approach each other in size, the centre of
+gravity would come the nearer to the middle point in a line connecting
+the two spheres. In this condition of a sun with a single planet,
+whatever were the relative size of sun and planet, the orbits which
+they traverse would be circular. In this state of affairs it should be
+noted that each of the two bodies would have its plane of rotation
+permanently in the same position. Even if the spheres were more or
+less flattened about the poles of their axes, as is the case with all
+the planets which we have been able carefully to measure, as well as
+with the sun, provided the axes of rotation were precisely parallel to
+each other, the mutual attraction of the masses would cause no
+disturbance of the spheres. The same would be the case if the polar
+axis of one sphere stood precisely at right angles to that of the
+other. If, however, the spheres were somewhat flattened at the poles,
+and the axes inclined to each other, then the pull of one mass on the
+other would cause the polar axes to keep up a constant movement which
+is called nutation, or nodding.
+
+The reason why this nodding movement of the polar axes would occur
+when these lines were inclined to each other is not difficult to see
+if we remember that the attraction of masses upon each other is
+inversely as the square of the distance; each sphere, pulling on the
+equatorial bulging of the other, pulls most effectively on the part of
+it which is nearest, and tends to draw it down toward its centre. The
+result is that the axes of the attracted spheres are given a wobbling
+movement, such as we may note in the spinning top, though in the toy
+the cause of the motion is not that which we are considering.
+
+If, now, in that excellent field for the experiment we are essaying,
+the mind's eye, we add a second planet outside of the single sphere
+which we have so far supposed to journey about the sun, or rather
+about the common centre of gravity, we perceive at once that we have
+introduced an element which leads to a complication of much
+importance. The new sphere would, of course, pull upon the others in
+the measure of its gravitative value--i.e., its weight. The centre of
+gravity of the system would now be determined not by two distinct
+bodies, but by three. If we conceive the second planet to journey
+around the sun at such a rate that a straight line always connected
+the centres of the three orbs, then the only effect on their
+gravitative centre would be to draw the first-mentioned planet a
+little farther away from the centre of the sun; but in our own solar
+system, and probably in all others, this supposition is inadmissible,
+because the planets have longer journeys to go and also move slower,
+the farther they are from the sun. Thus Mercury completes the circle
+of its year in eighty-eight of our days, while the outermost planet
+requires sixty thousand days (more than one hundred and sixty-four
+years) for the same task. The result is not only that the centre of
+gravity of the system is somewhat displaced--itself a matter of no
+great account--but also that the orbit of the original planet ceases
+to be circled and becomes elliptical, and this for the evident reason
+that the sphere will be drawn somewhat away from the sun when the
+second planet happens to lie in the part of its orbit immediately
+outside of its position, in which case the pull is away from the solar
+centre; while, on the other hand, when the new planet was on the other
+side of the sun, its pull would serve to intensify the attraction
+which drew the first sphere toward the centre of gravity. As the
+pulling action of the three bodies upon each other, as well as upon
+their equatorial protuberances, would vary with every change in their
+relative position, however slight, the variations in the form of their
+orbits, even if the spheres were but three in number, would be very
+important. The consequences of these perturbations will appear in the
+sequel.
+
+In our solar system, though there are but eight great planets, the
+group of asteroids, and perhaps a score of satellites, the variety of
+orbital and axial movement which is developed taxes the computing
+genius of the ablest astronomer. The path which our earth follows
+around the sun, though it may in general and for convenience be
+described as a variable ellipse, is, in fact, a line of such
+complication that if we should essay a diagram of it on the scale of
+this page it would not be possible to represent any considerable part
+of its deviations. These, in fact, would elude depiction, even if the
+draughtsman had a sheet for his drawing as large as the orbit itself,
+for every particle of matter in space, even if it be lodged beyond the
+limits of the farthest stars revealed to us by the telescope,
+exercises a certain attraction, which, however small, is effective on
+the mass of the earth. Science has to render its conclusions in
+general terms, and we can safely take them as such; but in this, as in
+other instances, it is well to qualify our acceptance of the
+statements by the memory that all things are infinitely more
+complicated than we can possibly conceive or represent them to be.
+
+We have next to consider the rotations of the planetary spheres upon
+their axes, together with the similar movement, or lack of it, in the
+case of their satellites. This rotation, according to the nebular
+hypothesis, may be explained by the movements which would set up in
+the share of matter which was at first a ring of the solar nebula, and
+which afterward gathered into the planetary aggregation. The way of it
+may be briefly set forth as follows: Such a ring doubtless had a
+diameter of some million miles; we readily perceive that the particles
+of matter in the outer part of the belt would have a swifter movement
+around the sun than those on the inside. When by some disturbance, as
+possibly by the passage of a great meteoric body of a considerable
+gravitative power, this ring was broken in two, the particles
+composing it on either side would, because of their mutual attraction,
+tend to draw away from the breach, widening that gap until the matter
+of the broken ring was aggregated into a sphere of the star dust or
+vapour. When the nebulous matter originally in the ring became
+aggregated into a spherical form, it would, on account of the
+different rates at which the particles were moving when they came
+together, be the surer to fall in toward the centre, not in straight
+lines, but in curves--in other words, the mass would necessarily take
+on a movement of rotation essentially like that which we have
+described in setting forth the nebular hypothesis.
+
+In the stages of concentration the planetary nebulæ might well repeat
+those through which the greater solar mass proceeded. If the volume of
+the material were great, subordinate rings would be formed, which when
+they broke and concentrated would constitute secondary planets or
+satellites, such as our moon. For some reason as yet unknown the outer
+planets--in fact, all those in the solar system except the two inner,
+Venus and Mercury and the asteroids--formed such attendants. All these
+satellite-forming rings have broken and concentrated except the inner
+of Saturn, which remains as an intellectual treasure of the solar
+system to show the history of its development.
+
+To the student who is not seeking the fulness of knowledge which
+astronomy has to offer, but desires only to acquaint himself with the
+more critical and important of the heavenly phenomena which help to
+explain the earth, these features of planetary movement should prove
+especially interesting for the reason that they shape the history of
+the spheres. As we shall hereafter see, the machinery of the earth's
+surface, all the life which it bears, its winds and rains--everything,
+indeed, save the actions which go on in the depths of the sphere--is
+determined by the heat and light which come from the sun. The
+conditions under which this vivifying tide is received have their
+origin in the planetary motion. If our earth's path around the centre
+of the system was a perfect circle, and if its polar axis lay at right
+angles to the plane of its journey, the share of light and heat which
+would fall upon any one point on the sphere would be perfectly
+uniform. There would be no variations in the length of day or night;
+no changes in the seasons; the winds everywhere would blow with
+exceeding steadiness--in fact, the present atmospheric confusion would
+be reduced to something like order. From age to age, except so far as
+the sun itself might vary in the amount of energy which it radiated,
+or lands rose up into the air or sunk down toward the sea level, the
+climate of each region would be perfectly stable. In the existing
+conditions the influences bring about unending variety. First of all,
+the inclined position of the polar axis causes the sun apparently to
+move across the heavens, so that it comes in an overhead position once
+or twice in the year in quite half the area of the lands and seas.
+This apparent swaying to and fro of the sun, due to the inclination of
+the axis of rotation, also affects the width of the climatal belts on
+either side of the equator, so that all parts of the earth receive a
+considerable share of the sun's influence. If the axis of the earth's
+rotation were at right angles to the plane of its orbit, there would
+be a narrow belt of high temperature about the equator, north and
+south of which the heat would grade off until at about the parallels
+of fifty degrees we should find a cold so considerable and uniform
+that life would probably fade away; and from those parallels to the
+poles the conditions would be those of permanent frost, and of days
+which would darken into the enduring night or twilight in the realm
+of the far north and south. Thus the wide habitability of the earth is
+an effect arising from the inclination of its polar axis.
+
+[Illustration: Fig. 3.--Inclination of Planetary Orbits (from
+Chambers).]
+
+As the most valuable impression which the student can receive from his
+study of Nature is that sense of the order which has made possible all
+life, including his own, it will be well for him to imagine, as he may
+readily do, what would be the effect arising from changes in relations
+of earth and sun. Bringing the earth's axis in imagination into a
+position at right angles to the plane of the orbit, he will see that
+the effect would be to intensify the equatorial heat, and to rob the
+high latitudes of the share which they now have. On moving the axis
+gradually to positions where it approaches the plane of the orbit, he
+will note that each stage of the change widens the tropic belt.
+Bringing the polar axis down to the plane of the orbit, one hemisphere
+would receive unbroken sunshine, the other remaining in perpetual
+darkness and cold. In this condition, in place of an equatorial line
+we should have an equatorial point at the pole nearest the sun; thence
+the temperatures would grade away to the present equator, beyond which
+half the earth would be in more refrigerating condition than are the
+poles at the present day. In considering the movements of our planet,
+we shall see that no great changes in the position of the polar axis
+can have taken place. On this account the suggested alterations of the
+axis should not be taken as other than imaginary changes.
+
+It is easy to see that with a circular orbit and with an inclined axis
+winter and summer would normally come always at the same point in the
+orbit, and that these seasons would be of perfectly even length. But,
+as we have before noted, the earth's path around the sun is in its
+form greatly affected by the attractions which are exercised by the
+neighbouring planets, principally by those great spheres which lie in
+the realm without its orbit, Jupiter and Saturn. When these attracting
+bodies, as is the case from time to time, though at long intervals,
+are brought together somewhere near to that part of the solar system
+in which the earth is moving around the sun, they draw our planet
+toward them, and so make its path very elliptical. When, however, they
+are so distributed that their pulling actions neutralize each other,
+the orbit returns more nearly to a circular form. The range in its
+eccentricity which can be brought about by these alterations is very
+great. When the path is most nearly circular, the difference in the
+major and minor axis may amount to as little as about five hundred
+thousand miles, or about one one hundred and eighty-sixth of its
+average diameter. When the variation is greatest the difference in
+these measurements may be as much as near thirteen million miles, or
+about one seventh of the mean width of the orbit.
+
+The first and most evident effect arising from these changes of the
+orbit comes from the difference in the amount of heat which the earth
+may receive according as it is nearer or farther from the sun. As in
+the case of other fires, the nearer a body is to it the larger the
+share of light and heat which it will receive. In an orbit made
+elliptical by the planetary attraction the sun necessarily occupies
+one of the foci of the ellipse. The result is, of course, that the
+side of the earth which is toward the sun, while it is thus brought
+the nearer to the luminary, receives more energy in the form of light
+and heat than come to any part which is exposed when the spheres are
+farther away from each other in the other part of the orbit.
+Computations clearly show that the total amount of heat and the
+attendant light which the earth receives in a year is not affected by
+these changes in the form of its path. While it is true that it
+receives heat more rapidly in the half of the ellipse which is nearest
+the source of the inundation, it obtains less while it is farther
+away, and these two variations just balance each other.
+
+Although the alterations in the eccentricity of its orbit do not vary
+the annual supply of heat which the earth receives, they are capable
+of changing the character of the seasons, and this in the way which we
+will now endeavour to set forth, though we must do it at the cost of
+considerable attention on the part of the reader, for the facts are
+somewhat complicated. In the first place, we must note that the
+ellipticity of the earth's orbit is not developed on fixed lines, but
+is endlessly varied, as we can readily imagine it would be for the
+reason that its form depends upon the wandering of the outer planetary
+spheres which pull the earth about. The longer axis of the ellipse is
+itself in constant motion in the direction in which the earth travels.
+This movement is slow, and at an irregular rate. It is easy to see
+that the effect of this action, which is called the revolution of the
+apsides, or, as the word means, the movement of the poles of the
+ellipse, is to bring the earth, when a given hemisphere is turned
+toward the sun, sometimes in the part of the orbit which is nearest
+the source of light and heat, and sometimes farther away. It may thus
+well come about that at one time the summer season of a hemisphere
+arrives when it is nearest the sun, so that the season, though hot,
+will be very short, while at another time the same season will arrive
+when the earth is farthest from the sun, and receives much less heat,
+which would tend to make a long and relatively cool summer. The reason
+for the difference in length of the seasons is to be found in the
+relative swiftness of the earth's revolution when it is nearest the
+sun, and the slowness when it is farther away.
+
+There is a further complication arising from that curious phenomenon
+called the precession of the equinoxes, which has to be taken into
+account before we can sufficiently comprehend the effect of the
+varying eccentricity of the orbit on the earth's seasons. To
+understand this feature of precession we should first note that it
+means that each year the change from the winter to the summer--or, as
+we phrase it, the passage of the equinoctial line--occurs a little
+sooner than the year before. The cause of this is to be found in the
+attraction which the heavenly bodies, practically altogether the moon,
+exercises on the equatorial protuberance of the earth. We know that
+the diameter of our sphere at the equator is, on the average,
+something more than twenty-six miles greater than it is through the
+poles. We know, furthermore, that the position of the moon in relation
+to the earth is such that it causes the attraction on one half of this
+protuberance to be greater than it is upon the other. We readily
+perceive that this action will cause the polar axis to make a certain
+revolution, or, what comes to the same thing, that the plane of the
+equator will constantly be altering its position. Now, as the
+equinoctial points in the orbit depend for their position upon the
+attitude of the equatorial plane, we can conceive that the effect is a
+change in position of the place in that orbit where summer and winter
+begin. The actual result is to bring the seasonal points backward,
+step by step, through the orbit in a regular measure until in
+twenty-two thousand five hundred years they return to the place where
+they were before. This cycle of change was of old called the Annus
+Magnus, or great year.
+
+If the earth's orbit were an ellipse, the major axis of which remained
+in the same position, we could readily reckon all the effects which
+arise from the variations of the great year. But this ellipse is ever
+changing in form, and in the measure of its departure from a circle
+the effects on the seasons distributed over a great period of time are
+exceedingly irregular. Now and then, at intervals of hundreds of
+thousands or millions of years, the orbit becomes very elliptical;
+then again for long periods it may in form approach a circle. When in
+the state of extreme ellipticity, the precession of the equinoxes will
+cause the hemispheres in turn each to have their winter and summer
+alternately near and far from the sun. It is easily seen that when the
+summer season comes to a hemisphere in the part of the orbit which is
+then nearest the sun the period will be very hot. When the summer
+came farthest from the sun that part of the year would have the
+temperature mitigated by its removal to a greater distance from the
+source of heat. A corresponding effect would be produced in the winter
+season. As long as the orbit remained eccentric the tendency would be
+to give alternately intense seasons to each hemisphere through periods
+of about twelve thousand years, the other hemisphere having at the
+same time a relatively slight variation in the summer and winter.
+
+At first sight it may seem to the reader that these studies we have
+just been making in matters concerning the shape of the orbit and the
+attendant circumstances which regulate the seasons were of no very
+great consequence; but, in the opinion of some students of climate, we
+are to look to these processes for an explanation of certain climatal
+changes on the earth, including the Glacial periods, accidents which
+have had the utmost importance in the history of man, as well as of
+all the other life of the planet.
+
+It is now time to give some account as to what is known concerning the
+general conditions of the solar bodies--the planets and satellites of
+our own celestial group. For our purpose we need attend only to the
+general physical state of these orbs so far as it is known to us by
+the studies of astronomers. The nearest planet to the sun is Mercury.
+This little sphere, less than half the diameter of our earth, is so
+close to the sun that even when most favourably placed for observation
+it is visible for but a few minutes before sunrise and after sunset.
+Although it may without much difficulty be found by the ordinary eye,
+very few people have ever seen it. To the telescope when it is in the
+_full moon_ state it appears as a brilliant disk; it is held by most
+astronomers that the surface which we see is made up altogether of
+clouds, but this, as most else that has been stated concerning this
+planet, is doubtful. The sphere is so near to the sun that if it were
+possessed of water it would inevitably bear an atmosphere full of
+vapour. Under any conceivable conditions of a planet placed as
+Mercury is, provided it had an atmosphere to retain the heat, its
+temperature would necessarily be very high. Life as we know it could
+not well exist upon such a sphere.
+
+Next beyond Mercury is Venus, a sphere only a little less in diameter
+than the earth. Of this sphere we know more than we do of Mercury, for
+the reason that it is farther from the sun and so appears in the
+darkened sky. Most astronomers hold that the surface of this planet
+apparently is almost completely and continually hidden from us by what
+appears to be a dense cloud envelope, through which from time to time
+certain spots appear of a dark colour. These, it is claimed, retain
+their place in a permanent way; it is, indeed, by observing them that
+the rotation period of the planet has, according to some observers,
+been determined. It therefore seems likely that these spots are the
+summits of mountains, which, like many of our own earth, rise above
+the cloud level.
+
+Recent observations on Venus made by Mr. Percival Lowell appear to
+show that the previous determinations of the rotation of that planet,
+as well as regards its cloud wrap, are in error. According to these
+observations, the sphere moves about the sun, always keeping the same
+side turned toward the solar centre, just as the moon does in its
+motion around the earth. Moreover, Mr. Lowell has failed to discover
+any traces of clouds upon the surface of the planet. As yet these
+results have not been verified by the work of other astronomers;
+resting, however, as they do on studies made with an excellent
+telescope and in the very translucent and steady air of the Flagstaff
+Station, they are more likely to be correct than those obtained by
+other students. If it be true that Venus does not turn upon its axis,
+such is likely to be the case also with the planet Mercury.
+
+Next in the series of the planets is our own earth. As the details of
+this planet are to occupy us during nearly all the remainder of this
+work, we shall for the present pass it by.
+
+Beyond the earth we pass first to the planet Mars, a sphere which has
+already revealed to us much concerning its peculiarities of form and
+physical state, and which is likely in the future to give more
+information than we shall obtain from any other of our companions in
+space, except perhaps the moon. Mars is not only nearer to us than any
+other planet, but it is so placed that it receives the light of the
+sun under favourable conditions for our vision. Moreover, its sky
+appears to be generally almost cloudless, so that when in its orbital
+course the sphere is nearest our earth it is under favourable
+conditions for telescopic observation. At such times there is revealed
+to the astronomer a surface which is covered with an amazing number of
+shadings and markings which as yet have been incompletely interpreted.
+The faint nature of these indications has led to very contradictory
+statements as to their form; no two maps which have been drawn agree
+except in their generalities. There is reason to believe that Mars has
+an atmosphere; this is shown by the fact that in the appropriate
+season the region about either pole is covered by a white coating,
+presumably snow. This covering extends rather less far toward the
+planet's equator than does the snow sheet on our continents. Taking
+into account the colour of the coating, and the fact that it
+disappears when the summer season comes to the hemisphere in which it
+was formed, we are, in fact, forced to believe that the deposit is
+frozen water, though it has been suggested that it may be frozen
+carbonic acid. Taken in connection with what we have shortly to note
+concerning the apparent seas of this sphere, the presumption is
+overwhelmingly to the effect that Mars has seasons not unlike our own.
+
+The existence of snow on any sphere may safely be taken as evidence
+that there is an atmosphere. In the case of Mars, this supposition is
+borne out by the appearance of its surface. The ruddy light which it
+sends back to us, and the appearance on the margin of the sphere,
+which is somewhat dim, appears to indicate that its atmosphere is
+dense. In fact, the existence of an atmosphere much denser than that
+of our own earth appears to be demanded by the fact that the
+temperatures are such as to permit the coming and going of snow. It is
+well known that the temperature of any point on the earth, other
+things being equal, is proportionate to the depth of atmosphere above
+its surface. If Mars had no more air over its surface than has an
+equal area of the earth, it would remain at a temperature so low that
+such seasonal changes as we have observed could not take place. The
+planet receives one third less heat than an equal area of the earth,
+and its likeness to our own temperature, if such exists, is doubtless
+brought about by the greater density of its atmosphere, that serves to
+retain the heat which comes upon its surface. The manner in which this
+is effected will be set forth in the study of the earth's atmosphere.
+
+[Illustration: Fig. 4.--Mars, August 27, 1892 (Guiot), the white patch
+is the supposed Polar Snow Cap.]
+
+As is shown by the maps of Mars, the surface is occupied by shadings
+which seem to indicate the existence of water and lands. Those
+portions of the area which are taken to be land are very much divided
+by what appear to be narrow seas. The general geographic conditions
+differ much from those of our own sphere in that the parts of the
+planet about the water level are not grouped in great continents, and
+there are no large oceans. The only likeness to the conditions of our
+earth which we can perceive is in a general pointing of the somewhat
+triangular masses of what appears to be land toward one pole. As a
+whole, the conditions of the Martial lands and seas as regards their
+form, at least, is more like that of Europe than that of any other
+part of the earth's surface. Europe in the early Tertiary times had a
+configuration even more like that of Mars than it exhibits at present,
+for in that period the land was very much more divided than it now is.
+
+If the lands of Mars are framed as are those of our own earth, there
+should be ridges of mountains constituting what we may term the
+backbones of the continent. As yet such have not been discerned, which
+may be due to the fact that they have not been carefully looked for.
+The only peculiar physical features which have as yet been discerned
+on the lands of Mars are certain long, straight, rather narrow
+crevicelike openings, which have received the name of "canals." These
+features are very indistinct, and are just on the limit of visibility.
+As yet they have been carefully observed by but few students, so that
+their features are not yet well recorded; as far as we know them,
+these fissures have no likeness in the existing conditions of our
+earth. It is difficult to understand how they are formed or preserved
+on a surface which is evidently subjected to rainfalls.
+
+It will require much more efficient telescopes than we now have before
+it will be possible to begin any satisfactory study on the geography
+of this marvellous planet. We can not hope as yet to obtain any
+indications as to the details of its structure; we can not see closely
+enough to determine whether rivers exist, or whether there is a
+coating which we may interpret as vegetation, changing its hues in the
+different seasons of the year. An advance in our instruments of
+research during the coming century, if made with the same speed as
+during the last, will perhaps enable us to interpret the nature of
+this neighbour, and thereby to extend the conception of planetary
+histories which we derive from our own earth.
+
+[Illustration: Fig. 5.--Comparative Sizes of the Planets (Chambers).]
+
+Beyond Mars we find one of the most singular features of our solar
+system in a group of small planetary bodies, the number of which now
+known amounts to some two hundred, and the total may be far greater.
+These bodies are evidently all small; it is doubtful if the largest is
+three hundred and the smaller more than twenty miles in diameter. So
+far as it has been determined by the effect of their aggregate mass in
+attracting the other spheres, they would, if put together, make a
+sphere far less in diameter than our earth, perhaps not more than five
+hundred miles through. The forms of these asteroids is as yet unknown;
+we therefore can not determine whether their shapes are spheroidal, as
+are those of the other planets, or whether they are angular bits like
+the meteorites. We are thus not in a position to conjecture whether
+their independence began when the nebulous matter of the ring to which
+they belonged was in process of consolidation, or whether, after the
+aggregation of the sphere was accomplished, and the matter solidified,
+the mass was broken into bits in some way which we can not yet
+conceive. It has been conjectured that such a solid sphere might have
+been driven asunder by a collision with some wandering celestial body;
+but all we can conceive of such actions leads us to suppose that a
+blow of this nature would tend to melt or convert materials subjected
+to it into the state of vapour, rather than to drive them asunder in
+the manner of an explosion.
+
+The four planets which lie beyond the asteroids give us relatively
+little information concerning their physical condition, though they
+afford a wide field for the philosophic imagination. From this point
+of view the reader is advised to consult the writings of the late R.A.
+Proctor, who has brought to the task of interpreting the planetary
+conditions the skill of a well-trained astronomer and a remarkable
+constructive imagination.
+
+The planet Jupiter, by far the largest of the children of the sun,
+appears to be still in a state where its internal heat has not so far
+escaped that the surface has cooled down in the manner of our earth.
+What appear to be good observations show that the equatorial part of
+its area, at least, still glows from its own heat. The sphere is
+cloud-wrapped, but it is doubtful whether the envelope be of watery
+vapour; it is, indeed, quite possible that besides such vapour it may
+contain some part of the many substances which occupy the atmosphere
+of the sun. If the Jovian sphere were no larger than the earth, it
+would, on account of its greater age, long ago have parted with its
+heat; but on account of its great size it has been able,
+notwithstanding its antiquity, to retain a measure of temperature
+which has long since passed away from our earth.
+
+In the case of Saturn, the cloud bands are somewhat less visible than
+on Jupiter, but there is reason to suppose in this, as in the
+last-named planet, that we do not behold the more solid surface of the
+sphere, but see only a cloud wrap, which is probably due rather to the
+heat of the sphere itself than to that which comes to it from the sun.
+At the distance of Saturn from the centre of the solar system a given
+area of surface receives less than one ninetieth of the sun's heat as
+compared with the earth; therefore we can not conceive that any
+density of the atmosphere whatever would suffice to hold in enough
+temperature to produce ordinary clouds. Moreover, from time to time
+bright spots appear on the surface of the planet, which must be due to
+some form of eruptions from its interior.
+
+Beyond Saturn the two planets Uranus and Neptune, which occupy the
+outer part of the solar system, are so remote that even our best
+telescopes discern little more than their presence, and the fact that
+they have attendant moons.
+
+From the point of view of astronomical science, the outermost planet
+Neptune, of peculiar interest for the reason that it was, as we may
+say, discovered by computation. Astronomers had for many years
+remarked the fact that the next inner planetary sphere exhibited
+peculiarities in its orbit which could only be accounted for on the
+supposition that it was subjected to the attraction of another
+wandering body which had escaped observation. By skilful computation
+the place in the heavens in which this disturbing element lay was so
+accurately determined that when the telescope was turned to the given
+field a brief study revealed the planet. Nothing else in the history
+of the science of astronomy, unless it be the computation of eclipses,
+so clearly and popularly shows the accuracy of the methods by which
+the work of that science may be done.
+
+As we shall see hereafter, in the chapters which are devoted to
+terrestrial phenomena, the physical condition of the sun determines
+the course of all the more important events which take place on the
+surface of the earth. It is therefore fit that in this preliminary
+study of the celestial bodies, which is especially designed to make
+the earth more interpretable to us, we should give a somewhat special
+attention to what is known under the title of "Solar Physics."
+
+The reader has already been told that the sun is one of many million
+similar bodies which exist in space, and, furthermore, that these
+aggregations of matter have been developed from an original nebulous
+condition. The facts indicate that the natural history of the sun, as
+well as that of its attendant spheres, exhibits three momentous
+stages: First, that of vapour; second, that of igneous fluidity;
+third, that in which the sphere is so far congealed that it becomes
+dark. Neither of these states is sharply separated from the other; a
+mass may be partly nebulous and partly fluid; even when it has been
+converted into fluid, or possibly into the solid state, it may still
+retain on the exterior some share of its original vaporous condition.
+In our sun the concentration has long since passed beyond the limits
+of the nebulous state; the last of the successively developed rings
+has broken, and has formed itself into the smallest of the planets,
+which by its distance from the sun seems to indicate that the process
+of division by rings long ago attained in our solar system its end,
+the remainder of its nebulous material concentrating on its centre
+without sign of any remaining tendency to produce these planet-making
+circles.
+
+
+                   THE CONSTITUTION OF THE SUN.
+
+Before the use of the telescope in astronomical work, which was begun
+by the illustrious Galileo in 1608, astronomers were unable to
+approach the problem of the structure of the sun. They could discern
+no more than can be seen by any one who looks at the great sphere
+through a bit of smoked glass, as we know this reveals a disklike body
+of very uniform appearance. The only variation in this simple aspect
+occurs at the time of a total eclipse, when for a minute or two the
+moon hides the whole body of the sun. On such occasions even the
+unaided eye can see that there is about the sphere a broad, rather
+bright field, of an aspect like a very thin cloud or fog, which rises
+in streamer like projections at points to a quarter of a million miles
+or more above the surface of the sphere. The appearance of this
+shining field, which is called the corona, reminds one of the aurora
+which glows in the region about either pole of the earth.
+
+One of the first results of the invention of the telescope was the
+revelation of the curious dark objects on the sun's disk, known by the
+name of spots from the time of their discovery, or, at least, from the
+time when it was clearly perceived that they were not planets, but
+really on the solar body. The interest in the constitution of the
+sphere has increased during the last fifty years. This interest has
+rapidly grown until at the present time a vast body of learning has
+been gathered for the solution of the many problems concerning the
+centre of our system. As yet there is great divergence in the views of
+astronomers as to the interpretation of their observations, but
+certain points of great general interest have been tolerably well
+determined. These may be briefly set forth by an account of what would
+meet the eye if an observer were able to pass from the surface of the
+earth to the central part of the sun.
+
+[Illustration: _Lava stream, in Hawaiian Islands, flowing into the
+sea. Note the "ropy" character of the half-frozen rock on the sides of
+the nearest rivulet of the lava._]
+
+In passing from the earth to a point about a quarter of a million
+miles from the sun's surface--a distance about that of the moon from
+our sphere--the observer would traverse the uniformly empty spaces of
+the heavens, where, but for the rare chance of a passing meteorite or
+comet, there would be nothing that we term matter. Arriving at a point
+some two or three hundred thousand miles from the body of the sun, he
+would enter the realm of the corona; here he would find scattered
+particles of matter, the bits so far apart that there would perhaps be
+not more than one or two in the cubic mile; yet, as they would glow
+intensely in the central light, they would be sufficient to give the
+illumination which is visible in an eclipse. These particles are most
+likely driven up from the sun by some electrical action, and are
+constantly in motion, much as are the streamers of the aurora.
+
+Below the corona and sharply separated from it the observer finds
+another body of very dense vapour, which is termed the chromosphere,
+and which has been regarded as the atmosphere of the sun. This layer
+is probably several thousand miles thick. From the manner in which it
+moves, in the way the air of our own planet does in great storms, it
+is not easy to believe that it is a fluid, yet its sharply defined
+upper surface leads us to suppose that it can not well be a mere mass
+of vapour. The spectroscope shows us that this chromosphere contains
+in the state of vapour a number of metallic substances, such as iron
+and magnesium. To an observer who could behold this envelope of the
+sun from the distance at which we see the moon, the spectacle would be
+more magnificent than the imagination, guided by the sight of all the
+relatively trifling fractures of our earth, can possibly conceive.
+From the surface of the fiery sea vast uprushes of heated matter rise
+to the height of two or three hundred thousand miles, and then fall
+back upon its surface. These jets of heated matter have the aspect of
+flames, but they would not be such in fact, for the materials are not
+burning, but merely kept at a high temperature by the heat of the
+great sphere beneath. They spring up with such energy that they at
+times move with a speed of one hundred and fifty miles a second, or at
+a rate which is attained by no other matter in the visible universe,
+except that strange, wandering star known to astronomers as
+"Grombridge, 1830," which is traversing the firmament with a speed of
+not less than two hundred miles a second.
+
+Below the chromosphere is the photosphere, the lower envelope of the
+sun, if it be not indeed the body of the sphere itself; from this
+comes the light and heat of the mass. This, too, can not well be a
+firm-set mass, for the reason that the spots appear to form in and
+move over it. It may be regarded as an extremely dense mass of gas, so
+weighed down by the vast attraction of the great sphere below it that
+it is in effect a fluid. The near-at-hand observer would doubtless
+find this photosphere, as it appears in the telescope, to be sharply
+separated from the thinner and more vaporous envelopes--the
+chromosphere and the corona--which are, indeed, so thin that they are
+invisible even with the telescope, except when the full blaze of the
+sun is cut off in a total eclipse. The fact that the photosphere,
+except when broken by the so-called spots, lies like a great smooth
+sea, with no parts which lie above the general line, shows that it has
+a very different structure from the envelope which lies upon it. If
+they were both vaporous, there would be a gradation between them.
+
+On the surface of the photosphere, almost altogether within thirty
+degrees of the equator of the sun, a field corresponding approximately
+to the tropical belt of the earth, there appear from time to time the
+curious disturbances which are termed spots. These appear to be
+uprushes of matter in the gaseous state, the upward movement being
+upon the margins of the field and a downward motion taking place in
+the middle of the irregular opening, which is darkened in its central
+part, thus giving it, when seen by an ordinary telescope, the aspect
+of a black patch on the glowing surface. These spots, which are from
+some hundred to some thousand miles in diameter, may endure for
+months before they fade away. It is clear that they are most abundant
+at intervals of about eleven years, the last period of abundance being
+in 1893. The next to come may thus be expected in 1904. In the times
+of least spotting more than half the days of a year may pass without
+the surface of the photosphere being broken, while in periods of
+plenty no day in the year is likely to fail to show them.
+
+[Illustration: Fig. 6.--Ordinary Sun-spot, June 22, 1885.]
+
+It is doubtful if the closest seeing would reveal the cause of the
+solar spots. The studies of the physicists who have devoted the most
+skill to the matter show little more than that they are tumults in the
+photosphere, attended by an uprush of vapours, in which iron and other
+metals exist; but whether these movements are due to outbreaks from
+the deeper parts of the sun or to some action like the whirling storms
+of the earth's atmosphere is uncertain. It is also uncertain what
+effect these convulsions of the sun have on the amount of the heat and
+light which is poured forth from the orb. The common opinion that the
+sun-spot years are the hottest is not yet fully verified.
+
+Below the photosphere lies the vast unknown mass of the unseen solar
+realm. It was at one time supposed that the dark colour of the spots
+was due to the fact that the photosphere was broken through in those
+spaces, and that we looked down through them upon the surface of the
+slightly illuminated central part of the sphere. This view is
+untenable, and in its place we have to assume that for the eight
+hundred and sixty thousand miles of its diameter the sun is composed
+of matter such as is found in our earth, but throughout in a state of
+heat which vastly exceeds that known on or in our planet. Owing to its
+heat, this matter is possibly not in either the solid or the fluid
+state, but in that of very compressed gases, which are kept from
+becoming solid or even fluid by the very high temperature which exists
+in them. This view is apparently supported by the fact that, while the
+pressure upon its matter is twenty-seven times greater in the sun than
+it is in the earth, the weight of the whole mass is less than we
+should expect under these conditions.
+
+As for the temperature of the sun, we only know that it is hot enough
+to turn the metals into gases in the manner in which this is done in a
+strong electric arc, but no satisfactory method of reckoning the scale
+of this heat has been devised. The probabilities are to the effect
+that the heat is to be counted by the tens of thousands of degrees
+Fahrenheit, and it may amount to hundreds of thousands; it has,
+indeed, been reckoned as high as a million degrees. This vast
+discharge is not due to any kind of burning action--i.e., to the
+combustion of substances, as in a fire. It must be produced by the
+gradual falling in of the materials, due to the gravitation of the
+mass toward its centre, each particle converting its energy of
+position into heat, as does the meteorite when it comes into the air.
+
+It is well to close this very imperfect account of the learning which
+relates to the sun with a brief tabular statement showing the relative
+masses of the several bodies of the solar system. It should be
+understood that by mass is meant not the bulk of the object, but the
+actual amount of matter in it as determined by the gravitative
+attraction which it exercises on other celestial bodies. In this test
+the sun is taken as the measure, and its mass is for convenience
+reckoned at 1,000,000,000.
+
+
+             TABLE OF RELATIVE MASSES OF SUN AND PLANETS.[2]
+    +------------------------------------------------------------+
+    |  The sun                                    1,000,000,000  |
+    |  Mercury                                              200  |
+    |  Venus                                              2,353  |
+    |  Earth                                              3,060  |
+    |  Mars                                                 339  |
+    |  Asteroids                                              ?  |
+    |  Saturn                                           285,580  |
+    |  Jupiter                                          954,305  |
+    |  Uranus                                            44,250  |
+    |  Neptune                                           51,600  |
+    |    Combined mass of the four inner planets          5,952  |
+    |    Combined mass of all the planets             1,341,687  |
+    +------------------------------------------------------------+
+
+[Footnote 2: See Newcomb's Popular Astronomy, p. 234. Harper Brothers,
+New York.]
+
+
+It thus appears that the mass of all the planets is about one seven
+hundredth that of the sun.
+
+Those who wish to make a close study of celestial geography will do
+well to procure the interesting set of diagrams prepared by the late
+James Freeman Clarke, in which transparencies placed in a convenient
+lantern show the grouping of the important stars in each
+constellation. The advantage of this arrangement is that the little
+maps can be consulted at night and in the open air in a very
+convenient manner. After the student has learned the position of a
+dozen of the constellations visible in the northern hemisphere, he can
+rapidly advance his knowledge in the admirable method invented by Dr.
+Clarke.
+
+Having learned the constellations, the student may well proceed to
+find the several planets, and to trace them in their apparent path
+across the fixed stars. It will be well for him here to gain if he can
+the conception that their apparent movement is compounded of their
+motion around the sun and that of our own sphere; that it would be
+very different if our earth stood still in the heavens. At this stage
+he may well begin to take in mind the evidence which the planetary
+motion supplies that the earth really moves round the sun, and not
+the sun and planets round the earth. This discovery was one of the
+great feats of the human mind; it baffled the wits of the best men for
+thousands of years. Therefore the inquirer who works over the evidence
+is treading one of the famous paths by which his race climbed the
+steeps of science.
+
+The student must not expect to find the evidence that the sun is the
+centre of the solar system very easy to interpret; and yet any youth
+of moderate curiosity, and that interest in the world about him which
+is the foundation of scientific insight, can see through the matter.
+He will best begin his inquiries by getting a clear notion of the fact
+that the moon goes round the earth. This is the simplest case of
+movements of this nature which he can see in the solar system. Noting
+that the moon occupies a different place at a given hour in the
+twenty-four, but is evidently at all times at about the same distance
+from the earth, he readily perceives that it circles about our sphere.
+This the people knew of old, but they made of it an evidence that the
+sun also went around our sphere. Here, then, is the critical point.
+Why does the sun not behave in the same manner as the moon? At this
+stage of his inquiry the student best notes what takes place in the
+motions of the planets between the earth and the sun. He observes that
+those so-called inferior planets Mercury and Venus are never very far
+away from the central body; that they appear to rise up from it, and
+then to go back to it, and that they have phases like the moon. Now
+and then Venus may be observed as a black spot crossing the disk of
+the sun. A little consideration will show that on the theory that
+bodies revolve round each other in the solar system these movements of
+the inner planets can only be explained on the supposition that they
+at least travel around the great central fire. Now, taking up the
+outer planets, we observe that they occasionally appear very bright,
+and that they are then at a place in the heavens where we see that
+they are far from the solar centre. Gradually they move down toward
+the sunset and disappear from view. Here, too, the movement, though
+less clearly so, is best reconcilable with the idea that these bodies
+travel in orbits, such as those which are traversed by the inner
+planets. The wonder is that with these simple facts before them, and
+with ample time to think the matter over, the early astronomers did
+not learn the great truth about the solar system--namely, that the sun
+is the centre about which the planets circled. Their difficulty lay
+mainly in the fact that they did not conceive the earth as a sphere,
+and even after they attained that conception they believed that our
+globe was vastly larger than the planets, or even than the sun. This
+misconception kept even the thoughtful Greeks, who knew that the earth
+was spherical in form, from a clear notion as to the structure of our
+system. It was not, indeed, until mathematical astronomy attained a
+considerable advance, and men began to measure the distances in the
+solar system, and until the Newtonian theory of gravitation was
+developed, that the planetary orbits and the relation of the various
+bodies in the solar system to each other could be perfectly discerned.
+
+Care has been taken in the above statements to give the student
+indices which may assist him in working out for himself the evidence
+which may properly lead a person, even without mathematical
+considerations of a formal kind, to construct a theory as to the
+relation of the planets to the sun. It is not likely that he can go
+through all the steps of this argument at once, but it will be most
+useful to him to ponder upon the problem, and gradually win his way to
+a full understanding of it. With that purpose in mind, he should avoid
+reading what astronomers have to say on the matter until he is
+satisfied that he has done as much as he can with the matter on his
+own account. He should, however, state his observations, and as far as
+possible draw the results in his note-book in a diagrammatic form. He
+should endeavour to see if the facts are reconcilable with any other
+supposition than that the earth and the other planets move around the
+sun. When he has done his task, he will have passed over one of the
+most difficult roads which his predecessors had to traverse on their
+way to an understanding of the heavens. Even if he fail he will have
+helped himself to some large understandings.
+
+The student will find it useful to make a map of the heavens, or
+rather make several representing their condition at different times in
+the year. On this plot he should put down only the stars whose places
+and names he has learned, but he should plot the position of the
+planets at different times. In this way, though at first his efforts
+will be very awkward, he will soon come to know the general geography
+of the heavens.
+
+Although the possession or at least the use of a small astronomical
+telescope is a great advantage to a student after he has made a
+certain advance in his work, such an instrument is not at all
+necessary, or, indeed, desirable at the outset of his studies. An
+ordinary opera-glass, however, will help him in picking out the stars
+in the constellations, in identifying the planets, and in getting a
+better idea as to the form of the moon's surface--a matter which will
+be treated in this work in connection with the structure of the earth.
+
+
+
+
+                            CHAPTER IV.
+
+                             THE EARTH.
+
+
+In beginning the study of the earth it is important that the student
+should at once form the habit of keeping in mind the spherical form of
+the planet. Many persons, while they may blindly accept the fact that
+the earth is a sphere, do not think of it as having that form. Perhaps
+the simplest way of securing the correct image of the shape is to
+imagine how the earth would appear as seen from the moon. In its full
+condition the moon is apt to appear as a disk. When it is new, and
+also when in its waning stages it is visible in the daytime, the
+spherical form is very apparent. Imagining himself on the surface of
+the moon, the student can well perceive how the earth would appear as
+a vast body in the heavens; its eight thousand miles of diameter,
+about four times that of the satellite, would give an area sixteen
+times the size which the moon presents to us. On this scale the
+continents and oceans would appear very much more plain than do the
+relatively slight irregularities on the lunar surface.
+
+With the terrestrial globe in hand, the student can readily construct
+an image which will represent, at least in outline, the appearance
+which the sphere he inhabits would present when seen from a distance
+of about a quarter of a million miles away. The continent of
+Europe-Asia would of itself appear larger than all the lunar surface
+which is visible to us. Every continent and all the greater islands
+would be clearly indicated. The snow covering which in the winter of
+the northern hemisphere wraps so much of the land would be seen to
+come and go in the changes of the seasons; even the permanent ice
+about either pole, and the greater regions of glaciers, such as those
+of the Alps and the Himalayas, would appear as brilliant patches of
+white amid fields of darker hue. Even the changes in the aspect of the
+vegetation which at one season clothes the wide land with a green
+mantle, and at another assumes the dun hue of winter, would be, to the
+unaided eye, very distinct. It is probable that all the greater rivers
+would be traceable as lines of light across the relatively dark
+surface of the continents. By such exercises of the constructive
+imagination--indeed, in no other way--the student can acquire the
+habit of considering the earth as a vast whole. From time to time as
+he studies the earth from near by he should endeavour to assemble the
+phenomena in the general way which we have indicated.
+
+The reader has doubtless already learned that the earth is a slightly
+flattened sphere, having an average diameter of about eight thousand
+miles, the average section at the equator being about twenty-six miles
+greater than that from pole to pole. In a body of such large
+proportions this difference in measurement appears not important; it
+is, however, most significant, for it throws light upon the history of
+the earth's mass. Computation shows that the measure of flattening at
+the poles is just what would occur if the earth were or had been at
+the time when it assumed its present form in a fluid condition. We
+readily conceive that a soft body revolving in space, while all its
+particles by gravitation tended to the centre, would in turning
+around, as our earth does upon its axis, tend to bulge out in those
+parts which were remote from the line upon which the turning took
+place. Thus the flattening of our sphere at the poles corroborates the
+opinion that its mass was once molten--in a word, that its ancient
+history was such as the nebular theory suggests.
+
+Although we have for convenience termed the earth a flattened
+spheroid, it is only such in a very general sense. It has an infinite
+number of minor irregularities which it is the province of the
+geographer to trace and that of the geologist to account for. In the
+first place, its surface is occupied by a great array of ridges and
+hollows. The larger of these, the oceans and continents, first deserve
+our attention. The difference in altitude of the earth's surface from
+the height of the continents to the deepest part of the sea is
+probably between ten and eleven miles, thus amounting to about two
+fifths of the polar flattening before noted. The average difference
+between the ocean floor and the summits of the neighbouring continents
+is probably rather less than four miles. It happens, most fortunately
+for the history of the earth, that the water upon its surface fills
+its great concavities on the average to about four fifths of their
+total depth, leaving only about one fifth of the relief projecting
+above the ocean level. We have termed this arrangement fortunate, for
+it insures that rainfall visits almost all the land areas, and thereby
+makes those realms fit for the uses of life. If the ocean had only
+half its existing area, the lands would be so wide that only their
+fringes would be fertile. If it were one fifth greater than it is, the
+dry areas would be reduced to a few scattered islands.
+
+From all points of view the most important feature of the earth's
+surface arises from its division into land and water areas, and this
+for the reason that the physical and vital work of our sphere is
+inevitably determined by this distribution. The shape of the seas and
+lands is fixed by the positions at which the upper level of the great
+water comes against the ridges which fret the earth's surface. These
+elevations are so disposed that about two thirds of the hard mass is
+at the present time covered with water, and only one third exposed to
+the atmosphere. This proportion is inconstant. Owing to the endless
+up-and-down goings of the earth's surface, the place of the shore
+lines varies from year to year, and in the geological ages great
+revolutions in the forms and relative area of water and land are
+brought about.
+
+Noting the greater divisions of land and water as they are shown on a
+globe, we readily perceive that those parts of the continental ridges
+which rise above the sea level are mainly accumulated in the northern
+hemisphere--in fact, far more than half the dry realm is in that part
+of the world. We furthermore perceive that all the continents more or
+less distinctly point to the southward; they are, in a word,
+triangles, with their bases to the northward, and their apices,
+usually rather acute, directed to the southward. This form is very
+well indicated in three of the great lands, North and South America
+and Africa; it is more indistinctly shown in Asia and in Australia. As
+yet we do not clearly understand the reason why the continents are
+triangular, why they point toward the south pole, or why they are
+mainly accumulated in the northern hemisphere. As stated in the
+chapter on astronomy, some trace of the triangular form appears in the
+land masses of the planet Mars. There, too, these triangles appear to
+point toward one pole.
+
+Besides the greater lands, the seas are fretted by a host of smaller
+dry areas, termed islands. These, as inquiry has shown, are of two
+very diverse natures. Near the continents, practically never more than
+a thousand miles from their shores, we find isles, often of great
+size, such as Madagascar, which in their structure are essentially
+like the continents--that is, they are built in part or in whole of
+non-volcanic rocks, sandstones, limestones, etc. In most cases these
+islands, to which we may apply the term continental, have at some time
+been connected with the neighbouring mainland, and afterward separated
+from it by a depression of the surface which permitted the sea to flow
+over the lowlands. Geologists have traced many cases where in the past
+elevations which are now parts of a continent were once islands next
+its shore. In the deeper seas far removed from the margins of the
+continents the islands are made up of volcanic ejections of lava,
+pumice, and dust, which has been thrown up from craters and fallen
+around their margin or are formed of coral and other organic remains.
+
+Next after this general statement as to the division of sea and land
+we should note the peculiarities which the earth's surface exhibits
+where it is bathed by the air, and where it is covered by the water.
+Beginning with the best-known region, that of the dry land, we observe
+that the surface is normally made up of continuous slopes of varying
+declivity, which lead down from the high points to the sea. Here and
+there, though rarely, these slopes centre in a basin which is occupied
+by a lake or a dead sea. On the deeper ocean floors, so far as we may
+judge with the defective information which the plumb line gives us,
+there is no such continuity in the downward sloping of the surface,
+the area being cast into numerous basins, each of great extent.
+
+When we examine in some detail the shape of the land surface, we
+readily perceive that the continuous down slopes are due to the
+cutting action of rivers. In the basin of a stream the waters act to
+wear away the original heights, filling them into the hollows, until
+the whole area has a continuous down grade to the point where the
+waters discharge into the ocean or perhaps into a lake. On the bottom
+of the sea, except near the margin of the continent, where the floor
+may in recent geological times have been elevated into the air, and
+thus exposed to river action, there is no such agent working to
+produce continuous down grades.
+
+Looking upon a map of a continent which shows the differences in
+altitude of the land, we readily perceive that the area is rather
+clearly divided into two kinds of surface, mountains and plains, each
+kind being sharply distinguished from the other by many important
+peculiarities. Mountains are characteristically made up of distinct,
+more or less parallel ridges and valleys, which are grouped in very
+elongated belts, which, in the case of the American Cordilleras,
+extend from the Arctic to the Antarctic Circle. Only in rare instances
+do we find mountains occupying an area which is not very distinctly
+elongated, and in such cases the elevations are usually of no great
+height. Plains, on the other hand, commonly occupy the larger part of
+the continent, and are distributed around the flanks of the mountain
+systems. There is no rule as to their shape; they normally grade away
+from the bases of the mountains toward the sea, and are often
+prolonged below the level of the water for a considerable distance
+beyond the shore, forming what is commonly known as the continental
+shelf or belt of shallows along the coast line. We will now consider
+some details concerning the form and structure of mountains.
+
+In almost any mountain region a glance over the surface of the country
+will give the reader a clew to the principal factor which has
+determined the existence of these elevations. Wherever the bed rocks
+are revealed he will recognise the fact that they have been much
+disturbed. Almost everywhere the strata are turned at high angles;
+often their slopes are steeper than those of house roofs, and not
+infrequently they stand in attitudes where they appear vertical. Under
+the surface of plains bedded rocks generally retain the nearly
+horizontal position in which all such deposits are most likely to be
+found. If the observer will attentively study the details of position
+of these tilted rocks of mountainous districts, he will in most cases
+be able to perceive that the beds have been flexed or folded in the
+manner indicated by the diagram. Sometimes, though rarely, the tops of
+these foldings or arches have been preserved, so that the nature of
+the movement can be clearly discerned. More commonly the upper parts
+of the upward-arching strata have been cut off by the action of the
+decay-bringing forces--frost, flowing water, or creeping ice in
+glaciers--so that only the downward pointing folds which were formed
+in the mountain-making are well preserved, and these are almost
+invariably hidden within the earth.
+
+[Illustration: Fig. 7.--Section of mountains. Rockbridge and Bath
+counties, Va. (from Dana). The numbers indicate the several
+formations.]
+
+By walking across any considerable mountain chain, as, for instance,
+that of the Alleghanies, it is generally possible to trace a number of
+these parallel up-and-down folds of the strata, so that we readily
+perceive that the original beds had been packed together into a much
+less space than they at first occupied. In some cases we could prove
+that the shortening of the line has amounted to a hundred miles or
+more--in other words, points on the plain lands on either side of the
+mountain range which now exists may have been brought a hundred miles
+or so nearer together than they were before the elevations were
+produced. The reader can make for himself a convenient diagram showing
+what occurred by pressing a number of leaves of this book so that the
+sheets of paper are thrown into ridges and furrows. By this experiment
+he also will see that the easiest way to account for such foldings as
+we observe in mountains is by the supposition that some force residing
+in the earth tends to shove the beds into a smaller space than they
+originally occupied. Not only are the rocks composing the mountains
+much folded, but they are often broken through after the manner of
+masonry which has been subjected to earthquake shocks, or of ice which
+has been strained by the expansion that affects it as it becomes
+warmed before it is melted. In fact, many of our small lakes in New
+England and in other countries of a long winter show in a miniature
+way during times of thawing ice folds which much resemble mountain
+arches.
+
+At first geologists were disposed to attribute all the phenomena of
+mountain-folding to the progressive cooling of the earth. Although
+this sphere has already lost a large part of the heat with which it
+was in the beginning endowed, it is still very hot in its deeper
+parts, as is shown by the phenomena of volcanoes. This internal heat,
+which to the present day at the depth of a hundred miles below the
+surface is probably greater than that of molten iron, is constantly
+flowing away into space; probably enough of it goes away on the
+average each day to melt a hundred cubic miles or more of ice, or, in
+more scientific phrase, the amount of heat rendered latent by melting
+that volume of frozen water. J.R. Meyer, an eminent physicist,
+estimated the quantity of heat so escaping each day of the year to be
+sufficient to melt two hundred and forty cubic miles of ice. The
+effect of this loss of heat is constantly to shrink the volume of the
+earth; it has, indeed, been estimated that the sphere on this account
+contracts on the average to the amount of some inches each thousand
+years. For the reason that almost all this heat goes from the depths
+of the earth, the cool outer portion losing no considerable part of
+it, the contraction that is brought about affects the interior
+portions of the sphere alone. The inner mass constantly shrinking as
+it loses heat, the outer, cold part is by its weight forced to settle
+down, and can only accomplish this result by wrinkling. An analogous
+action may be seen where an apple or a potato becomes dried; in this
+case the hard outer rind is forced to wrinkle, because, losing no
+water, it does not diminish in its extent, and can only accommodate
+itself to the interior by a wrinkling process. In one case it is water
+which escapes, in the other heat; but in both contraction of the part
+which suffers the loss leads to the folding of the outside of the
+spheroid.
+
+Although this loss of heat on the part of the earth accounts in some
+measure for the development of mountains, it is not of itself
+sufficient to explain the phenomena, and this for the reason that
+mountains appear in no case to develop on the floors of the wide sea.
+The average depth of the ocean is only fifteen thousand feet, while
+there are hundreds, if not thousands, of mountain crests which exceed
+that height above the sea. Therefore if mountains grew on the sea
+floor as they do upon the land, there should be thousands of peaks
+rising above the plain of the waters, while, in fact, all of the
+islands except those near the shores of continents are of volcanic
+origin--that is, are lands of totally different nature.
+
+Whenever a considerable mountain chain is formed, although the actual
+folding of the beds is limited to the usually narrow field occupied by
+these disturbances, the elevation takes place over a wide belt of
+country on one or both sides of the range. Thus if we approach the
+Rocky Mountains from the Mississippi Valley, we begin to mount up an
+inclined plane from the time we pass westward from the Mississippi
+River. The beds of rock as well as the surface rises gradually until
+at the foot of the mountain; though the rocks are still without
+foldings, they are at a height of four or five thousand feet above the
+sea. It seems probable--indeed, we may say almost certain--that when
+the crust is broken, as it is in mountain-building, by extensive folds
+and faults, the matter which lies a few score miles below the crust
+creeps in toward those fractures, and so lifts up the country on which
+they lie. When we examine the forms of any of our continents, we find
+that these elevated portions of the earth's crust appear to be made up
+of mountains and the table-lands which fringe those elevations. There
+is not, as some of our writers suppose, two different kinds of
+elevation in our great lands--the continents and the mountains which
+they bear--but one process of elevation by which the foldings and the
+massive uplifts which constitute the table-lands are simultaneously
+and by one process formed.
+
+Looking upon continents as the result of mountain growth, we may say
+that here and there on the earth's crust these dislocations have
+occurred in such association and of such magnitude that great areas
+have been uplifted above the plain of the sea. In general, we find
+these groups of elevations so arranged that they produce the
+triangular form which is characteristic of the great lands. It will be
+observed, for instance, that the form of North America is in general
+determined by the position of the Appalachian and Cordilleran systems
+on its eastern and western margins, though there are a number of
+smaller chains, such as the Laurentians in Canada and the ice-covered
+mountains of Greenland, which have a measure of influence in fixing
+its shore lines.
+
+[Illustration: _Waterfall near Gadsden, Alabama. The upper shelf of
+rock is a hard sandstone, the lower beds are soft shale. The
+conditions are those of most waterfalls, such as Niagara._]
+
+The history of plains, as well as that of mountains, will have further
+light thrown upon it when in the next chapter we come to consider the
+effect of rain water on the land. We may here note the fact that the
+level surfaces which are above the seashores are divisible into two
+main groups--those which have been recently lifted above the sea
+level, composed of materials laid down in the shallows next the shore,
+and which have not yet shared in mountain-building disturbances, and
+those which have been slightly tilted in the manner before indicated
+in the case of the plains which border the Rocky Mountains on the
+east. The great southern plain of eastern and southern United States,
+extending from near New York to Mexico, is a good specimen of the
+level lands common on all the continents which have recently emerged
+from the sea. The table-lands on either side of the Mississippi
+Valley, sloping from the Alleghanies and the Cordilleras, represent
+the more ancient type of plain which has already shared in the
+elevation which mountain-building brings about. In rarer cases plains
+of small area are formed where mountains formerly existed by the
+complete moving down of the original ridges.
+
+There is a common opinion that the continents are liable in the course
+of the geologic ages to very great changes of position; that what is
+now sea may give place to new great lands, and that those already
+existing may utterly disappear. This opinion was indeed generally held
+by geologists not more than thirty years ago. Further study of the
+problem has shown us that while parts of each continent may at any
+time be depressed beneath the sea, the whole of its surface rarely if
+ever goes below the water level. Thus, in the case of North America,
+we can readily note very great changes in its form since the land
+began to rise above the water. But always, from that ancient day to
+our own, some portion of the area has been above the level of the sea,
+thus providing an ark of refuge for the land life when it was
+disturbed by inundations. The strongest evidence in favour of the
+opinion that the existing continents have endured for many million
+years is found in the fact that each of the great lands preserves many
+distinct groups of animals and plants which have descended from
+ancient forms dwelling upon the same territory. If at any time the
+relatively small continent of Australia had gone beneath the sea, all
+of the curious pouched animals akin to the opossum and kangaroo which
+abound in that country--creatures belonging in the ancient life of the
+world--would have been overwhelmed.
+
+We have already noted the fact that the uplifting of mountains and of
+the table-lands about them, which appears to have been the basis of
+continental growth, has been due to strains in the rocks sufficiently
+strong to disturb the beds. At each stage of the mountain-building
+movement these compressive strains have had to contend with the very
+great weight of the rocks which they had to move. These lands are not
+to be regarded as firm set or rigid arches, but as highly elastic
+structures, the shapes of which may be determined by any actions which
+put on or take off burden. We see a proof of this fact from numerous
+observations which geologists are now engaged in making. Thus during
+the last ice epoch, when almost all the northern part of this
+continent, as well as the northern part of Europe, was covered by an
+ice sheet several thousand feet thick, the lands sank down under their
+load, and to an extent roughly proportional to the depth of the icy
+covering. While the northern regions were thus tilted down by the
+weight which was upon them, the southern section of this land, the
+region about the Gulf of Mexico, was elevated much above its present
+level; it seems likely, indeed, that the peninsula of Florida rose to
+the height of several hundred feet above its present shore line. After
+the ice passed away the movements were reversed, the northern region
+rising and the southern sinking down. These movements are attested by
+the position of the old shore lines formed during the later stages of
+the Glacial epoch. Thus around Lake Ontario, as well as the other
+Great Lakes, the beaches which mark the higher positions of those
+inland seas during the closing stages of the ice time, and which, of
+course, were when formed horizontal, now rise to the northward at the
+rate of from two to five feet for each mile of distance. Recent
+studies by Mr. G.K. Gilbert show that this movement is still in
+progress.
+
+Other evidence going to show the extent to which the movements of the
+earth's crust are affected by the weight of materials are found in the
+fact that wherever along the shores thick deposits of sediments are
+accumulated the tendency of the region where they lie is gradually to
+sink downward, so that strata having an aggregate thickness of ten
+thousand feet or more may be accumulated in a sea which was always
+shallow. The ocean floor, in general, is the part of the earth's
+surface where strata are constantly being laid down. In the great
+reservoir of the waters the _débris_ washed from the land, the dust
+from volcanoes, and that from the stellar spaces, along with the vast
+accumulation of organic remains, almost everywhere lead to the
+steadfast accumulation of sedimentary deposits. On the other hand, the
+realms of the surface above the ocean level are constantly being worn
+away by the action of the rivers and glaciers, of the waves which beat
+against the shores, and of the winds which blow over desert regions.
+The result is that the lands are wearing down at the geologically
+rapid average rate of somewhere about one foot in five thousand years.
+All this heavy matter goes to the sea bottoms. Probably to this cause
+we owe in part the fact that in the wrinklings of the crust due to the
+contraction of the interior the lands exhibit a prevailing tendency to
+uprise, while the ocean floors sink down. In this way the continents
+are maintained above the level of the sea despite the powerful forces
+which are constantly wearing their substance away, while the seas
+remain deep, although they are continually being burdened with
+imported materials.
+
+[Illustration: Fig. 8.--Diagram showing the effect of the position of
+the fulcrum point in the movement of the land masses. In diagrams I
+and II, the lines _a b_ represent the land before the movement, and
+_a' b'_ its position after the movement; _s_, _s_, the position of the
+shore line; _p_, _p_, the pivotal points; _l_, _s_, the sea line. In
+diagram III, the curved line designates a shore; the line _a b_,
+connecting the pivotal points _p_, _p_, is partly under the land and
+partly under the sea.]
+
+It is easy to see that if the sea floors tend to sink downward, while
+the continental lands uprise, the movements which take place may be
+compared with those which occur in a lever about a fulcrum point. In
+this case the sea end of the bar is descending and the land end
+ascending. Now, it is evident that the fulcrum point may fall to the
+seaward or to the landward of the shore; only by chance and here and
+there would it lie exactly at the coast line. By reference to the
+diagram (Fig. 8), it will be seen that, while the point of rotation is
+just at the shore, a considerable movement may take place without
+altering the position of the coast line. Where the point of no
+movement is inland of the coast, the sea will gain on the continent;
+where, however, the point is to seaward, beneath the water, the land
+will gain on the ocean. In this way we can, in part at least, account
+for the endless changes in the attitude of the land along the coastal
+belt without having to suppose that the continents cease to rise or
+the sea floors to sink downward. It is evident that the bar or section
+of the rocks from the interior of the land to the bottoms of the seas
+is not rigid; it is also probable that the matter in the depths of the
+earth, which moves with the motions of this bar, would change the
+position of the fulcrum point from time to time. Thus it may well come
+about that our coast lines are swaying up and down in ceaseless
+variation.
+
+In very recent geological times, probably since the beginning of the
+last Glacial period, the region about the Dismal Swamp in Virginia has
+swayed up and down through four alternating movements to the extent of
+from fifty to one hundred feet. The coast of New Jersey is now sinking
+at the rate of about two feet in a hundred years. The coast of New
+England, though recently elevated to the extent of a hundred feet or
+more, at a yet later time sank down, so that at some score of points
+between New York and Eastport, Me., we find the remains of forests
+with the roots of their trees still standing below high-tide mark in
+positions where the trees could not have grown. Along all the marine
+coasts of the world which have been carefully studied from this point
+of view there are similar evidences of slight or great modern changes
+in the level of the lands. At some points, particularly on the coast
+of Alaska and along the coast of Peru, these uplifts of the land have
+amounted to a thousand feet or more. In the peninsular district of
+Scandinavia the swayings, sometimes up and sometimes down, which are
+now going on have considerably changed the position of the shore lines
+since the beginning of the historical period.
+
+There are other causes which serve to modify the shapes and sizes of
+the continents which may best be considered in the sequel; for the
+present we may pass from this subject with the statement that our
+great lands are relatively permanent features; their forms change from
+age to age, but they have remained for millions of years habitable to
+the hosts of animals and plants which have adapted their life to the
+conditions which these fields afford them.
+
+
+
+
+                              CHAPTER V.
+
+                            THE ATMOSPHERE.
+
+
+The firm-set portion of the earth, composed of materials which became
+solid when the heat so far disappeared from the sphere that rocky
+matter could pass from its previous fluid condition to the solid or
+frozen state, is wrapped about by two great envelopes, the atmosphere
+and the waters. Of these we shall first consider the lighter and more
+universal air; in taking account of its peculiarities we shall have to
+make some mention of the water with which it is greatly involved;
+afterward we shall consider the structure and functions of that fluid.
+
+Atmospheric envelopes appear to be common features about the celestial
+spheres. In the sun there is, as we have noted, a very deep envelope
+of this sort which is in part composed of the elements which form our
+own air; but, owing to the high temperature of the sphere, these are
+commingled with many substances which in our earth--at least in its
+outer parts--have entered in the solid state. Some of the planets, so
+far as we can discern their conditions, seem also to have gaseous
+wraps; this is certainly the case with the planet Mars, and even the
+little we know of the other like spheres justifies the supposition
+that Jupiter and Saturn, at least, have a like constitution. We may
+regard an atmosphere, in a word, as representing a normal and
+long-continued state in the development of the heavenly orbs. In only
+one of these considerable bodies of the solar system, the moon, do we
+find tolerably clear evidence that there is no atmosphere.
+
+The atmosphere of the earth is composed mainly of very volatile
+elements, known as nitrogen and argon. This is commingled with oxygen,
+also a volatile element. Into this mass a number of other substances
+enter in varying but always relatively very small proportions. Of
+these the most considerable are watery vapour and carbon dioxide; the
+former of these rarely amounts to one per cent of the weight of the
+air, considering the atmosphere as a whole, and the latter is never
+more than a small fraction of one per cent in amount. As a whole, the
+air envelope of the earth should be regarded as a mass of nitrogen and
+argon, which only rarely, under the influence of conditions which
+exist in the soil, enters into combinations with other elements by
+which it assumes a solid form. The oxygen, though a permanent element
+in the atmosphere, tends constantly to enter into combinations which
+fix it temporarily or permanently in the earth, in which it forms,
+indeed, in its combined state about one half the weight of all the
+mineral substances we know. The carbon dioxide, or carbonic-acid gas,
+as it is commonly termed, is a most important substance, as it affords
+plants all that part of their bodies which disappear on burning. It is
+constantly returned to the atmosphere by the decay of organic matter,
+as well as by volcanic action.
+
+In addition to the above-noted materials composing the air, all of
+which are imperatively necessary to the wonderful work accomplished by
+that envelope, we find a host of other substances which are
+accidentally, variably, and always in small quantities contained in
+this realm. Thus near the seashores, and indeed for a considerable
+distance into the continent, we find the air contains a certain amount
+of salt so finely divided that it floats in the atmosphere. So, too,
+we find the air, even on the mountain tops amid eternal snows, charged
+with small particles of dust, which, though not evident to the
+unassisted eye, become at once visible when we permit a slender ray of
+light to enter a dark chamber.
+
+It is commonly asserted that the atmosphere does not effectively
+extend above the height of forty-five miles; we know that it is
+densest on the surface of the earth, the most so in those depressions
+which lie below the level of the sea. This is proved to us by the
+weight which the air imposes upon the mercury at the open end of a
+barometric tube. If we could deepen these cavities to the extent of a
+thousand miles, the pressure would become so great that if the pit
+were kept free from the heat of the earth the gaseous materials would
+become liquefied. Upward from the earth's surface at the sea level the
+atoms and molecules of the air become farther apart until, at the
+height of somewhere between forty and fifty miles, the quantity of
+them contained in the ether is so small that we can trace little
+effect from them on the rays of light which at lower levels are
+somewhat bent by their action. At yet higher levels, however, meteors
+appear to inflame by friction against the particles of air, and even
+at the height of eighty miles very faint clouds have at times been
+discerned, which are possibly composed of volcanic dust floating in
+the very rarefied medium, such as must exist at this great elevation.
+
+The air not only exists in the region where we distinctly recognise
+it; it also occupies the waters and the under earth. In the waters it
+occurs as a mechanical mixture which is brought about as the rain
+forms and falls in the air, as the streams flow to the sea, and as the
+waves roll over the deep and beat against the shores. In the realm of
+the waters, as well as on the land, the air is necessary for the
+maintenance of all animal forms; but for its presence such life would
+vanish from the earth.
+
+Owing to certain peculiarities in its constitution, the atmosphere of
+our earth, and that doubtless of myriad other spheres, serves as a
+medium of communication between different regions. It is, as we know,
+in ceaseless motion at rates which may vary from the speed in the
+greatest tempests, which may move at the rate of somewhere a hundred
+and fifty miles an hour, to the very slow movements which occur in
+caverns, where the transfer is sometimes effected at an almost
+microscopic rate in the space of a day. The motion of the atmosphere
+is brought about by the action of heat here and there, and in a
+trifling way, by the heat from the interior of the earth escaping
+through hot springs or volcanoes, but almost altogether by the heat of
+the sun. If we can imagine the earth cut off from the solar radiation,
+the air would cease to move. We often note how the variable winds fall
+away in the nighttime. Those who in seeking for the North Pole have
+spent winters in the long-continued dark of that region have noted
+that the winds almost cease to blow, the air being disturbed only when
+a storm originated in the sunlit realm forced its way into the
+circumpolar darkness.
+
+The sun's heat does not directly disturb the atmosphere; if we could
+take the solid sphere of the world away, leaving the air, the rays
+would go straight through, and there would be no winds produced. This
+is due to the fact that the air permits the direct rays of heat, such
+as come from the sun, to pass through it with very slight resistance.
+In an aërial globe such as we have imagined, the rays impinging upon
+its surface would be slightly thrown out of their path as they are in
+passing through a lens, but they would journey on in space without in
+any considerable measure warming the mass. Coming, however, upon the
+solid earth, the heat rays warm the materials on which they are
+arrested, bringing them to a higher temperature than the air. Then
+these heated materials radiate the energy into the air; it happens,
+however, that this radiant heat can not journey back into space as
+easily as it came in; therefore the particles of air next the surface
+acquire a relatively high temperature. Thus a thermometer next the
+ground may rise to over a hundred degrees Fahrenheit, while at the
+same time the fleecy clouds which we may observe floating at the
+height of five or six miles above the surface are composed of frozen
+water.
+
+The effect of the heated air which acquires its temperature by
+radiation from the earth's surface is to produce the winds. This it
+brings about in a very simple manner, though the details of the
+process have a certain complication. The best illustration of the mode
+in which the winds are produced is obtained by watching what takes
+place about an ordinary fire at the bottom of a chimney. As soon as
+the fire is lit, we observe that the air about it, so far as it is
+heated, tends upward, drawing the smoke with it. If the air in the
+chimney be cold, it may not draw well at first; but in a few minutes
+the draught is established, or, in other words, the heated lower air
+breaks its way up the shaft, gradually pushing the cooler matter out
+at the top. In still air we may observe the column from the flue
+extending about the chimney-top, sometimes to the height of a hundred
+feet or more before it is broken to pieces. It is well here to note
+the fact that the energy of the draught in a chimney is, with a given
+heat of fire and amount of air which is permitted to enter the shaft,
+directly proportionate to the height; thus in very tall flues, between
+two and three hundred feet high, which are sometimes constructed, the
+uprush is at the speed of a gale.
+
+Whenever the air next the surface is so far heated that it may
+overcome the inertia of the cooler air above, it forces its way up
+through it in the general manner indicated in the chimney flue. When
+such a place of uprush is established, the hot air next the surface
+flows in all directions toward the shaft, joining the expedition to
+the heights of the atmosphere. Owing to the conditions of the earth's
+surface, which we shall now proceed to trace, these ascents of heated
+air belong in two distinct classes--those which move upward through
+more or less cylindrical chimneys in the atmosphere, shafts which are
+impermanent, which vary in diameter from a few feet to fifty or
+perhaps a hundred miles, and which move over the surface of the earth;
+and another which consists of a broad, beltlike shaft in the
+equatorial regions, which in a way girdles the earth, remains in
+about the same place, continually endures, and has a width of hundreds
+of miles. Of these two classes of uprushes we shall first consider the
+greatest, which occurs in the central portions of the tropical realm.
+
+Under the equator, owing to the fact that the sun for a considerable
+belt of land and sea maintains the earth at a high temperature, there
+is a general updraught which began many million years ago, probably
+before the origin of life, in the age when our atmosphere assumed its
+present conditions. Into this region the cooler air from the north and
+south necessarily flows, in part pressed in by the weight of the cold
+air which overlies it, but aided in its motion by the fact that the
+particles which ascend leave place for others to occupy. Over the
+surfaces of the land within the tropical region this draught toward
+what we may term the equatorial chimney is perturbed by the
+irregularities of the surface and many local accidents. But on the
+sea, where the conditions are uniform, the air moving toward the point
+of ascent is marked in the trade winds, which blow with a steadfast
+sweep down toward the equator. Many slight actions, such as the
+movement of the hot and cold currents of the sea, the local air
+movements from the lands or from detached islands, somewhat perturb
+the trade winds, but they remain among the most permanent features in
+this changeable world. It is doubtful if anything on this sphere
+except the atoms and molecules of matter have varied as little as the
+trade winds in the centre of the wide ocean. So steadfast and uniform
+are they that it is said that the helm and sails of a ship may be set
+near the west coast of South America and be left unchanged for a
+voyage which will carry the navigator in their belt across the width
+of the Pacific.
+
+Rising up from the earth in the tropical belt, the air attains the
+height of several thousand feet; it then begins to curve off toward
+the north and south, and at the height of somewhere about three to
+five miles above the surface is again moving horizontally toward
+either pole; attaining a distance on that journey, it gradually
+settles down to the surface of the earth, and ceases to move toward
+higher latitudes. If the earth did not revolve upon its axis the
+course of these winds along the surface toward the equator, and in the
+upper air back toward the poles, would be made in what we may call a
+square manner--that is, the particles of air would move toward the
+point where they begin to rise upward in due north and south lines,
+according as they came from the southern or northern hemisphere, and
+the upper currents or counter trades would retrace their paths also
+parallel with the meridians or longitude lines. But because the earth
+revolves from west to east, the course of the trade winds is oblique
+to the equator, those in the northern hemisphere blowing from
+northeast to southwest, those in the southern from southeast to
+northwest. The way in which the motion of the earth affects the
+direction of these currents is not difficult to understand. It is as
+follows:
+
+Let us conceive a particle of air situated immediately over the
+earth's polar axis. Such an atom would by the rotation of the sphere
+accomplish no motion except, indeed, that it might turn round on its
+own centre. It would acquire no velocity whatever by virtue of the
+earth's movement. Then let us imagine the particle moving toward the
+equator with the speed of an ordinary wind. At every step of its
+journey toward lower latitudes it would come into regions having a
+greater movement than those which it had just left. Owing to its
+inertia, it would thus tend continually to lag behind the particles of
+matter about it. It would thus fall off to the westward, and, in place
+of moving due south, would in the northern hemisphere drift to the
+southwest, and in the southern hemisphere toward the northwest. A good
+illustration of this action may be obtained from an ordinary
+turn-table such as is used about railway stations to reverse the
+position of a locomotive. If the observer will stand in the centre of
+such a table while it is being turned round he will perceive that his
+body is not swayed to the right or left. If he will then try to walk
+toward the periphery of the rotating disk, he will readily note that
+it is very difficult, if not impossible, to walk along the radius of
+the circle; he naturally falls behind in the movement, so that his
+path is a curved line exactly such as is followed by the winds which
+move toward the equator in the trades. If now he rests a moment on the
+periphery of the table, so that his body acquires the velocity of the
+disk at that point, and then endeavours to walk toward the centre, he
+will find that again he can not go directly; his path deviates in the
+opposite direction--in other words, the body continually going to a
+place having a less rate of movement by virtue of the rotation of the
+earth, on account of its momentum is ever moving faster than the
+surface over which it passes. This experiment can readily be tried on
+any small rotating disk, such as a potter's wheel, or by rolling a
+marble or a shot from the centre to the circumference and from the
+circumference to the centre. A little reflection will show the
+inquirer how these illustrations clearly account for the oblique
+though opposite sets of the trade winds in the upper and lower parts
+of the air.
+
+The dominating effect of the tropical heat in controlling the
+movements of the air currents extends, on the ocean surface, in
+general about as far north and south as the parallels of forty
+degrees, considerably exceeding the limits of the tropics, those lines
+where the sun, because of the inclination of the earth's axis, at some
+time of the year comes just overhead. Between these belts of trade
+winds there is a strip or belt under the region where the atmosphere
+is rising from the earth, in which the winds are irregular and have
+little energy. This region of the "doldrums" or frequent calms is one
+of much trouble to sailing ships on their voyages from one hemisphere
+to another. In passing through it their sails are filled only by the
+airs of local storms, or winds which make their way into that part of
+the sea from the neighbouring continents. Beyond the trade-wind belt,
+toward the poles, the movements of the atmosphere are dependent in
+part on the counter trades which descend to the surface of the earth
+in latitudes higher than that in which the surface or trade winds
+flow. Thus along our Atlantic coast, and even in the body of the
+continent, at times when the air is not controlled by some local
+storm, the counter trade blows with considerable regularity.
+
+The effect of the trade and counter-trade movements of the air on the
+distribution of temperature over the earth's surface is momentous. In
+part their influence is due to the direct heat-carrying power of the
+atmosphere; in larger measure it is brought about by the movement of
+the ocean waters which they induce. Atmospheric air, when deprived of
+the water which it ordinarily contains, has very little
+heat-containing capacity. Practically nearly all the power of
+conveying heat which it possesses is due to the vapour of water which
+it contains. By virtue of this moisture the winds do a good deal to
+transfer heat from the tropical or superheated portion of the earth's
+surface to the circumpolar or underheated realms. At first, the
+relatively cool air which journeys toward the equator along the
+surface of the sea constantly gains in heat, and in that process takes
+up more and more water, for precisely the same reason that causes
+anything to dry more rapidly in air which has been warmed next a fire.
+The result is that before it begins to ascend in the tropical
+updraught, being much moisture-laden, the atmosphere stores a good
+deal of heat. As it rises, rarefies, and cools, the moisture descends
+in the torrential rains which ordinarily fall when the sun is nearly
+vertical in the tropical belt.
+
+Here comes in a very interesting principle which is of importance in
+understanding the nature of great storms, either the continuous storm
+of the tropics or the local and irregular whirlings which occur in
+various parts of the earth. When the moisture-laden air starts on its
+upward journey from the earth it has, by virtue of the watery vapour
+which it contains, a store of energy which becomes applied to
+promoting the updraught. As it rises, the moisture in the air gathers
+together or condenses, and in so doing parts with the heat which
+caused it to evaporate from the ocean surface. For a given weight of
+water, the amount of heat required to effect the evaporation is very
+great; this we may roughly judge by observing what a continuous fire
+is required to send a pint of water into the state of steam. This
+energy, when it is released by the condensation of water into rain or
+snow, becomes again heat, and tends somewhat, as does the fire in the
+chimney, to accelerate the upward passage of the air. The result is
+that the water which ascends in the equatorial updraught becomes what
+we may term fuel to promote this important element in the earth's
+aërial circulation. Trades and counter trades would doubtless exist
+but for the efficiency of this updraught, which is caused by the
+condensation of watery vapour, but the movement would be much less
+than it is.
+
+
+                        WHIRLING STORMS.
+
+In the region near the equator, or near the line of highest
+temperature, which for various reasons does not exactly follow the
+equator, there is, as we have noticed, a somewhat continuous uprushing
+current where the air passes upward through an ascending chimney,
+which in a way girdles the sea-covered part of the earth. In this
+region the movements of the air are to a great extent under the
+control of the great continuous updraught. As we go to the north and
+south we enter realms where the air at the surface of the earth is, by
+the heat which it acquires from contact with that surface, more or
+less impelled upward; but there being no permanent updraught for its
+escape, it from time to time breaks through the roof of cold air which
+overlies it and makes a temporary channel of passage. Going polarward
+from the equator, we first encounter these local and temporary
+upcastings of the air near the margin of the tropical belt. In these
+districts, at least over the warmer seas, during the time of the year
+when it is midsummer, and in the regions where the trade winds are not
+strong enough to sweep the warm and moisture-laden air down to the
+equatorial belt, the upward tending strain of the atmosphere next the
+earth often becomes so strong that the overlying air is displaced,
+forming a channel through which the air swiftly passes. As the
+moisture condenses in the way before noted, the energy set free serves
+to accelerate the updraught, and a hurricane is begun. At first the
+movement is small and of no great speed, but as the amount of air
+tending upward is likely to be great, as is also the amount of
+moisture which it contains, the aërial chimney is rapidly enlarged,
+and the speed of the rising air increased. The atmosphere next the
+surface of the sea flows in toward the channel of escape; its passage
+is marked by winds which are blowing toward the centre. On the
+periphery of the movement the particles move slowly, but as they win
+their way toward the centre they travel with accelerating velocity. On
+the principle which determines the whirling movement of the water
+escaping through a hole in the bottom of a basin, the particles of the
+air do not move on straight lines toward the centre, but journey in
+spiral paths, at first along the surface, and then ascending.
+
+We have noted the fact that in a basin of water the direction of the
+whirling is what we may term accidental--that is, dependent on
+conditions so slight that they elude our observation--but in
+hurricanes a certain fact determines in an arbitrary way the direction
+in which the spin shall take place. As soon as such a movement of the
+air attains any considerable diameter, although in its beginning it
+may have spun in a direction brought about by local accidents, it will
+be affected by the diverse rates of travel, by virtue of the earth's
+rotation, of the air on its equatorial and polar sides. On the
+equatorial side this air is moving more rapidly than it is on the
+polar side. By observing the water passing from a basin this
+principle, with a few experiments, can be made plain. The result is to
+cause these great whirlwinds of the hurricanes of higher latitudes to
+whirl round from right to left in the northern hemisphere and in the
+reverse way in the southern. The general system of the air currents
+still further affects these, as other whirling storms, by driving
+their centres or chimneys over the surface of the earth. The principle
+on which this is done may be readily understood by observing how the
+air shaft above a chimney, through which we may observe the smoke to
+rise during a time of calm, is drawn off to one side by the slight
+current which exists even when we feel no wind; it may also be
+discerned in the little dust whirls which form in the streets on a
+summer day when the air is not much disturbed. While they spin they
+move on in the direction of the air drift. In this way a hurricane
+originating in the Gulf of Mexico may gradually journey under the
+influence of the counter trades across the Antilles, or over southern
+Florida, and thence pursue a devious northerly course, generally near
+the Atlantic coast and in the path of the Gulf Stream, until it has
+travelled a thousand miles or more toward the North Atlantic. The
+farther it goes northward the less effectively it is fed with warm and
+moisture-laden air, the feebler its movement becomes, until at length
+it is broken up by the variable winds which it encounters.
+
+A very interesting and, from the point of view of the navigator,
+important peculiarity of these whirls is that at their centre there is
+a calm, similar in origin and nature to the calm under the equator
+between the trade-wind belts. Both these areas are in the field where
+the air is ascending, and therefore at the surface of the earth does
+not affect the sails of ships, though if men ever come to use flying
+machines and sail through the tropics at a good height above the sea
+it will be sensible enough. The difference between the doldrum of the
+equator and that of the hurricane, besides their relative areas, is
+that one is a belt and the other a disk. If the seafarer happens to
+sail on a path which leads him through the hurricane centre, he will
+first discern, as from the untroubled air and sea he approaches the
+periphery of the storm, the horizon toward the disturbance beset by
+troubled clouds, all moving in one direction. Entering beneath this
+pall, he finds a steadily increasing wind, which in twenty miles of
+sailing may, and in a hundred miles surely will, compel him to take in
+all but his storm sails, and is likely to bring his ship into grave
+peril. The most furious winds the mariner knows are those which he
+encounters as he approaches the still centre. These trials are made
+the more appalling by the fact that in the furious part of the whirl
+the rain, condensing from the ascending air, falls in torrents, and
+the electricity generated in the condensation gives rise to vivid
+lightning. If the storm-beset ship can maintain her way, in a score or
+two of miles of journey toward the centre, generally very quickly, it
+passes into the calm disk, where the winds, blowing upward, cease to
+be felt. In this area the ship is not out of danger, for the waves,
+rolling in from the disturbed areas on either side, make a torment of
+cross seas, where it is hard to control the movements of a sailing
+vessel because the impulse of the winds is lost. Passing through this
+disk of calm, the ship re-encounters in reverse order the furious
+portion of the whirl, afterward the lessening winds, until it escapes
+again into the airs which are not involved in the great torment.
+
+In the old days, before Dove's studies of storms had shown the laws of
+hurricane movement, unhappy shipmasters were likely to be caught and
+retained in hurricanes, and to battle with them for weeks until their
+vessels were beaten to pieces. Now the "Sailing Directions," which are
+the mariner's guide, enable him, from the direction of the winds and
+the known laws of motion of the storm centre, to sail out of the
+danger, so that in most cases he may escape calamity. It is otherwise
+with the people who dwell upon the land over which these atmospheric
+convulsions sweep. Fortunately, where these great whirlwinds trespass
+on the continent, they quickly die out, because of the relative lack
+of moisture which serves to stimulate the uprush which creates them.
+Thus in their more violent forms hurricanes are only felt near the
+sea, and generally on islands and peninsulas. There the hurricane
+winds, by the swiftness of their movement, which often attains a speed
+of a hundred miles or more, apply a great deal of energy to all
+obstacles in their path. The pressure thus produced is only less
+destructive than that which is brought about by the tornadoes, which
+are next to be described.
+
+There is another effect from hurricanes which is even more destructive
+to life than that caused by the direct action of the wind. In these
+whirlings great differences in atmospheric pressure are brought about
+in contiguous areas of sea. The result is a sudden elevation in the
+level of one part of the water. These disturbances, where the shore
+lands are low and thickly peopled, as is the case along the western
+coast of the Bay of Bengal, may produce inundations which are terribly
+destructive to life and property. They are known also in southern
+Florida and along the islands of the Caribbean, but in that region are
+not so often damaging to mankind.
+
+Fortunately, hurricanes are limited to a very small part of the
+tropical district. They occur only in those regions, on the eastern
+faces of tropical lands, where the general westerly set of the winds
+favours the accumulation of great bodies of very warm, moist air next
+the surface of the sea. The western portion of the Gulf of Mexico and
+the Caribbean, the Bay of Bengal, and the southeastern portion of Asia
+are especially liable to their visitations. They sometimes develop,
+though with less fury, in other parts of the tropics. On the western
+coast of South America and Africa, where the oceans are visited by the
+dry land winds, and where the waters are cooled by currents setting
+in from high latitudes, they are unknown.
+
+Only less in order of magnitude than the hurricanes are the circular
+storms known as cyclones. These occur on the continents, especially
+where they afford broad plains little interrupted by mountain ranges.
+They are particularly well exhibited in that part of North America
+north of Mexico and south of Hudson Bay. Like the hurricanes, they
+appear to be due to the inrush of relatively warm air entering an
+updraught which had been formed in the overlying, cooler portions of
+the atmosphere. They are, however, much less energetic, and often of
+greater size than the hurricane whirl. The lack of energy is probably
+due to the comparative dryness of the air. The greater width of the
+ascending column may perhaps be accounted for by the fact that,
+originating at a considerable height above the sea, they have a less
+thickness of air to break through, and so the upward setting column is
+readily made broad.
+
+The cyclones of North America appear generally to originate in the
+region of the Rocky Mountains, though it is probable that in some
+instances, perhaps in many, the upward set of the air which begins the
+storm originates in the ocean along the Pacific coast. They gather
+energy as they descend the great sloping plain leading eastward from
+the Rocky Mountains to the central portion of the great continental
+valley. Thence they move on across the country to the Atlantic coast.
+Not infrequently they continue on over the ocean to the European
+continent. The eastward passage of the storm centre is due to the
+prevailing eastward movement of the air in its upper part throughout
+that portion of the northern hemisphere. Commonly they incline
+somewhat to the northward of east in their journey. In all cases the
+winds appear to blow spirally into the common storm centre. There is
+the same doldrum area or calm field in the centre of the storm that we
+note between the trade winds and in the middle of a hurricane disk,
+though this area is less defined than in the other instances, and the
+forward motion of the storm at a considerable speed is in most cases
+characteristic of the disturbance. On the front of one of these storms
+in North America the winds commonly begin in the northeast, thence
+they veer by the east to the southwest. At this stage in the movement
+the storm centre has passed by, the rainfall commonly ceases, and
+cold, dry winds setting to the northwestward set in. This is caused by
+the fact that the ascending air, having attained a height above the
+earth, settles down behind the storm, forming an anticyclone or mass
+of dry air, which presses against the retreating side of the great
+whirlwind.
+
+In front of the storm the warm and generally moist relatively warm
+air, pressing in toward the point of uprise and overlaid by the upper
+cold air, is brought into a condition where it tends to form small
+subordinate shafts up through which it whirls on the same principle,
+but with far greater intensity than the main ascending column. The
+reason for the violence of this movement is that the difference in
+temperature of the air next the surface and that at the height of a
+few thousand feet is great. As might be expected, these local
+spinnings are most apt to occur in the season when the air next the
+earth is relatively warm, and they are aptest to take place in the
+half of the advancing front lying between the east and south, for the
+reason that there the highest temperatures and the greatest humidity
+are likely to coexist. In that part of the field, during the time when
+the storm is advancing from the Rocky Mountains to the Atlantic, a
+dozen or more of these spinning uprushes may be produced, though few
+of them are likely to be of large size or of great intensity.
+
+The secondary storms of cyclones, such as are above noted, receive the
+name of tornadoes. They are frequent and terrible visitations of the
+country from northern Texas, Florida, and Alabama to about the line of
+the Great Lakes; they are rarely developed in the region west of
+central Kansas, and only occasionally do they exhibit much energy in
+the region east of the plain-lands of the Ohio Valley. Although known
+in other lands, they nowhere, so far as our observations go, exhibit
+the paroxysmal intensity which they show in the central portion of the
+North American continent. There the air which they affect acquires a
+speed of movement and a fury of action unknown in any other
+atmospheric disturbances, even in those of the hurricanes.
+
+The observer who has a chance to note from an advantageous position
+the development of a tornado observes that in a tolerably still air,
+or at least an air unaffected by violent winds--generally in what is
+termed a "sultry" state of the atmosphere--the storm clouds in the
+distance begin to form a kind of funnel-shaped dependence, which
+gradually extends until it appears to touch the earth. As the clouds
+are low, this downward-growing column probably in no case is observed
+for the height of more than three or four thousand feet. As the funnel
+descends, the clouds above and about it may be seen to take on a
+whirling movement around the centre, and under favourable
+circumstances an uprush of vapours may be noted in the centre of the
+swaying shaft. As the whirl comes nearer, the roar of the disturbance,
+which at a distance is often compared to the sound made by a threshing
+machine or to that of distant musketry, increases in loudness until it
+becomes overwhelming. When a storm such as this strikes a building, it
+is not only likely to be razed by the force of the wind, but it may be
+exploded, as by the action of gunpowder fired within its walls,
+through the sudden expansion of the air which it contains. In the
+centre of the column, although it rarely has a diameter of more than a
+few hundred feet, the uprush is so swift that it makes a partial
+vacuum. The air, striving to get into the space which it is eager to
+occupy, is whirling about at such a rate that the centrifugal motion
+which it thus acquires restrains its entrance. In this way there may
+be, as the column rapidly moves by, a difference of pressure
+amounting probably to what the mercury of a barometer would indicate
+by four or five inches of fall. Unless the structure is small and its
+walls strong, its roof and sides are apt to be blown apart by this
+difference of pressure and the consequent expansion of the contained
+air. In some cases where wooden buildings have withstood this curious
+action the outer clapboards have been blown off by the expansion of
+the small amount of air contained in the interspaces between that
+covering and the lath and plaster within (see Fig. 9).
+
+[Illustration: Fig. 9.--Showing effect of expansion of air contained
+in a hollow wall during the passage of the storm.]
+
+The blow of the air due to its rotative whirling has in several cases
+proved sufficient to throw a heavy locomotive from the track of a
+well-constructed railway. In all cases where it is intense it will
+overturn the strongest trees. The ascending wind in the centre of the
+column may sometimes lift the bodies of men and of animals, as well as
+the branches and trunks of trees and the timber of houses, to the
+height of hundreds of feet above the surface. One of the most striking
+exhibitions of the upsucking action in a tornado is afforded by the
+effect which it produces when it crosses a small sheet of water. In
+certain cases where, in the Northwestern States of this country, the
+path of the storm lay over the pool, the whole of the water from a
+basin acres in extent has been entirely carried away, leaving the
+surface, as described by an observer, apparently dry enough to plough.
+
+Fortunately for the interests of man, as well as those of the lower
+organic life, the paths of these storms, or at least the portion of
+their track where the violence of the air movement makes them very
+destructive, often does not exceed five hundred feet in width, and is
+rarely as great as half a mile in diameter. In most cases the length
+of the journey of an individual tornado does not exceed thirty miles.
+It rarely if ever amounts to twice that distance.
+
+In every regard except their small size and their violence these
+tornadoes closely resemble hurricanes. There is the same broad disk of
+air next the surface spirally revolving toward the ascending centre,
+where its motion is rapidly changed from a horizontal to a vertical
+direction. The energy of the uprush in both cases is increased by the
+energy set free through the condensation of the water, which tends
+further to heat and thus to expand the air. The smaller size of the
+tornado may be accounted for by the fact that we have in their
+originating conditions a relatively thin layer of warm, moist air next
+the earth and a relatively very cold layer immediately overlying it.
+Thus the tension which serves to start the movement is intense, though
+the masses involved are not very great. The short life of a tornado
+may be explained by the fact that, though it apparently tends to grow
+in width and energy, the central spout is small, and is apt to be
+broken by the movements of the atmosphere, which in the front of a
+cyclone are in all cases irregular.
+
+On the warmer seas, but often beyond the limits of the tropics,
+another class of spinning storms, known as waterspouts, may often be
+observed. In general appearance these air whirls resemble tornadoes,
+except that they are in all cases smaller than that group of
+whirlings. As in the tornadoes, the waterspout begins with a funnel,
+which descends from the sky to the surface of the sea. Up the tube
+vapours may be seen ascending at great speed, the whole appearing like
+a gigantic pillar of swiftly revolving smoke. When the whirl reaches
+the water, it is said that the fluid leaps up into the tube in the
+form of dense spray, an assertion which, in view of the fact of the
+action of a tornado on a lake as before described, may well be
+believed. Like the tornadoes and dust whirls, the life of a waterspout
+appears to be brief. They rarely endure for more than a few minutes,
+or journey over the sea for more than two or three miles before the
+column appears to be broken by some swaying of the atmosphere. As
+these peculiar storms are likely to damage ships, the old-fashioned
+sailors were accustomed to fire at them with cannon. It has been
+claimed that a shot would break the tube and end the little
+convulsion. This, in view of the fact that they appear to be easily
+broken up by relatively trifling air currents, may readily be
+believed. The danger which these disturbances bring to ships is
+probably not very serious.
+
+The special atmospheric conditions which bring about the formation of
+waterspouts are not well known; they doubtless include, however, warm,
+moist air next the surface of the sea and cold air above. Just why
+these storms never attain greater size or endurance is not yet known.
+These disturbances have been seen for centuries, but as yet they have
+not been, in the scientific sense, observed. Their picturesqueness
+attracts all beholders; it is interesting to note the fact that
+perhaps the earliest description of their phenomena--one which takes
+account in the scientific spirit of all the features which they
+present--was written by the poet Camoëns in the Lusiad, in which he
+strangely mingles fancy and observation in his account of the great
+voyage of Vasco da Gama. The poet even notes that the water which
+falls when the spout is broken is not salt, but fresh--a point which
+clearly proves that not much of the water which the tube contains is
+derived from the sea. It is, in fact, watery vapour drawn from the air
+next the surface of the ocean, and condensed in its ascent through the
+tube. In this and other descriptions of Nature Camoëns shows more of
+the scientific spirit than any other poet of his time. He was in this
+regard the first of modern writers to combine a spiritual admiration
+for Nature with some sense of its scientific meaning.
+
+In treating of the atmosphere, meteorologists base their studies
+largely on changes in the weight of that medium, which they determine
+by barometric observations. In fact, the science of the air had its
+beginning in Pascal's admirable observation on the changes in the
+height of a column of mercury contained in a bent tube as he ascended
+the volcanic peak known as Puy de Dome, in central France. As before
+noted, it is to the disturbances in the weight of the air, brought
+about mainly by variations in temperature, that we owe all its
+currents, and it is upon these winds that the features we term climate
+in largest measure depend. Every movement of the winds is not only
+brought about by changes in the relative weight of the air at certain
+points, but the winds themselves, owing to the momentum which the air
+attains by them, serve to bring about alterations in the quantity of
+air over different parts of the earth, which are marked most
+distinctly by barometric variations. These changes are exceedingly
+complicated; a full account of them would demand the space of this
+volume. A few of the facts, however, should be presented here. In the
+first place, we note that each day there is normally a range in the
+pressure which causes the barometer to be at the lowest at about four
+o'clock in the morning and four o'clock in the afternoon, and highest
+at about ten o'clock in those divisions of the day. This change is
+supposed to be due to the fact that the motes of dust in the
+atmosphere in the night, becoming cooled, condense the water vapour
+upon their surfaces, thus diminishing the volume of the air. When the
+sun rises the water evaporated by the heat returns from these little
+storehouses into the body of the atmosphere. Again in the evening the
+condensation sets in; at the same time the air tends to drift in from
+the region to the westward, where the sun is still high, toward the
+field where the barometer has been thus lowered; the current gradually
+attains a certain volume, and so brings about the rise of the
+barometer about ten o'clock at night.
+
+In the winter time, particularly on the well-detached continent of
+North America, we find a prevailing high barometer in the interior of
+the country and a corresponding low state of pressure on the Atlantic
+Ocean. In the summer season these conditions are on the whole
+reversed.
+
+Under the tropics, in the doldrum belt, there is a zone of low
+barometer connected to the ascending currents which take place along
+that line. This is a continuous manifestation of the same action which
+gives a large area of a disklike form in the centre or eye of the
+hurricane and in the middle portion of the tornado's whirl. In
+general, it may be said that the weight of the air is greatest in the
+regions from which it is blowing toward the points of upward escape,
+and least in and about those places where the superincumbent air is
+rising through a temporary or permanent line of escape. In other
+words, ascending air means generally a relatively low barometer, while
+descending air is accompanied by greater pressure in the field upon
+which it falls.
+
+In almost every part of the earth which is affected by a particular
+physiography we find that the movements of the atmosphere next the
+surface are qualified by the condition which it encounters. In fact,
+if a person were possessed of all the knowledge which could be
+obtained concerning winds, he could probably determine as by a map the
+place where he might chance to find himself, provided he could extend
+his observations over a term of years. In other words, the regimen of
+the winds--at least those of a superficial nature--is almost as
+characteristic of the field over which they go as is a map of the
+country. Of these special winds a number of the more important have
+been noted, only a few of which we can advert to. First among these
+may well come the land and sea breezes which are remarked about all
+islands which are not continuously swept by permanent winds. One of
+the most characteristic instances of these alternate winds is perhaps
+that afforded on the island of Jamaica.
+
+The island of Jamaica is so situated within the basin of the Caribbean
+that it does not feel the full influence of the trades. It has a range
+of high mountains through its middle part. In the daytime the surface
+of the land, which has the sun overhead twice each year, and is always
+exposed to nearly vertical radiation, becomes intensely hot, so that
+an upcurrent is formed. The formation of this current is favoured by
+the mountains, which apply a part of the heat at the height of about a
+mile above the surface of the sea. This action is parallel to that we
+notice when, in order to create a draught in the air of a chimney, we
+put a torch some distance up above the fireplace, thus diminishing the
+height of the column of air which has to be set in motion. It is
+further shown by the fact that when miners sought to make an upcurrent
+in a shaft, in order to lead pure air into the workings through other
+openings, they found after much experience that it was better to have
+the fire near the top of the shaft rather than at the bottom.
+
+The ascending current being induced up the mountain sides of Jamaica,
+the air is forced in from the sea to the relatively free space. Before
+noon the current, aided in its speed by a certain amount of the
+condensation of the watery vapour before described, attains the
+proportions of a strong wind. As the sun begins to sink, the earth's
+surface pours forth its heat; the radiation being assisted by the
+extended surfaces of the plants, cooling rapidly takes place.
+Meanwhile the sea, because of the great heat-storing power of water,
+is very little cooled, the ascent of the air ceases, the temporary
+chimney with its updraught is replaced by a downward current, and the
+winds blow from the land until the sun comes again to reverse the
+current. In many cases these movements of the daily winds flowing into
+and from islands induce a certain precipitation of moisture in the
+form of rain. Generally, however, their effect is merely to ameliorate
+the heat by bringing alternately currents from the relatively cool sea
+and from the upper atmosphere to lessen the otherwise excessive
+temperature of the fields which they traverse.
+
+Although characteristic sea and land winds are limited to regions
+where the sun's heat is great, they are traceable even in high
+latitudes during the periods of long-continued calm attended with
+clear skies. Thus on the island of Martha's Vineyard, in
+Massachusetts, the writer has noted, when the atmosphere was in such a
+state, distinct night and day, or sea and land, breezes coming in
+their regular alternation. During the night when these alternate winds
+prevail the central portion of the island, at the distance of three
+miles from the sea, is remarkably cold, the low temperature being due
+to the descending air current. To the same physical cause may be
+attributed the frequent insets of the sea winds toward midday along
+the continental shores of various countries. Thus along the coast of
+New England in the summer season a clear, still, hot day is certain to
+lead to the creation of an ingoing tide of air, which reaches some
+miles into the interior. This stream from the sea enters as a thin
+wedge, it often being possible to note next the shore when the
+movement begins a difference of ten degrees of temperature between the
+surface of the ground to which the point of the wedge has attained,
+and a position twenty feet higher in the air. This is a beautiful
+example to show at once how the relative weight of the atmosphere,
+even when the differences are slight, may bring about motion, and also
+how masses of the atmosphere may move by or through the rest of the
+medium in a way which we do not readily conceive from our observations
+on the transparent mass. Very few people have any idea how general is
+the truth that the air, even in continuous winds, tends to move in
+more or less individualized masses. This, however, is made very
+evident by watching the gusts of a storm or the wandering patches of
+wind which disturb the surface of an otherwise smooth sea.
+
+[Illustration: _South shore, Martha's Vineyard, Massachusetts, showing
+a characteristic sand beach with long slope and low dunes. Note the
+three lines of breakers and the splash flows cutting little bays in
+the sand._]
+
+Among the notable local winds are those which from their likeness to
+the Föhn of the Swiss valleys receive that name. Föhns are produced
+where a body of air blowing against the slope of a continuous mountain
+range is lifted to a considerable height, and, on passing over the
+crest, falls again to a low position. In its ascent the air is cooled,
+rarefied, and to a great extent deprived of its moisture. In
+descending it is recondensed, and by the process by which its atoms
+are brought together its latent heat is made sensible. There being but
+little watery vapour in the mass, this heat is not much called for by
+that heat-storing fluid, and so the air is warmed. So far Föhn winds
+have only been remarked as conspicuous features in Switzerland and on
+the eastern face of the Rocky Mountains. In the region about the head
+waters of the Missouri and to the northward their influence in what
+are called the Chinook winds is distinctly to ameliorate the severe
+winter climate of the country.
+
+In almost all great desert regions, particularly in the typical
+Sahara, we find a variety of storm belonging to the whirlwind group,
+which, owing to the nature of the country, take on special
+characteristics. These desert storms take up from the verdureless
+earth great quantities of sand and other fine _débris_, which often so
+clouds the air as to bring the darkness of night at midday. Their
+whirlings appear in size to be greater than those which produce
+tornadoes or waterspouts, but less than hurricanes or cyclones.
+Little, however, is known about them. They have not been well
+observed by meteorologists. In some ways they are important, for the
+reason that they serve to carry the desert sand into regions
+previously verdure-clad, and thus to extend the bounds of the desolate
+fields in which they originate. Where they blow off to the seaward,
+they convey large quantities of dust into the ocean, and thus serve to
+wear down the surface of the land in regions where there are no rivers
+to effect that action in the normal way.
+
+Notwithstanding its swift motion when impelled by differences in
+weight, the movements of the air have had but little direct and
+immediate influence on the surface of the earth. The greater part of
+the work which it does, as we shall see hereafter, is done through the
+waters which it impels and bears about. Yet where winds blow over
+verdureless surfaces the effect of the sand which they sweep before
+them is often considerable. In regions of arid mountains the winds
+often drive trains of sand through the valleys, where the sharp
+particles cut the rocks almost as effectively as torrents of water
+would, distributing the wearing over the width of the valley. The dust
+thus blown, from a desert region may, when it attains a country
+covered with vegetation, gradually accumulate on its surface, forming
+very thick deposits. Thus in northwestern China there is a wide area
+where dust accumulations blown from the arid districts of central Asia
+have gradually heaped up in the course of ages to the depth of
+thousands of feet, and this although much of the _débris_ is
+continually being borne away by the action of the rain waters as they
+journey toward the sea. Such dust accumulations occur in other parts
+of the world, particularly in the districts about the upper
+Mississippi and in the valleys of the Rocky Mountains, but nowhere are
+they so conspicuous as in the region first mentioned.
+
+Where prevailing winds from the sea, from great lakes, and even from
+considerable rivers, blow against sandy shores or cliffs of the same
+nature, large quantities of sand and dust are often driven inland
+from the coast line. In most cases these wind-borne materials take on
+the form of dunes, or heaps of sand, varying from a few feet to
+several hundred feet in height. It is characteristic of these hills of
+blown sand that they move across the face of the country. Under
+favourable conditions they may journey scores of miles from the shore.
+The marching of a dune is effected through the rolling up of the sand
+on the windward side of the elevation, when it is impelled by the
+current of air to the crest where it falls into the lee or shelter
+which the hill makes to the wind. In this way in the course of a day
+the centre of the dune, if the wind be blowing furiously, may advance
+a measurable distance from the place it occupied before. By fits and
+starts this ongoing may be indefinitely continued. A notable and
+picturesque instance of the march of a great dune may be had from the
+case in which one of them overwhelmed in the last century the village
+of Eccles in southeastern England. The advancing sand gradually crept
+into the hamlet, and in the course of a decade dispossessed the people
+by burying their houses. In time the summit of the church spire
+disappeared from view, and for many years thereafter all trace of the
+hamlet was lost. Of late years, however, the onward march of the sands
+has disclosed the church spire, and in the course of another century
+the place may be revealed on its original site, unchanged except that
+the marching hill will be on its other side.
+
+In the region about the head of the Bay of Biscay the quantity of
+these marching sands is so great that at one time they jeopardized the
+agriculture of a large district. The French Government has now
+succeeded, by carefully planting the surface of the country with
+grasses and other herbs which will grow in such places, in checking
+the movement of the wind-blown materials. By so doing they have merely
+hastened the process by which Nature arrests the march of dunes. As
+these heaps creep away from the sea, they generally come into regions
+where a greater variety of plants flourish; moreover, their sand
+grains become decayed, so that they afford a better soil. Gradually
+the mat of vegetation binds them down, and in time covers them over so
+that only the expert eye can recognise their true nature. Only in
+desert regions can the march of these heaps be maintained for great
+distances.
+
+Characteristic dunes occur from point to point all along the Atlantic
+coast from the State of Maine to the northern coast of Florida. They
+also occur along the coasts of our Great Lakes, being particularly
+well developed at the southern end of Lake Michigan, where they form,
+perhaps, the most notable accumulations within the limits of the
+United States.
+
+When blown sands invade a forest and the deposit is rapidly
+accumulated, the trees are often buried in an undecayed condition. In
+this state, with certain chemical reactions which may take place in
+the mass, the woody matter is apt to become replaced by silex
+dissolved from the sand, which penetrates the tissues of the plants.
+In this way salicified forests are produced, such as are found in the
+region of the Rocky Mountains, where the trunks of the trees, now very
+hard stone, so perfectly preserve their original structure that when
+cut and polished they may be used for decorative purposes. Conspicuous
+as is this work of the dunes, it is in a geological way much less
+important than that accomplished by the finer dust which drifts from
+one region of land to another or into the sea. Because of their
+weight, the sand grains journey over the surface of the earth, except,
+indeed, where they are uplifted by whirl storms. They thus can not
+travel very fast or far. Dust, however, rises into the air, and
+journeys for indefinite distances. We thus see how slight differences
+in the weight of substances may profoundly affect the conditions of
+their deportation.
+
+
+                      THE SYSTEM OF WATERS.
+
+The envelope of air wraps the earth completely about, and, though
+varying in thickness, is everywhere present over its surface. That of
+the waters is much less equally distributed. Because of its weight, it
+is mainly gathered in the depths of the earth, where it lies in the
+interstices of the rocks and in the great realm of the seas. Only a
+very small portion of the fluid is in the atmosphere or on the land.
+Perhaps less than a ten thousandth part of the whole is at any one
+time on this round from the seas through the air to the land and back
+to the great reservoir.
+
+The great water store of the earth is contained in two distinct
+realms--in the oceans, where the fluid is concentrated in a quantity
+which fills something like nine tenths of the hollows formed by the
+corrugations of the earth's surface; and in the rocks, where it is
+stored in a finely divided form, partly between the grains of the
+stony matter and partly in the substance of its crystals, where it
+exists in a combination, the precise nature of which is not well
+known, but is called water of crystallization. On the average, it
+seems likely that the materials of the earth, whether under the sea or
+on the land, have several per cent of their mass of the fluid.
+
+It is not yet known to what depth the water-bearing section of the
+earth extends; but, as we shall see more particularly hereafter when
+we come to consider volcanoes, the lavas which they send up to the
+surface are full of contained water, which passes from them in the
+form of steam. The very high temperature of these volcanic ejections
+makes it necessary for us to suppose that they come from a great
+depth. It is difficult to believe that they originate at less than a
+hundred miles below the earth's surface. If, then, the rocks contain
+an average of even five per cent of water to the depth of one hundred
+miles, the quantity of the fluid stored within the earth is greater
+than that which is contained in the reservoir of the ocean. The
+oceans, on the average, are not more than three miles deep; spread
+evenly over the surface of the whole earth, their depth would be less
+than two miles, while the water in the rocks, if it could be added to
+the seas, would make the total depth seven miles or more. As we shall
+note hereafter, the processes of formation of strata tend to imprison
+water in the beds, which in time is returned to the earth's surface by
+the forces which operate within the crust.
+
+Although the water in the seas is, as we have seen, probably less than
+one half of the store which the earth possesses, the part it plays in
+the economy of the planet is in the highest measure important. The
+underground water operates solely to promote certain changes which
+take place in the mineral realm. Its effect, except in volcanic
+processes, are brought about but slowly, and are limited in their
+action. The movements of this buried water are exceedingly gradual;
+the forces which impel it about and which bring it to do its work
+originate in the earth. In the seas the fluid has an exceeding freedom
+of motion; it can obey the varied impulses which the solar energy
+imposes upon it. The rôle of these wonderful actions which we are
+about to trace includes almost everything which goes on upon the
+surface of the planet--that which relates to the development of animal
+and vegetable life, as well as to the vast geological changes which
+the earth is undergoing.
+
+If the surface of the earth were uniformly covered with water to the
+depth of ten thousand feet or more, every particle of fluid would, in
+a measure, obey the attraction of the sun, of the moon, and,
+theoretically, also of all the other bodies in space, on the principle
+that every particle of matter in the universe exercises a gravitative
+effect on every other. As it is, owing to the divided condition of the
+water on the earth's surface, only that which is in the ocean and
+larger seas exhibits any measurable influence from these distant
+attractions. In fact, only the tides produced by the moon and sun are
+of determinable magnitude, and of these the lunar is of greater
+importance, the reason being the near position of our satellite to our
+own sphere. The solar tide is four tenths as great as the lunar. The
+water doubtless obeys in a slight way the attraction of the other
+celestial bodies, but the motions thus imparted are too small to be
+discerned; they are lost in the great variety of influences which
+affect all the matter on the earth.
+
+Although the tides are due to the attraction of the solar bodies,
+mainly to that of the moon, the mode in which the result is brought
+about is somewhat complicated. It may briefly and somewhat
+incompletely be stated as follows: Owing to the fact that the
+attracting power of the earth is about eighty times greater than that
+of the moon, the centre of gravity of the two bodies lies within the
+earth. About this centre the spheres revolve, each in a way swinging
+around the other. At this point there is no centrifugal motion arising
+from the revolution of the pair of spheres, but on the side of the
+earth opposite the moon, some six thousand miles away, the centrifugal
+force is considerable, becoming constantly greater as we pass away
+from the turning point. At the same time the attraction of the moon on
+the water becomes less. Thus the tide opposite the satellite is
+formed. On the side toward the moon the same centrifugal action
+operates, though less effectively than in the other case, for the
+reason that the turning point is nearer the surface; but this action
+is re-enforced by the greater attraction of the moon, due to the fact
+that the water is much nearer that body.
+
+In the existing conditions of the earth, what we may call the normal
+run of the tides is greatly interrupted. Only in the southern ocean
+can the waters obey the lunar and solar attraction in anything like a
+normal way. In that part of the earth two sets of tides are
+discernible, the one and greater due to the moon, the other, much
+smaller, to the sun. As these tides travel round at different rates,
+the movements which they produce are sometimes added to each other
+and sometimes subtracted--that is, at times they come together, while
+again the elevation of one falls in the hollow of the other. Once
+again supposing the earth to be all ocean covered, computation shows
+that the tides in such a sea would be very broad waves, having,
+indeed, a diameter of half the earth's circumference. Those produced
+by the moon would have an altitude of about one foot, and those by the
+sun of about three inches. The geological effects of these swayings
+would be very slight; the water would pass over the bottom to and fro
+twice each day, with a maximum journey of a hundred or two feet each
+way from a fixed point. This movement would be so slow that it could
+not stir the fine sediment; its only influence would perhaps be to
+help feed the animals which were fixed upon the bottom by drawing the
+nurture-bringing water by their mouths.
+
+Although the divided condition of the ocean perturbs the action of the
+tides, so that except by chance their waves are rarely with their
+centres where the attracting bodies tend to make them, the influence
+of these divisions is greatly to increase the geological or
+change-bringing influences arising from these movements. When from the
+southern ocean the tides start to the northward up the bays of the
+Atlantic, the Pacific, or the Indian Ocean, they have, as before
+noted, a height of perhaps less than two feet. As they pass up the
+narrowing spaces the waves become compressed--that is, an equal volume
+of moving water has less horizontal room for its passage, and is
+forced to rise higher. We see a tolerably good illustration of the
+same principle when we observe a wind-made wave enter a small recess
+of the shore, the sides of which converge in the direction of the
+motion. With the diminished room, the wave gains in height. It thus
+comes about that the tide throughout the Atlantic basin is much higher
+than in the southern ocean. On the same principle, when the tide rolls
+in against the shores every embayment of a distinct kind, whose sides
+converge toward the head, packs up the tidal wave, often increasing
+its height in a remarkable way. When these bays are wide-mouthed and
+of elongate triangular form, with deep bottoms, the tides which on
+their outer parts have a height of ten or fifteen feet may attain an
+altitude of forty or fifty feet at the apex of the triangle.
+
+We have already noted the fact that the tide, such as runs in the
+southern ocean, exercises little or no influence upon the bottom of
+the sea over which it moves. As the height of the confined waters
+increases, the range of their journey over the bottom as the wave
+comes and goes rapidly increases. When they have an elevation of ten
+feet they can probably stir the finer mud on the ocean floor, and in
+shallow water move yet heavier particles. In the embayments of the
+land, where a great body of water journeys like an alternating river
+into extensive basins, the tidal action becomes intense; the current
+may be able to sweep along large stones quite as effectively as a
+mountain torrent. Thus near Eastport, Me., where the tides have a
+maximum rise and fall of over twenty feet, the waters rush in places
+so swiftly that at certain stages of the movement they are as much
+troubled as those at the rapids of the St. Lawrence. In such portions
+of the shore the tides do important work in carving channels into the
+lands.
+
+Along the shores of the continents about the North Atlantic, where the
+tides act in a vigorous manner, we almost everywhere find an
+underwater shelf extending from the shore with a declivity of only
+five to ten feet to the mile toward the centre of the sea, until the
+depth of about five hundred feet is attained; from this point the
+bottom descends more steeply into the ocean's depth. It is probable
+that the larger part of the material composing these continental
+shelves has been brought to its position by tidal action. Each time
+the tidal wave sweeps in toward the shore it urges the finer particles
+of sediment along with it. When it moves out it drags them on the
+return journey toward the depths of the sea. If this shelf were
+perfectly horizontal, the two journeys of the sand and mud grains
+would be of the same length; but as the movement takes place up and
+down a slope, the bits will travel farther under the impulse which
+leads them downward than under that which impels them up. The result
+will be that the particles will travel a little farther out from the
+shore each time it is swung to and fro in the alternating movement of
+the tide.
+
+The effect of tidal movement in nurturing marine life is very great.
+It aids the animals fixed on the bottoms of the deep seas to obtain
+their provision of food and their share of oxygen by drawing the water
+by their bodies. All regions which are visited by strong tides
+commonly have in the shallows near the shores a thick growth of
+seaweed which furnishes an ample provision of food for the fishes and
+other forms of animal life.
+
+A peculiar effect arising from tidal action is believed by students of
+the phenomena to be found in the slowing of the earth's rotation on
+its axis. The tides rotate around the earth from east to west, or
+rather, we should say, the solid mass of the earth rubs against them
+as it spins from west to east. As they move over the bottom and as
+they strike against the shores this push of the great waves tends in a
+slight measure to use up the original spinning impulse which causes
+the earth's rotation. Computation shows that the amount of this action
+should be great enough gradually to lengthen the day, or the time
+occupied by the earth in making a complete revolution on the polar
+axis. The effect ought to be great enough to be measurable by
+astronomers in the course of a thousand years. On the other hand, the
+records of ancient eclipses appear pretty clearly to show that the
+length of the day has not changed by as much as a second in the course
+of three thousand years. This evidence does not require us to abandon
+the supposition that the tides tend to diminish the earth's rate of
+rotation. It is more likely that the effect of the reduction in the
+earth's diameter due to the loss of heat which is continually going on
+counterbalances the influence of the tidal friction. As the diameter
+of a rotating body diminishes, the tendency is for the mass to spin
+more rapidly; if it expands, to turn more slowly, provided in each
+case the amount of the impulse which leads to the turning remains the
+same. This can be directly observed by whirling a small weight
+attached to a string in such a manner that the cord winds around the
+finger with each revolution; it will be noted that as the line
+shortens the revolution is more quickly accomplished. We can readily
+conceive that the earth is made up of weights essentially like that
+used in the experiment, each being drawn toward the centre by the
+gravitative stress, which is like that applied to the weight by the
+cord.
+
+The fact that the days remain of the same length through vast periods
+of time is probably due to this balance between the effects of tidal
+action and those arising from the loss of heat--in other words, we
+have here one of those delicate arrangements in the way of
+counterpoise which serve to maintain the balanced conditions of the
+earth's surface amid the great conflicts of diverse energies which are
+at work in and upon the sphere.
+
+It should be understood that the effects of the attraction which
+produces tides are much more extensive than they are seen to be in the
+movements of the sea. So long as the solar and planetary spheres
+remain fluid, the whole of their masses partake of the movement. It is
+a consequence of this action, as the computations of Prof. George
+Darwin has shown, that the moon, once nearer the earth than it is at
+present, has by a curious action of the tidal force been pushed away
+from the centre of our sphere, or rather the two bodies have repelled
+each other. An American student of the problem, Mr. T.J.J. See, has
+shown that the same action has served to give to the double stars the
+exceeding eccentricity of their orbits.
+
+Although these recent studies of tidal action in the celestial sphere
+are of the utmost importance to the theory of the universe, for they
+may lead to changes in the nebular hypotheses, they are as yet too
+incomplete and are, moreover, too mathematical to be presented in an
+elementary treatise such as this.
+
+                  *       *       *       *       *
+
+We now turn to another class of waves which are of even more
+importance than those of the tides--to the undulations which are
+produced by the action of the wind on the surface of the water. While
+the tide waves are limited to the open ocean, and to the seas and bays
+which afford them free entrance, wind waves are produced everywhere
+where water is subjected to the friction of air which flows over it.
+While tidal waves come upon the shores but twice each day, the wind
+waves of ordinary size which roll in from the ocean deliver their
+blows at intervals of from three to ten seconds. Although the tidal
+waves sometimes, by a packing-up process, attain the height of fifty
+feet, their average altitude where they come in contact with the shore
+probably does not much exceed four feet; usually they come in gently.
+It is likely that in a general way the ocean surges which beat against
+the coast are of greater altitude.
+
+Wind waves are produced and perform their work in a manner which we
+shall now describe. When the air blows over any resisting surface, it
+tends, in a way which we can hardly afford here to describe, to
+produce motions. If the particle is free to move under the impulse
+which it communicates, it bears it along; if it is linked together in
+the manner of large masses, which the wind can not transport, it tends
+to set it in motion in an alternating way. The sounds of our musical
+instruments which act by wind are due to these alternating vibrations,
+such as all air currents tend to produce. An Æolian harp illustrates
+the action which we are considering. Moving over matter which has the
+qualities that we denote by the term fluid, the swayings which the air
+produces are of a peculiar sort, though they much resemble those of
+the fiddle string. The surface of the liquid rises and falls in what
+we term waves, the size of which is determined by the measure of
+fluidity, and by the energy of the wind. Thus, because fresh water is
+considerably lighter than salt, a given wind will produce in a given
+distance for the run of the waves heavier surges in a lake than it
+will in the sea. For this reason the surges in a great storm which
+roll on the ocean shore, because of the wide water over which they
+have gathered their impetus, are in size very much greater than those
+of the largest lakes, which do not afford room for the development of
+great undulations.
+
+To the eye, a wave in the water appears to indicate that the fluid is
+borne on before the wind. Examination, however, shows that the amount
+of motion in the direction in which the wind is blowing is very
+slight. We may say, indeed, that the essential feature of a wave is
+found in the transmission of impulse rather than in the movement of
+the fluid matter. A strip of carpet when shaken sends through its
+length undulations which are almost exactly like water waves. If we
+imagine ourselves placed in a particle of water, moving in the
+swayings of a wave in the open and deep sea, we may conceive ourselves
+carried around in an ellipse, in each revolution returning through
+nearly the same orbit. Now and then, when the particle came to the
+surface, it would experience the slight drift which the continual
+friction of the wind imposes on the water. If the wave in which the
+journey was made lay in the trade winds, where the long-continued,
+steadfast blowing had set the water in motion to great depths, the
+orbit traversed would be moving forward with some rapidity; where also
+the wind was strong enough to blow the tops of the waves over, forming
+white-caps, the advance of the particle very near the surface would be
+speedy. Notwithstanding these corrections, waves are to be regarded
+each as a store of energy, urging the water to sway much in the manner
+of a carpet strip, and by the swaying conveying the energy in the
+direction of the wave movement.
+
+The rate of movement of wind waves increases with their height.
+Slight undulations go forward at the rate of less than half a mile an
+hour. The greater surges of the deeps when swept by the strongest
+winds move with the speed which, though not accurately determined, has
+been estimated by the present writer as exceeding forty miles an hour.
+As these surges often have a length transverse to the wind of a mile
+or more, a width of about an eighth of a mile, and a height of from
+thirty-five to forty-five feet, the amount of energy which they
+transmit is very great. If it could be effectively applied to the
+shores in the manner in which the energy of exploding gunpowder is
+applied by cannon shot, it is doubtful whether the lands could have
+maintained their position against the assaults of the sea. But there
+are reasons stated below why the ocean waves can use only a very small
+part of their energy in rending the rocks against which they strike on
+the coast line.
+
+In the first place, we should note that wind waves have very little
+influence on the bottom of the deep sea. If an observer could stand on
+the sea floor at the depth of a mile below a point over which the
+greatest waves were rolling, he could not with his unaided senses
+discern that the water was troubled. He would, indeed, require
+instruments of some delicacy to find out that it moved at all. Making
+the same observations at the depth of a thousand feet, it is possible
+that he would note a slight swaying motion in the water, enough
+sensibly to affect his body. At five hundred feet in depth the
+movement would probably be sufficient to disturb fine mud. At two
+hundred feet, the rasping of the surge on the bottom would doubtless
+be sufficient to push particles of coarse sand to and fro. At one
+hundred feet in depth, the passage of the surge would be strong enough
+to urge considerable pebbles before it. Thence up the slope the
+driving action would become more and more intense until we attained
+the point where the wave broke. It should furthermore be noted that,
+while the movement of the water on the floor of the deep sea as the
+wave passes overhead would be to and fro, with every advance in the
+shallowing and consequent increased friction on the bottom, the
+forward element in the movement would rapidly increase. Near the coast
+line the effect of the waves is continually to shove the detritus up
+the slopes of the continental shelf. Here we should note the fact that
+on this shelf the waves play a part exactly the opposite of that
+effected by the tides. The tides, as we have noted, tend to drag the
+particles down the slope, while the waves operate to roll them up the
+declivity.
+
+As the wave in advancing toward the shore ordinarily comes into
+continually shallowing water, the friction on the bottom is
+ever-increasing, and serves to diminish the energy the surge contains,
+and therefore to reduce its proportions. If this action operated
+alone, the subtraction which the friction makes would cause the surf
+waves which roll in over a continental shelf to be very low, probably
+in height less than half that which they now attain. In fact, however,
+there is an influence at work to increase the height of the waves at
+the expense of its width. Noting that the friction rapidly increases
+with the shallowing, it is easy to see that this resistance is
+greatest on the advancing front of the wave, and least on its seaward
+side. The result is that the front moves more slowly than the rear, so
+that the wave is forced to gain in height; but for the fact that the
+total friction which the wave encounters takes away most of its
+impetus, we might have combers a hundred feet high rolling upon the
+shelving shores which almost everywhere face the seas.
+
+As the wave shortens its width and gains in relative height, though
+not in actual elevation, another action is introduced which has
+momentous consequences. The water in the bottom of the wave is greatly
+retarded in its ongoing by its friction over the sea floor, while the
+upper part of the surge is much less affected in this way. The result
+is that at a certain point in the advance, the place of which is
+determined by the depth, the size, and the speed of the undulation,
+the front swiftly steepens until it is vertical, and the top shoots
+forward to a point where it is no longer supported by underlying
+water, when it plunges down in what is called the surf or breaker. In
+this part of the wave's work the application of the energy which it
+transmits differs strikingly from the work previously done. Before the
+wave breaks, the only geological task which it accomplishes is
+effected by forcing materials up the slope, in which movement they are
+slightly ground over each other until they come within the battering
+zone of the shore, where they may be further divided by the action of
+the mill which is there in operation.
+
+When the wave breaks on the shore it operates in the following manner:
+First, the overturning of its crest sends a great mass of water, it
+may be from the height of ten or more feet, down upon the shore. Thus
+falling water has not only the force due to its drop from the summit
+of the wave, but it has a share of the impulse due to the velocity
+with which the surge moved against the shore. It acts, in a word, like
+a hammer swung down by a strong arm, where the blow represents not
+only the force with which the weight would fall of itself, but the
+impelling power of the man's muscles. Any one who will expose his body
+to this blow of the surf will recognise how violent it is; he may, if
+the beach be pebbly, note how it drives the stones about; fragments
+the size of a man's head may be hurled by the stroke to the distance
+of twenty feet or more; those as large as the fist may be thrown clear
+beyond the limits of the wave. So vigorous is this stroke that the
+sound of it may sometimes be heard ten miles inland from the coast
+where it is delivered.
+
+Moving forward up the slope of a gently inclined beach, the fragments
+of the wave are likely to be of sufficient volume to permit them to
+regather into a secondary surge, which, like the first, though much
+smaller, again rises into a wall, forming another breaker. Under
+favourable conditions as many as four or five of these successive
+diminishing surf lines may be seen. The present writer has seen in
+certain cases as many as a dozen in the great procession, the lowest
+and innermost only a few inches high, the outer of all with a height
+of perhaps twenty feet.
+
+Along with the direct bearing action of the surf goes a to-and-fro
+movement, due to the rushing up and down of the water on the beach.
+This swashing affects not only the broken part of the waves, but all
+the water between the outer breaker and the shore. These swayings in
+the surf belt often swing the _débris_ on the inner margin over a
+range of a hundred feet or more, the movement taking place with great
+swiftness, affecting the pebbles to the depth of several inches, and
+grinding the bits together in a violent way. Listening to the turmoil
+of a storm, we can on a pebbly beach distinctly hear the sound of the
+downward stroke, a crashing tone, and the roar of the rolling stones.
+
+As waves are among the interesting things in the world, partly on
+account of their living quality and partly because of their immediate
+and often exceeding interest to man, we may here note one or two
+peculiar features in their action. In the first place, as the reader
+who has gained a sense of the changes in form of action may readily
+perceive, the beating of waves on the shore converts the energy which
+they possess into heat. This probably warms the water during great
+storms, so that by the hand we may note the difference in temperature
+next the coast line and in the open waters. This relative warmth of
+the surf water is perhaps a matter of some importance in limiting the
+development of ice along the shore line; it may also favour the
+protection of the coast life against the severe cold of the winter
+season.
+
+The waves which successively come against the shore in any given time,
+particularly if a violent wind is blowing on to the coast, are usually
+of about the same size. When, however, in times of calm an old sea, as
+it is called, is rolling in, the surges may occasionally undergo very
+great variations in magnitude. Not infrequently these occasional waves
+are great enough to overwhelm persons who are upon the rocks next the
+shore. These greater surges are probably to be accounted for by the
+fact that in the open sea waves produced by winds blowing in different
+directions may run on with their diverse courses and varied intervals
+until they come near the shore. Running in together, it very well
+happens that two of the surges belonging to different sets may combine
+their forces, thus doubling the swell. The danger which these
+conjoined waves bring is obviously greatest on cliff shores, where, on
+account of the depth of water, the waves do not break until they
+strike the steep.
+
+                  *       *       *       *       *
+
+Having considered in a general way the action of waves as they roll in
+to the shore, bearing with them the solar energy which was contributed
+to them by the winds, we shall now take up in some detail the work
+which goes on along the coast line--work which is mainly accomplished
+by wave action.
+
+On most coast lines the observer readily notes that the shore is
+divided into two different kinds of faces--those where the inner
+margin of the wave-swept belt comes against rocky steeps, and those
+bordered by a strand altogether composed of materials which the surges
+have thrown up. These may be termed for convenience cliff shores and
+wall-beach shores. We shall begin our inquiry with cliff shores, for
+in those sections of the coast line the sea is doing its most
+characteristic and important work of assaulting the land. If the
+student has an opportunity to approach a set of cliffs of hard rock in
+time of heavy storm, when the waves have somewhere their maximum
+height, he should seek some headland which may offer him safe foothold
+whence he can behold the movements which are taking place. If he is so
+fortunate as to have in view, as well may be the case, cliffs which
+extend down into deep water, and others which are bordered by rude
+and generally steeply sloping beaches covered with large stones, he
+may perceive that the waves come in against the cliffs which plunge
+into deep water without taking on the breaker form. In this case the
+undulation strikes but a moderate blow; the wave is not greatly
+broken. The part next the rock may shoot up as a thin sheet to a
+considerable height; it is evident that while the ongoing wave applies
+a good deal of pressure to the steep, it does not deliver its energy
+in the effective form of a blow as when the wave overturns, or in the
+consequent rush of the water up a beach slope. It is easy to perceive
+that firm-set rock cliffs, with no beaches at their bases, can almost
+indefinitely withstand the assaults. On the steep and stony beach,
+because of its relatively great declivity, the breaker or surf forms
+far in, and even in its first plunge often attains the base of the
+precipice. The blow of the overfalling as well as that of the inrush
+moves about stones of great size; those three feet or more in diameter
+are often hurled by the action against the base of the steep, striking
+blows, the sharp note of which can often be heard above the general
+roar which the commotion produces. The needlelike crags forming isles
+standing at a distance from the shore, such as are often found along
+hard rock coasts, are singularly protected from the action of
+effective waves. The surges which strike against them are unarmed with
+stones, and the water at their bases is so deep that it does not sway
+with the motion with sufficient energy to move them on the bottom.
+Where a cliff is in this condition, it may endure until an elevation
+of the coast line brings its base near the level of the sea, or until
+the process of decay has detached a sufficient quantity of stone to
+form a talus or inclined plane reaching near to the water level.
+
+As before noted, it is the presence of a sloping beach reaching to
+about the base of the cliff which makes it possible for the waves to
+strike at with a hammer instead of with a soft hand. Battering at the
+base of the cliff, the surges cut a crease along the strip on which
+they strike, which gradually enters so far that the overhanging rock
+falls of its own weight. The fragments thus delivered to the sea are
+in turn broken up and used as battering instruments until they are
+worn to pieces. We may note that in a few months of heavy weather the
+stones of such a fall have all been reduced to rudely spherical forms.
+Observations made on the eastern face of Cape Ann, Mass., where the
+seas are only moderately heavy, show that the storms of a single
+winter reduce the fragments thrown into the sea from the granite
+quarries to spheroidal shapes, more than half of their weight commonly
+being removed in the form of sand and small pebbles which have been
+worn from their surfaces.
+
+We can best perceive the effect of battering action which the sea
+applies to the cliffs by noting the points where, owing to some chance
+features in the structure in the rock, it has proved most effective.
+Where a joint or a dike, or perhaps a softer layer, if the rocks be
+bedded, causes the wear to go on more rapidly, the waves soon excavate
+a recess in which the pebbles are retained, except in stormy weather,
+in an unmoved condition. When the surges are heavy, these stones are
+kept in continuous motion, receding as the wave goes back, and rushing
+forward with its impulse until they strike against the firm-set rock
+at the end of the chasm. In this way they may drive in a cut having
+the length of a hundred feet or more from the face of the precipice.
+In most cases the roofs over these sea caves fall in, so that the
+structure is known as a chasm. Occasionally these roofs remain, in
+which case, for the reason that the floor of the cutting inclines
+upward, an opening is made to the surface at their upper end, forming
+what is called in New England a "spouting horn"; from the inland end
+of the tunnel the spray may be thrown far into the air. As long as the
+cave is closed at this inner end, and is not so high but that it may
+be buried beneath a heavy wave, the inrushing water compresses the
+air in the rear parts of the opening. When the wave begins to retreat
+this air blows out, sending a gust of spray before it, the action
+resembling the discharge of a great gun from the face of a
+fortification. It often happens that two chasms converging separate a
+rock from the cliff. Then a lowering of the coast may bring the mass
+to the state of a columnar island, such as abound in the Hebrides and
+along various other shores.
+
+If a cliff shore retreats rapidly, it may be driven back into the
+shore, and its face assumes the curve of a small bay. With every step
+in this change the bottom is sure to become shallower, so that the
+waves lose more and more of their energy in friction over the bottom.
+Moreover, in entering a bay the friction which the waves encounter in
+running along the sides is greater than that which they meet in
+coming in upon a headland or a straight shore. The result is, with the
+inward retreat of the steep it enters on conditions which diminish the
+effectiveness of the wave stroke. The embayment also is apt to hold
+detritus, and so forms in time a beach at the foot of the cliff, over
+which the waves rarely are able to mount with such energy as will
+enable them to strike the wall in an effective manner. With this
+sketch of the conditions of a cliff shore, we will now consider the
+fate of the broken-tip rock which the waves have produced on that
+section of the coast land.
+
+By observation of sea-beaten cliffs the student readily perceives that
+a great amount of rocky matter has been removed from most cliff-faced
+shores. Not uncommonly it can be shown that such sea faces have
+retreated for several miles. The question now arises, What becomes of
+the matter which has been broken up by the wave action? In some part
+the rock, when pulverized by the pounding to which it is subjected,
+has dissolved in the water. Probably ninety per cent of it, however,
+retains the visible state, and has a fate determined by the size of
+the fragments of which it is composed. If these be as fine as mud, so
+that they may float in the water, they are readily borne away by the
+currents which are always created along a storm-swept shore,
+particularly by the undertow or bottom outcurrent--the "sea-puss," as
+it is sometimes called--that sweeps along the bottom from every shore,
+against which the waves form a surf. If as coarse as sand grains, or
+even very small pebbles, they are likely to be drawn out, rolling over
+the bottom to an indefinite distance from the sea margin. The coarser
+stones, however, either remain at the foot of the cliff until they are
+beaten to pieces, or are driven along the shore until they find some
+embayment into which they enter. The journey of such fragments may,
+when the wind strikes obliquely to the shore, continue for many miles;
+the waves, running with the wind, drive the fragments in oscillating
+journeys up and down the beach, sometimes at the rate of a mile or
+more a day. The effect of this action can often be seen where a vessel
+loaded with brick or coal is wrecked on the coast. In a month
+fragments of the materials may be stretched along for the distance of
+many miles on either side of the point where the cargo came ashore.
+Entering an embayment deep enough to restrain their further journey,
+the fragments of rock form a boulder beach, where the bits roll to and
+fro whenever they are struck by heavy surges. The greater portion of
+them remain in this mill until they are ground to the state of sand
+and mud. Now and then one of the fragments is tossed up beyond the
+reach of the waves, and is contributed to the wall of the beach. In
+very heavy storms these pebbles which are thrown inland may amount in
+weight to many tons for each mile of shore.
+
+The study of a pebbly beach, drawn from crest to the deep water
+outside, will give an idea as to the history of its work. On either
+horn of the crescent by which the pebbles are imported into the pocket
+we find the largest fragments. If the shore of the bay be long, the
+innermost part of the recess may show even only very small pebbles, or
+perhaps only fine sand, the coarser material having been worn out in
+the journey. On the bottom of the bay, near low tide, we begin to find
+some sand produced by the grinding action. Yet farther out, below
+high-tide mark, there is commonly a layer of mud which represents the
+finer products of the mill.
+
+Boulder beaches are so quick in answering to every slight change in
+the conditions which affect them that they seem almost alive. If by
+any chance the supply of detritus is increased, they fill in between
+the horns, diminish the incurve of the bay, and so cause its beach to
+be more exposed to heavy waves. If, on the other hand, the supply of
+grist to the mill is diminished, the beach becomes more deeply
+incurved, and the wave action is proportionately reduced. We may say,
+in general, that the curve of these beaches represents a balance
+between the consumption and supply of the pebbles which they grind up.
+The supply of pebbles brought along the shore by the waves is in many
+cases greatly added to by a curious action of seaweeds. If the bottom
+of the water off the coast is covered by these fragments, as is the
+case along many coast lines within the old glaciated districts, the
+spores of algæ are prone to take root upon them. Fastening themselves
+in those positions, and growing upward, the seaweeds may attain
+considerable size. Being provided with floats, the plant exercises a
+certain lifting power on the stone, and finally the tugging action of
+the waves on the fronds may detach the fragments from the bottom,
+making them free to journey toward the shore. Observing from near at
+hand the straight wall of the wave in times of heavy storm, the
+present writer has seen in one view as many as a dozen of these
+plant-borne stones, sometimes six inches in diameter, hanging in the
+walls of water as it was about to topple over. As soon as they strike
+the wave-beaten part of the shore these stones are apt to become
+separated from the plants, though we can often notice the remains or
+prints of the attachments adhering to the surface of the rock. Where
+the pebbles off the shore are plenty, a rocky beach may be produced
+by this process of importation through the agency of seaweeds without
+any supply being brought by the waves along the coast line.
+
+Returning to sand beaches, we enter the most interesting field of
+contact between seas and lands. Probably nine tenths of all the coast
+lines of the open ocean are formed of arenaceous material. In general,
+sand consists of finely broken crystals of silica or quartz. These
+bits are commonly distinctly faceted; they rarely have a spherical
+form. Not only do accumulations of sand border most of the shore line,
+but they protect the land against the assaults of the sea, and this in
+the following curious manner: When shore waves beat pebbles against
+each other, they rapidly wear to bits; we can hear the sound of the
+wearing action as the wave goes to and fro. We can often see that the
+water is discoloured by the mud or powdered rock. When, however, the
+waves tumble on a sandy coast, they make but a muffled sound, and
+produce no mud. In fact, the particles of sand do not touch each other
+when they receive the blow. Between them there lies a thin film of
+water, drawn in by the attraction known as capillarity, which sucks
+the fluid into a sponge or between plates of glass placed near
+together. The stroke of the waves slightly compresses this capillary
+water, but the faces of the grains are kept apart as sheets of glass
+may be observed to be restrained from contact when water is between
+them. If the reader would convince himself as to the condition of the
+sand grains and the water which is between them, he may do so by
+pressing his foot on the wet beach which the wave has just left. He
+will observe that it whitens and sinks a little under the pressure,
+but returns in good part to its original form when the foot is lifted.
+In the experiment he has pushed a part of the contained water aside,
+but he has not brought the grains together; they do not make the sound
+which he will often hear when the sand is dry. The result is that the
+sand on the seashore may wear more in going the distance of a mile in
+the dry sand dune than in travelling for hundreds along the wet shore.
+
+If the rock matter in the state of sand wore as rapidly under the
+heating of the waves as it does in the state of pebbles, the
+continents would doubtless be much smaller than they are. Those coasts
+which have no other protection than is afforded by a low sand beach
+are often better guarded against the inroads of the sea than the
+rock-girt parts of the continents. It is on account of this remarkable
+endurance of sand of the action of the waves that the stratified rocks
+which make up the crust of the earth are so thick and are to such an
+extent composed of sand grains.
+
+The tendency of the _débris_-making influences along the coast line is
+to fill in the irregularities which normally exist there; to batter
+off the headlands, close up the bays and harbours, and generally to
+reduce the shores to straight lines. Where the tide has access to
+these inlets, it is constantly at work in dragging out the detritus
+which the waves make and thrust into the recesses. These two actions
+contend with each other, and determine the conditions of the coast
+line, whether they afford ports for commerce or are sealed in by sand
+bars, as are many coast lines which are not tide-swept, as that of
+northern Africa, which faces the Mediterranean, a nearly tideless sea.
+The same is the case with the fresh-water lakes; even the greater of
+them are often singularly destitute of shelters which can serve the
+use of ships, and this because there are no tides to keep the bays and
+harbours open.
+
+
+                        THE OCEAN CURRENTS.
+
+The system of ocean currents, though it exhibits much complication in
+detail, is in the main and primarily dependent on the action of the
+constant air streams known as the trade winds. With the breath from
+the lips over a basin of water we can readily make an experiment which
+shows in a general way the method in which the winds operate in
+producing the circulation of the sea. Blowing upon the surface of the
+water in the basin, we find that even this slight impulse at once sets
+the upper part in motion, the movement being of two kinds--pulsating
+movements or waves are produced, and at the same time the friction of
+the air on the surface causes its upper part to slide over the under.
+With little floats we can shortly note that the stream which forms
+passes to the farther side of the vessel, there divides, and returns
+to the point of beginning, forming a double circle, or rather two
+ellipses, the longer sides of which are parallel with the line of the
+air current. Watching more closely, aiding the sight by the particles
+which float at various distances below the surface, we note the fact
+that the motion which was at first imparted to the surface gradually
+extends downward until it affects the water to the depth of some
+inches.
+
+In the trade-wind belt the ocean waters to the depth of some hundreds
+of feet acquire a continuous movement in the direction in which they
+are impelled by those winds. This motion is most rapid at the surface
+and near the tropics. It diminishes downwardly in the water, and also
+toward the polar sides of the trade-wind districts. Thus the trades
+produce in the sea two broad, slow-moving, deep currents, flowing in
+the northern hemisphere toward the southwest, and in the southern
+hemisphere toward the northwest. Coming down upon each other
+obliquely, these broad streams meet about the middle of the tropical
+belt. Here, as before noted, the air of the trade winds leaves the
+surface and rises upward. The waters being retained on their level,
+form a current which moves toward the west. If the earth within the
+tropics were covered by a universal sea, the result of this movement
+would be the institution of a current which, flowing under the
+equator, would girdle the sphere.
+
+With a girdling equatorial current, because of the intense heat of the
+tropics and the extreme cold of the parallels beyond the fortieth
+degree of latitude, the earth would be essentially uninhabitable to
+man, and hardly so to any forms of life. Its surface would be visited
+by fierce winds induced by the very great differences of temperature
+which would then prevail. Owing, however, to the barriers which the
+continents interpose to the motions of these windward-setting tropical
+currents, all the water which they bear, when it strikes the opposing
+shores, is diverted to the right and left, as was the stream in the
+experiment with the basin and the breath, the divided currents seeking
+ways toward high latitudes, conveying their store of heat to the
+circumpolar lands. So effective is this transfer of temperature that a
+very large part of the heat which enters the waters in the tropical
+region is taken out of that division of the earth's surface and
+distributed over the realms of sea and land which lie beyond the
+limits of the vertical sun. Thus the Gulf Stream, the northern branch
+of the Atlantic tropical current, by flowing into the North Atlantic,
+contributes to the temperature of the region within the Arctic Circle
+more heat than actually comes to that district by the direct influx
+from the sun.
+
+The above statements as to the climatal effect of the ocean streams
+show us how important it is to obtain a sufficient conception as to
+the way in which these currents now move and what we can of their
+history during the geologic ages. This task can not yet be adequately
+done. The fields of the sea are yet too imperfectly explored to afford
+us all the facts required to make out the whole story. Only in the
+case of our Gulf Stream can we form a full conception as to the
+journey which the waters undergo and the consequence of their motion.
+In the case of this current, observations clearly show that it arises
+from the junction near the equatorial line of the broad stream created
+by the two trade-wind belts. Uniting at the equator, these produce a
+westerly setting current, having the width of some hundred miles and a
+depth of several hundred feet. Its velocity is somewhat greater than a
+mile an hour. The centre of the current, because of the greater
+strength of the northern as compared with the southern trades, is
+considerably south of the equator. When this great slow-moving stream
+comes against the coast of South America, it encounters the projecting
+shoulder of that land which terminates at Cape St. Roque. There it
+divides, as does a current on the bows of an anchored ship, a
+part--rather more than one half--of the stream turning to the
+northward, the remainder passing toward the southern pole; this
+northerly portion becomes what is afterward known as the Gulf Stream,
+the history of which we shall now briefly follow.
+
+Flowing by the northwesterly coast of South America, the northern
+share of the tropical current, being pressed in against the land by
+the trade winds, is narrowed, and therefore acquires at once a swifter
+flow, the increased speed being due to conditions like those which add
+to the velocity of the water flowing through a hose when it comes to
+the constriction of the nozzle. Attaining the line of the southeastern
+or Lesser Antilles, often known as the Windward Islands, a part of
+this current slips through the interspaces between these isles and
+enters the Gulf of Mexico. Another portion, failing to find sufficient
+room through these passages, skirts the Antilles on their eastern and
+northern sides, passes by and among the Bahama Islands, there to
+rejoin the part of the stream which entered the Caribbean. This
+Caribbean portion of the tide spreads widely in that broad sea, is
+constricted again between Cuba and Yucatan, again expands in the Gulf
+of Mexico, and is finally poured forth through the Straits of Florida
+as a stream having the width of forty or fifty miles, a depth of a
+thousand feet or more, and a speed of from three to five miles an
+hour, exceeding in its rate of flow the average of the greatest
+rivers, and conveying more water than do all the land streams of the
+earth. In this part of its course the deep and swift stream from the
+Gulf of Mexico, afterward to be named the Gulf Stream, receives the
+contribution of slower moving and shallower currents which skirted the
+Antilles on their eastern verge. The conjoined waters then move
+northward, veering toward the east, at first as a swift river of the
+sea having a width of less than a hundred miles and of great depth;
+with each step toward the pole this stream widens, diminishing
+proportionately in depth; the speed of its current decreases as the
+original impetus is lost, and the baffling winds set its surface
+waters to and fro in an irregular way. Where it passes Cape Hatteras
+it has already lost a large share of its momentum and much of its
+heat, and is greatly widened.
+
+Although the current of the Gulf Stream becomes more languid as we go
+northward, it for a very long time retains its distinction from the
+waters of the sea through which it flows. Sailing eastward from the
+mouth of the Chesapeake, the navigator can often observe the moment
+when he enters the waters of this current. This is notable not only in
+the temperature, but in the hue of the sea. North of that line the
+sharpness of the parting wall becomes less distinct, the stream
+spreads out broadly over the surface of the Atlantic, yet its
+thermometric effects are distinctly traceable to Iceland and Nova
+Zembla, and the tropical driftwood which it carries affords the
+principal timber supply of the inhabitants of the first-named isle.
+Attaining this circumpolar realm, and finally losing the impulse which
+bore it on, the water of the Gulf Stream partly returns to the
+southward in a relatively slight current which bears the fluid along
+the coast of Europe until it re-enters the system of tropical winds
+and the currents which they produce. A larger portion stagnates in the
+circumpolar region, in time slowly to return to the tropical district
+in a manner afterward to be described. Although the Gulf Stream in the
+region north of Cape Hatteras is so indistinct that its presence was
+not distinctly recognised until the facts were subjected to the keen
+eye of Benjamin Franklin, its effects in the way of climate are so
+great that we must attribute the fitness of northern Europe for the
+uses of civilized man to its action. But for the heat which this
+stream brings to the realm of the North Atlantic, Great Britain would
+be as sterile as Labrador, and the Scandinavian region, the
+cradle-land of our race, as uninhabitable as the bleakest parts of
+Siberia.
+
+It is a noteworthy fact that when the equatorial current divides on
+the continents against which it flows, the separate streams, although
+they may follow the shores for a certain distance toward the poles,
+soon diverge from them, just as the Gulf Stream passes to the seaward
+from the eastern coast of the United States. The reason for this
+movement is readily found in the same principle which explains the
+oblique flow of the trades and counter trades in their passage to and
+from the equatorial belt. The particle of water under the equator,
+though it flows to the west, has, by virtue of the earth's rotation,
+an eastward-setting velocity of a thousand miles an hour. Starting
+toward the poles, the particle is ever coming into regions of the sea
+where the fluid has a less easterly movement, due to the earth's
+rotation on its axis. Consequently the journeying water by its
+momentum tends to move off in an easterly course. Attaining high
+latitudes and losing its momentum, it abides in the realm long enough
+to become cooled.
+
+We have already noted the fact that only a portion of the waters sent
+northward in the Gulf Stream and the other currents which flow from
+the equator to the poles is returned by the surface flow which sets
+toward the equator along the eastern side of the basins. The largest
+share of the tide effects its return journey in other ways. Some
+portion of this remainder sets equatorward in local cold streams, such
+as that which pours forth through Davis Strait into Baffin Bay,
+flowing under the Gulf Stream waters for an unknown distance toward
+the tropics. There are several of these local as yet little known
+streams, which doubtless bring about a certain amount of circulation
+between the polar regions and the tropical districts. Their effect is,
+however, probably small as compared with that massive drift which we
+have now to note.
+
+The tropical waters when they attain high latitudes are constantly
+cooled, and are overlaid by the warmer contributions of that tide, and
+are thus brought lower and lower in the sea. When they start downward
+they have, as observations show, a temperature not much above the
+freezing point of salt water. They do not congeal for the reason that
+the salt of the ocean lowers the point at which the water solidifies
+to near 28° Fahr. The effect of this action is gradually to press down
+the surface cold water until it attains the very bottom in all the
+circumpolar regions. At the same time this descending water drifts
+along the bottom of the ocean troughs toward the equatorial realm. As
+this cold water is heavier than that which is of higher temperature
+and nearer the surface, it has no tendency to rise. Being below the
+disturbing influences of any current save its own, it does not tend,
+except in a very small measure, to mingle with the warmer overlying
+fluid. The result is that it continues its journey until it may come
+within the tropics without having gained a temperature of more than
+35° Fahr., the increase in heat being due in small measure to that
+which it receives from the earth's interior and that which it acquires
+from the overlying warmer water. Attaining the region of the tropical
+current, this drift water from the poles gradually rises, to take the
+place of that which goes poleward, becomes warm, and again starts on
+its surface journey toward the arctic and antarctic regions.
+
+Nothing is known as to the rate of this bottom drift from the polar
+districts toward the equator, but, from some computation which he has
+made, the writer is of the opinion that several centuries is doubtless
+required for the journey from the Arctic Circle to the tropics. The
+speed of the movement probably varies; it may at times require some
+thousand years for its accomplishment. The effect of the bottom drift
+is to withdraw from seas in high latitudes the very cold water which
+there forms, and to convey it beneath the seas of middle latitudes to
+a realm where it is well placed for the reheating process. If all the
+cold water of circumpolar regions had to journey over the surface to
+the equator, the perturbing effect of its flow on the climates of
+various lands would be far greater than it is at present. Where such
+cold currents exist the effect is to chill the air without adding much
+to the rainfall; while the currents setting northward not only warm
+the regions near which they flow, but by so doing send from the water
+surfaces large quantities of moisture which fall as snow or rain. Thus
+the Gulf Stream, directly and indirectly, probably contributes more
+than half the rainfall about the Atlantic basin. The lack of this
+influence on the northern part of North America and Asia causes those
+lands to be sterilized by cold, although destitute of permanent ice
+and snow upon their surfaces.
+
+We readily perceive that the effect of the oceanic circulation upon
+the temperatures of different regions is not only great but widely
+contrasted. By taking from the equatorial belt a large part of the
+heat which falls within that realm, it lowers the temperature to the
+point which makes the district fit for the occupancy of man, perhaps,
+indeed, tenable to all the higher forms of life. This same heat
+removed to high latitudes tempers the winter's cold, and thus makes a
+vast realm inhabitable which otherwise would be locked in almost
+enduring frosts. Furthermore, this distribution of temperatures tends
+to reduce the total wind energy by diminishing the trades and counter
+trades which are due to the variations of heat which are encountered
+in passing polarward from the equator. Still further, but for this
+circulation of water in the sea, the oceans about the poles would be
+frozen to their very bottom, and this vast sheet of ice might be
+extended southward to within the parallels of fifty degrees north and
+south latitude, although the waters under the equator might at the
+same time be unendurably hot and unfit for the occupancy of living
+beings.
+
+A large part of the difficulties which geologists encounter in
+endeavouring to account for the changes of the past arise from the
+evidences of great climatal revolutions which the earth has undergone.
+In some chapters of the great stone book, whose leaves are the strata
+of the earth, we find it plainly written in the impressions made by
+fossils that all the lands beyond the equatorial belt have undergone
+changes which can only be explained by the supposition that the heat
+and moisture of the countries have been subjected to sudden and
+remarkable changes. Thus in relatively recent times thick-leaved
+plants which retained their vegetation in a rather tender state
+throughout the year have flourished near to the poles, while shortly
+afterward an ice sheet, such as now covers the greater part of
+Greenland, extended down to the line of the Ohio River at Cincinnati.
+Although these changes of climate are, as we shall hereafter note,
+probably due to entangled causes, we must look upon the modifications
+of the ocean streams as one of the most important elements in the
+causation. We can the more readily imagine such changes to be due to
+the alterations in the course and volume of the ocean current when we
+note how trifling peculiarities in the geography of the
+shores--features which are likely to be altered by the endless changes
+which occur in the form of a continent--affect the run of these
+currents. Thus the growth of coral reefs in southern Florida, and, in
+general, the formation of that peninsula, by narrowing the exit of the
+great current from the Gulf of Mexico, has probably increased its
+velocity. If Florida should again sink down, that current would go
+forth into the North Atlantic with the speed of about a mile an hour,
+and would not have momentum enough to carry its waters over half the
+vast region which they now traverse. If the lands about the western
+border of the Caribbean Sea, particularly the Isthmus of Darien,
+should be depressed to a considerable depth below the ocean level,
+the tropical current would enter the Pacific Ocean, adding to the
+temperature of its waters all the precious heat which now vitalizes
+the North Atlantic region. Such a geographic accident would not only
+profoundly alter the life conditions of that part of the world, but it
+would make an end of European civilization.
+
+In the chapter on climatal changes further attention will be given to
+the action of ocean currents from the point of view of their influence
+on the heat and moisture of different parts of the world. We now have
+to consider the last important influence of ocean currents--that which
+they directly exercise on the development of organic life. The most
+striking effect of this nature which the sea streams bring about is
+caused by the ceaseless transportation to which they subject the eggs
+and seeds of animals and plants, as well as the bodies of the mature
+form which are moved about by the flowing waters. But for the
+existence of these north and south flowing currents, due to the
+presence of the continental barriers, the living tenants of the seas
+would be borne along around the earth, always in the same latitude,
+and therefore exposed to the same conditions of temperature. In this
+state of affairs the influences which now make for change in organic
+species would be far less than they are. Journeying in the great
+whirlpools which the continental barriers make out of the westward
+setting tropical currents, these organic species are ever being
+exposed to alterations in their temperature conditions which we know
+to be favourable to the creation of those variations on which the
+advance of organic life so intimately depends. Thus the ocean currents
+not only help to vary the earth by producing changes in the climate of
+both sea and land, breaking up the uniformity which would otherwise
+characterize regions at the same distance from the equator, but they
+induce, by the consequences of the migrations which they enforce,
+changes in the organic tenants of the sea.
+
+Another immediate effect of ocean streams arises where their currents
+of warm water come against shores or shallows of the sea. At these
+points, if the water have a tropical temperature, we invariably find a
+vast and rapid development of marine animals and plants, of which the
+coral-making polyps are the most important. In such positions the
+growth of forms which secrete solid skeletons is so rapid that great
+walls of their remains accumulate next the shore, the mass being built
+outwardly by successive growths until the realm of the land may be
+extended for scores of miles into the deep. In other cases vast mounds
+of this organic _débris_ may be accumulated in mid ocean until its
+surface is interspersed with myriads of islands, all of which mark the
+work due to the combined action of currents and the marine life which
+they nourish. Probably more than four fifths of all the islands in the
+tropical belt are due in this way to the life-sustaining action of the
+currents which the trade winds create.
+
+There are many secondary influences of a less important nature which
+are due to the ocean streams. The reader will find on most wall-maps
+of the world certain areas in the central part of the oceans which are
+noted as Sargassum seas, of which that of the North Atlantic, west and
+south of the Azore Islands, is one of the most conspicuous. In these
+tracts, which in extent may almost be compared with the continents, we
+find great quantities of floating seaweed, the entangled fronds of
+which often form a mass sufficiently dense to slightly restrain the
+speed of ships. When the men on the caravels of Columbus entered this
+tangle, they were alarmed lest they should be unable to escape from
+its toils. It is a curious fact that these weeds of the sea while
+floating do not reproduce by spores the structures which answer to the
+seeds of higher plants, but grow only by budding. It seems certain
+that they could not maintain their place in the ocean but for the
+action of the currents which convey the bits rent off from the shores
+where the plant is truly at home. This vast growth of plant life in
+the Sargassum basins doubtless contributed considerable and important
+deposits of sediment to the sea floors beneath the waters which it
+inhabits. Certain ancient strata, known as the Devonian black shale,
+occupying the Ohio valley and the neighbouring parts of North America
+to the east and north of that basin, appear to be accumulations which
+were made beneath an ancient Sargassum sea.
+
+The ocean currents have greatly favoured and in many instances
+determined the migrations not only of marine forms, but of land
+creatures as well. Floating timber may bear the eggs and seeds of many
+forms of life to great distances until the rafts are cast ashore in a
+realm where, if the conditions favour, the creatures may find a new
+seat for their life. Seeds of plants incased in their often dense
+envelopes may, because they float, be independently carried great
+distances. So it comes about that no sooner does a coral or other
+island rise above the waters of the sea than it becomes occupied by a
+varied array of plants. The migrations of people, even down to the
+time of the voyages which discovered America, have in large measure
+been controlled by the run of the ocean streams. The tropical set of
+the waters to the westward helped Columbus on his way, and enabled him
+to make a journey which but for their assistance could hardly have
+been accomplished. This same current in the northern part of the Gulf
+Stream opposed the passage of ships from northern Europe to the
+westward, and to this day affects the speed with which their voyages
+are made.
+
+
+                    THE CIRCUIT OF THE RAIN.
+
+We have now to consider those movements of the water which depend upon
+the fact that at ordinary temperatures the sea yields to the air a
+continued and large supply of vapour, a contribution which is made in
+lessened proportion by water in all stages of coldness, and even by
+ice when it is exposed to dry air. This evaporation of the sea water
+is proportional to the temperature and to the dryness of the air where
+it rests upon the ocean. It probably amounts on the average to
+somewhere about three feet per annum; in regions favourably situated
+for the process, as on the west coast of northern Africa, it may be
+three or four times as much, while in the cold and humid air about the
+poles it may be as little as one foot. When contributed to the air,
+the water enters on the state of vapour, in which state it tends to
+diffuse itself freely through the atmosphere by virtue of the motion
+which is developed in particles when in the vaporous or gaseous state.
+
+The greater part of the water evaporated from the seas probably finds
+its way as rain at once back into the deep, yet a considerable portion
+is borne away horizontally until it encounters the land. The
+precipitation of the water from the air is primarily due to the
+cooling to which it is subjected as it rises in the atmosphere. Over
+the sea the ascent is accomplished by the simple diffusion of the
+vapour or by the uprise through the aërial shaft, such as that near
+the equator or over the centres of the whirling storms. It is when the
+air strikes the slopes of the land that we find it brought into a
+condition which most decidedly tends to precipitate its moisture.
+Lifted upward, the air as it ascends the slopes is brought into cooler
+and more rarefied conditions. Losing temperature and expanding, it
+parts with its water for the same reason that it does in the ascending
+current in the equatorial belt or in the chimneys of the whirl storms.
+A general consequence of this is that wherever moisture-laden winds
+from the sea impinge upon a continent they lay down a considerable
+part of the water which they contain.
+
+If all the lands were of the same height, the rain would generally
+come in largest proportion upon their coastal belt, or those portions
+of the shore-line districts over which the sea winds swept. But as
+these winds vary in the amount of the watery vapour which they
+contain, and as the surface of the land is very irregular, the
+rainfall is the most variable feature in the climatal conditions of
+our sphere. Near the coasts it ranges from two or three inches in arid
+regions--such as the western part of the Sahara and portions of the
+coast regions of Chili and Peru--to eight hundred inches about the
+head waters of the Brahmapootra River in northern India, where the
+high mountains are swept over by the moisture-laden airs from the
+neighbouring sea. Here and there detached mountainous masses produce a
+singular local increase in the amount of the rainfall. Thus in the
+lake district in northwestern England the rainfall on the seaward side
+of mountains, not over four thousand feet high, is very much greater
+than it is on the other slope, less than a score of miles away. These
+local variations are common all over the world, though they are but
+little observed.
+
+In general, the central parts of continents are likely to receive much
+less rainfall than their peripheral portions. Thus the central
+districts of North America, Asia, and Australia--three out of the five
+continental masses--have what we may call interior deserts. Africa has
+one such, though it is north of the centre, and extends to the shores
+of the Mediterranean and the Atlantic. The only continent without this
+central nearly rainless field is South America, where the sole
+characteristic arid district is situated on the western slope of the
+Cordilleran range. In this case the peculiarity is due to the fact
+that the strong westerly setting winds which sweep over the country
+encounter no high mountains until they strike the Andean chain. They
+journey up a long and rather gradual slope, where the precipitation is
+gradually induced, the process being completed when they strike the
+mountain wall. Passing over its summit, they appear as dry winds on
+the Pacific coast.
+
+Even while the winds frequently blow in from the sea, as along the
+western coast of the Americas, they may come over water which is
+prevailingly colder than the land. This is characteristically the case
+on the western faces of the American continent, where the sea is
+cooled by the currents setting toward the equator from high latitudes.
+Such cool sea air encountering the warm land has its temperature
+raised, and therefore does not tend to lay down its burden of
+moisture, but seeks to take up more. On this account the rainfall in
+countries placed under such conditions is commonly small.
+
+By no means all the moisture which comes upon the earth from the
+atmosphere descends in the form of rain or snow. A variable, large,
+though yet undetermined amount falls in the form of dew. Dew is a
+precipitation of moisture which has not entered the peculiar state
+which we term fog or cloud, but has remained invisible in the air. It
+is brought to the earth through the radiation of heat which
+continually takes place, but which is most effective during the
+darkened half of the day, when the action is not counterbalanced by
+the sun's rays. While the sun is high and the air is warm there is a
+constant absorption of moisture in large part from the ground or from
+the neighbouring water areas, probably in some part from those
+suspended stores of water, the clouds, if such there be in the
+neighbourhood. We can readily notice how clouds drifting in from the
+sea often melt into the dry air which they encounter. Late in the
+afternoon, even before the sun has sunk, the radiation of heat from
+the earth, which has been going on all the while, but has been less
+considerable than the incurrent of temperature, in a way overtakes
+that influx. The air next the surface becomes cooled from its contact
+with the refrigerating earth, and parts with its moisture, forming a
+coating of water over everything it touches. At the same time the
+moisture escaping from the warmed under earth likewise drops back upon
+its cooled surface almost as soon as it has escaped. The thin sheet of
+water precipitated by this method is quickly returned to the air when
+it becomes warmed by the morning sunshine, but during the night
+quantities of it are absorbed by the plants; very often, indeed, with
+the lowlier vegetation it trickles down the leaves and enters the
+earth about the base of the stem, so that the roots may appropriate
+it. Our maize, or Indian corn, affords an excellent example of a plant
+which, having developed in a land of droughts, is well contrived,
+through its capacities for gathering dew, to protect itself against
+arid conditions. In an ordinary dew-making night the leaves of a
+single stem may gather as much as half a pint of water, which flows
+down their surfaces to the roots. So efficient is this dew supply,
+this nocturnal cloudless rain, that on the western coast of South
+America and elsewhere, where the ordinary supply of moisture is almost
+wanting, many important plants are able to obtain from it much of the
+water which they need. The effect is particularly striking along
+seashores, where the air, although it may not have the humidity
+necessary for the formation of rain, still contains enough to form
+dew.
+
+It is interesting to note that the quantity of dew which falls upon an
+area is generally proportioned to the amount of living vegetation
+which it bears. The surfaces of leaves are very efficient agents of
+radiation, and the tangle which they make offers an amount of
+heat-radiating area many times as great as that afforded by a surface
+of bared earth. Moreover, the ground itself can not well cool down to
+the point where it will wring the moisture out of the air, while the
+thin membranes of the plants readily become so cooled. Thus vegetation
+by its own structure provides itself with means whereby it may be in a
+measure independent of the accidental rainfall. We should also note
+the fact that the dewfall is a concomitant of cloudless skies. The
+quantity which is precipitated in a cloudy night is very small, and
+this for the reason that when the heavens are covered the heat from
+the earth can not readily fly off into space. Under these conditions
+the temperature of the air rarely descends low enough to favour the
+precipitation of dew.
+
+Having noted the process by which in the rain circuit the water
+leaves the sea and the conditions of distribution when it returns to
+the earth, we may now trace in more detail the steps in this great
+round. First, we should take note of the fact that the water after it
+enters the air may come back to the surface of the earth in either of
+two ways--directly in the manner of dewfall, or in a longer circuit
+which leads it through the state of clouds. As yet we are not very
+well informed as to the law of the cloud-making, but certain features
+in this picturesque and most important process have been tolerably
+well ascertained.
+
+Rising upward from the sea, the vapour of water commonly remains
+transparent and invisible until it attains a considerable height above
+the surface, where the cooling tends to make it assume again the
+visible state of cloud particles. The formation of these cloud
+particles is now believed to depend on the fact that the air is full
+of small dust motes, exceedingly small bits of matter derived from the
+many actions which tend to bring comminuted solid matter into the air,
+as, for instance, the combustion of meteoric stones, which are greatly
+heated by friction in their swift course through the air, the
+ejections of volcanoes, the smoke of forest and other fires, etc.
+These tiny bits, floating in the air, because of their solid nature
+radiate their heat, cool the air which lies against them, and thereby
+precipitate the water in the manner of dew, exactly as do the leaves
+and other structures on the surface of the earth. In fact, dew
+formation is essentially like cloud formation, except that in the one
+case the water is gathered on fixed bodies, and in the other on
+floating objects. Each little dust raft with its cargo of condensed
+water tends, of course, to fall downward toward the earth's surface,
+and, except for the winds which may blow upward, does so fall, though
+with exceeding slowness. Its rate of descent may be only a few feet a
+day. It was falling before it took on the load of water; it will fall
+a little more rapidly with the added burden, but even in a still air
+it might be months or years before it would come to the ground. The
+reason for this slow descent may not at first sight be plain, though a
+little consideration will make it so.
+
+If we take a shot of small size and a feather of the same weight, we
+readily note that their rate of falling through the air may vary in
+the proportion of ten to one or more. It is easy to conceive that this
+difference is due to the very much less friction which the smaller
+body encounters in its motion by the particles of air. With this point
+in mind, the student should observe that the surface presented by
+solid bodies in relation to their solid contents is the greater the
+smaller the diameter. A rough, though not very satisfactory, instance
+of this principle may be had by comparing the surface and interior
+contents of two boxes, one ten feet square and the other one foot
+square. The larger has six hundred feet of surface to one thousand
+cubic feet of interior, or about half a square foot of outer surface
+to the cubic foot of contents; while the smaller box has six feet of
+surface for the single cubic foot of interior, or about ten times the
+proportion of exterior to contents. The result is that the smaller
+particles encounter more friction in moving toward the earth, until,
+in the case of finely divided matter, such as the particles of carbon
+in the smoke from an ordinary fire, the rate of down-falling may be so
+small as to have little effect in the turbulent conditions of
+atmospheric motion.
+
+[Illustration: _Pocket Creek, Cape Ann, Massachusetts. Note the
+relatively even size of the pebbles, and the splash wave which sets
+them in motion._]
+
+The little drops of water which gather round dust motes, falling but
+slowly toward the earth, are free to obey the attractions which they
+exercise upon each other--impulses which are partly gravitative and
+partly electrical. We have no precise knowledge concerning these
+movements, further than that they serve to aggregate the myriad little
+floats into cloud forms, in which the rafts are brought near together,
+but do not actually touch each other. They are possibly kept apart by
+electrical repulsion. In this state of association without union the
+divided water may undergo the curiously modified aggregations which
+give us the varied forms of clouds. As yet we know little as to the
+cause of cloud shapes. We remark the fact that in the higher of these
+agglomerations of condensed vapour, the clouds which float at an
+elevation of from twenty to thirty thousand feet or more, the masses
+are generally thin, and arranged more or less in a leaflike form,
+though even here a tendency to produce spherical clouds is apparent.
+In this high realm floating water is probably in the frozen state,
+answering to the form of dew, which we call hoar frost. The lower
+clouds, gathering in the still air, show very plainly the tendency to
+agglomerate into spheres, which appears to be characteristic of all
+vaporous material which is free to move by its own impulses. It is
+probable that the spherical shape of clouds is more or less due to the
+same conditions as gathered the stellar matter from the ancient
+nebular chaos into the celestial spheres. Upon these spherical
+aggregations of the clouds the winds act in extremely varied ways. The
+cloud may be rubbed between opposite currents, and so flattened out
+into a long streamer; it may take the same form by being carried off
+by a current in the manner of smoke from a fire; the spheres may be
+kept together, so as to form the patchwork which we call "mackerel"
+sky; or they may be actually confounded with each other in a vast
+common cloud-heap. In general, where the process of aggregation of two
+cloud bodies occurs, changes of temperature are induced in the masses
+which are mixed together. If the temperature resulting from this
+association of cloud masses is an average increase, the cloud may
+become lighter, and in the manner of a balloon move upward. Each of
+the motes in the cloud with its charge of vapour may be compared with
+the ballast of the balloon; if they are warmed, they send forth a part
+of their load of condensed water again to the state of invisible
+vapour. Rising to a point where it cools, the vapour gathers back on
+the rafts and tends again to weight the cloud downward. The ballast of
+an ordinary balloon has to be thrown away from its car; but if some
+arrangement for condensing the moisture from the air could be
+contrived, a balloon might be brought into the adjustable state of a
+cloud, going up or down according as it was heated or cooled.
+
+When the formation of the drop of water or snowflake begins, the mass
+is very small. If in descending it encounters great thickness of
+cloud, the bit may grow by further condensation until it becomes
+relatively large. Generally in this way we may account for the
+diversities in the size of raindrops or snowflakes. It often happens
+that the particles after taking on the form of snowflakes encounter in
+their descent air so warm that they melt into raindrops, or, if only
+partly melted, reach the surface as sleet. Or, starting as raindrops,
+they may freeze, and in this simple state may reach the earth, or
+after freezing they may gather other frozen water about them, so that
+the hailstone has a complicated structure which, from the point of
+view of classification, is between a raindrop and a snowflake.
+
+In the process of condensation--indeed, in the steps which precede the
+formation of rain and snow--there is often more or less trace of
+electrical action; in fact, a part of the energy which was involved in
+the vapourization of water, on its condensation, even on the dust
+motes appears to be converted into electrical action, which probably
+operates in part to keep the little aggregates of water asunder. When
+they coalesce in drops or flakes, this electricity often assumes the
+form of lightning, which represents the swift passage of the electric
+store from a region where it is most abundant to one where it is less
+so. The variations in this process of conveying the electricity are
+probably great. In general, it probably passes, much as an electric
+current is conveyed, through a wire from the battery which produces
+the force. In other cases, where the tension is high, or, in other
+words, where the discharge has to be hastened, we have the phenomena
+of lightning in which the current burns its way along its path, as it
+may traverse a slender wire, vapourizing it as it goes. In general,
+the lightning flash expends its force on the air conductors, or lines
+of the moist atmosphere along which it breaks its path, its energy
+returning into the vapour which it forms or the heat which it produces
+in the other parts of the air. In some cases, probably not one in the
+thousand of the flashes, the charge is so heavy that it is not used up
+in its descent toward the earth, and so electrifies, or, as we say,
+strikes, some object attached to the earth, through which it passes to
+the underlying moisture, where it finds a convenient place to take on
+a quiet form. Almost all these hurried movements of electrical energy
+which intensely heat and light the air which they traverse fly from
+one part of a cloud to another, or cross from cloud sphere to cloud
+sphere; of those which start toward the earth, many are exhausted
+before they reach its surface, and even those that strike convey but a
+portion of their original impulse to the ground.
+
+The wearing-out effect of lightning in its journey along the air
+conductors in its flaming passages is well illustrated by what happens
+when the charge strikes a wire which is not large enough freely to
+convey it. The wire is heated, generally made white hot, often melted,
+and perhaps scattered in the form of vapour. In doing this work the
+electricity may, and often is, utterly dissipated--that is, changed
+into heat. It has been proposed to take advantage of this principle in
+protecting buildings from lightning by placing in them many thin
+wires, along which the current will try to make its way, being
+exhausted in melting or vaporizing the metal through which it passes.
+
+There are certain other forms of lightning, or at least of electrical
+discharges, which produce light and which may best be described in
+this connection. It occasionally happens that the earth becomes so
+charged that the current proceeds from its surface to the clouds. More
+rarely, and under conditions which we do not understand, the electric
+energy is gathered into a ball-like form, which may move slowly along
+the surface until it suddenly explodes. It is a common feature of all
+these forms of lightning which we have noted that they ordinarily make
+in their movement considerable noise. This is due to the sudden
+displacement of the air which they traverse--displacement due to the
+action of heat in separating the particles. It is in all essential
+regards similar to the sounds made by projectiles, such as meteors or
+swift cannon shots, as they fly through the air. It is even more
+comparable to the sound produced by exploding gunpowder. The first
+sound effect from the lightning stroke is a single rending note, which
+endures no longer--indeed, not as long--as the explosion of a cannon.
+Heard near by, this note is very sharp, reminding one of the sound
+made by the breaking of glass. The rolling, continuous sound which we
+commonly hear in thunder is, as in the case of the noise produced by
+cannon, due to echo from the clouds and the earth. Thunder is
+ordinarily much more prolonged and impressive in a mountainous country
+than in a region of plains, because the steeps about the hearer
+reverberate the original single crash.
+
+The distribution of thunderstorms is as yet not well understood, but
+it appears in many cases that they are attendants on the advancing
+face of cyclones and hurricanes, the area in front of these great
+whirlstorms being subjected to the condensation and irregular air
+movements which lead to the development of much electrical energy.
+There are, however, certain parts of the earth which are particularly
+subjected to lightning flashes. They are common in the region near the
+equator, where the ascending currents bring about heavy rains, which
+mean a rapid condensation and consequent liberation of electrical
+energy. They diminish in frequency toward the arctic regions. An
+observer at the pole would probably fail ever to perceive strong
+flashes. For the same reason thunderstorms are more frequent in
+summer, the time when the difference in temperature between the
+surface and the upper air is greatest, when, therefore, the uprushes
+of air are likely to be most violent. They appear to be more common in
+the night than in the daytime, for the reason that condensation is
+favoured by the cooling which occurs in the dark half of the day. It
+is rare, indeed, that a thunderstorm occurs near midday, a period when
+the air is in most cases taking up moisture on account of the swiftly
+increasing heat.
+
+There are other forms of electrical discharges not distinctly
+connected with the then existing condensation of moisture. What the
+sailors call St. Elmo's fire--a brush of electric light from the mast
+tops and other projections of the ship--indicates the passage of
+electrical energy between the vessel and the atmosphere. Similar
+lights are said sometimes to be seen rising from the surface of the
+water. Such phenomena are at present not satisfactorily explained.
+Perhaps in the same group of actions comes the so-called
+"Jack-o'-lantern" or "Will-o'-the-wisp" fires flashing from the earth
+in marshy places, which are often described by the common people, but
+have never been observed by a naturalist. If this class of
+illuminations really exists, we have to afford them some other
+explanation than that they are emanations of self-inflamed
+phosphoretted hydrogen, a method of accounting for them which
+illogically finds a place in many treatises on atmospheric phenomena.
+A gas of any kind would disperse itself in the air; it could not dance
+about as these lights are said to do, and there is no chemical means
+known whereby it could be produced in sufficient purity and quantity
+from the earth to produce the effects which are described.[3]
+
+[Footnote 3: The present writer has made an extended and careful study
+of marsh and swamp phenomena, and is very familiar with the aspect of
+these fields in the nighttime. He has never been able to see any sign of
+the Jack-o'-lantern light. Looking fixedly into any darkness, such as is
+afforded by the depths of a wood, the eye is apt to imagine the
+appearance of faint lights. Those who have had to do with outpost duty
+in an army know how the anxious sentry, particularly if he is new to the
+soldier's trade, will often imagine that he sees lights before him.
+Sometimes the pickets will be so convinced of the fact that they see
+lights that they will fire upon the fiction of the imaginations. These
+facts make it seem probable that the Jack-o'-lantern and his companion,
+the Will-o'-the-wisp, are stories of the overcredulous.]
+
+In the upper air, or perhaps even beyond the limits of the field
+which deserves the name, in the regions extending from the poles to
+near the tropics, there occur electric glowings commonly known as the
+aurora borealis. This phenomenon occurs in both hemispheres. These
+illuminations, though in some way akin to those of lightning, and
+though doubtless due to some form of electrical action, are peculiar
+in that they are often attended by glows as if from clouds, and by
+pulsations which indicate movements not at electric speed. As yet but
+little is known as to the precise nature of these curious storms. It
+has been claimed, however, that they are related to the sun spots;
+those periods when the solar spots are plenty, at intervals of about
+eleven years, are the times of auroral discharges. Still further, it
+seems probable that the magnetic currents of the earth, that circling
+energy which encompasses the sphere, moving round in a general way
+parallel to the equator, are intensified during these illuminations of
+the circumpolar skies.
+
+
+                    GEOLOGICAL WORK OF WATER.
+
+We turn now to the geological work which is performed by falling
+water. Where the rain or snow returns from the clouds to the sea, the
+energy of position given to the water by its elevation above the earth
+through the heat which it acquired from the sun is returned to the air
+through which it falls or to the ocean surface on which it strikes. In
+this case the circuit of the rain is short and without geological
+consequence which it is worth while to consider, except to note that
+the heat thus returned is likely to be delivered in another realm than
+that in which the falling water acquired the store, thus in a small
+way modifying the climate. When, however, the precipitation occurs on
+the surface of the land, the drops of frozen or fluid water apply a
+part of their energy in important geological work, the like of which
+is not done where they return at once to the sea.
+
+[Illustration: Fig. 10.--Showing the diverse action of rain on wooded
+and cleared fields, _a_, wooded area; _b_, tilled ground.]
+
+We shall first consider what takes place when the water in the form of
+drops of rain comes to the surface of the land. Descending as they do
+with a considerable speed, these raindrops apply a certain amount of
+energy to the surface on which they fall. Although the beat of a
+raindrop is proverbially light, the stroke is not ineffective.
+Observing what happens where the action takes place on the surface of
+bare rock, we may notice that the grains of sand or small pebbles
+which generally abound on such surfaces, if they be not too steeply
+inclined, dance about under the blows which they receive. If we could
+cover hard plate glass, a much firmer material than ordinary stone,
+with such bits, we should soon find that its surface would become
+scratched all over by the friction. Moreover, the raindrops
+perceptibly urge the small detached bits of stone down the slopes
+toward the streams.
+
+If all the earth's surface were bare rocks, the blow of the raindrops
+would deserve to be reckoned among the important influences which lead
+to the wearing of land. As it is, when a country is in a state of
+Nature, only a small part of its surface is exposed to this kind of
+wearing. Where there is rain enough to effect any damage, there is
+sure to be sufficient vegetation to interpose a living and
+self-renewed covering between the rocks and the rain. Even the lichens
+which coat what at first sight often seems to be bare rock afford an
+ample covering for this purpose. It is only where man bares the field
+by stripping away and overturning this protecting vegetation that the
+raindrops cut away the earth. The effect of their action can often be
+noted by observing how on ploughed ground a flat stone or a potsherd
+comes after a rain to cap a little column. The geologist sometimes
+finds in soft sandstones that the same action is repeated in a larger
+way where a thin fragment of hard rock has protected a column many
+feet in height against the rain work which has shorn down the
+surrounding rock.
+
+When water strikes the moistened surface it at once loses the droplike
+form which all fluids assume when they fall through the air.[4]
+
+[Footnote 4: This principle of the spheroidal form in falling fluids is
+used in making ordinary bird shot. The melted lead drops through
+sievelike openings, the resulting spheres of the metal being allowed to
+fall into water which chills them. Iron shot, used in cutting stone,
+where they are placed between the saw and the surface of the rock, are
+also made in the same manner. The descending fluid divides into drops
+because it is drawn out by the ever-increasing speed of the falling
+particles, which soon make the stream so thin that it can not hold
+together.]
+
+When the raindrops coalesce on the surface of the earth, the rôle of
+what we may call land water begins. Thenceforward until the fluid
+arrives at the surface of the sea it is continually at work in
+effecting a great range of geological changes, only a few of which can
+well be traced by the general student. The work of land water is due
+to three classes of properties--to the energy with which it is endowed
+by virtue of its height above the sea, a power due to the heat of the
+sun; to the capacity it has for taking substances into solution; and
+to its property of giving some part of its own substance to other
+materials with which it comes in contact. The first of these groups of
+properties may be called dynamical; the others, chemical.
+
+The dynamic value of water when it falls upon the land is the amount
+of energy it can apply in going down the slope which separates it from
+the sea. A ton of the fluid, such as may gather in an ordinary rain on
+a thousand square feet of ground in the highlands of a country--say at
+an elevation of a thousand feet above the sea--expends before it comes
+to rest in the great reservoir as much energy as would be required to
+lift that weight from the ocean's surface to the same height. The ways
+in which this energy may be expended we shall now proceed in a general
+way to trace.
+
+As soon as the water has been gathered, from its drop to its sheet
+state--a process which takes place as soon as it falls--the fluid
+begins its downward journey. On this way it is at once parted into two
+distinct divisions, the surface water and the ground water: the former
+courses more or less swiftly, generally at the rate of a mile or more
+an hour, in the light of day; the latter enters the interstices of the
+earth, slowly descends therein to a greater or less depth, and
+finally, journeying perhaps at the rate of a mile a year, rejoins the
+surface water, escaping through the springs. The proportion of these
+two classes, the surface and the ground water, varies greatly, and an
+intermixture of them is continually going on. Thus on the surface of
+bare rock or frozen earth all the rain may go away without entering
+the ground. On very sandy fields the heaviest rainfall may be taken
+up by the porous earth, so that no streams are found. On such surfaces
+the present writer has observed that a rainfall amounting to six
+inches in depth in two hours produced no streams whatever. We shall
+first follow the history of the surface water, afterward considering
+the work which the underground movements effect.
+
+If the student will observe what takes place on a level ploughed
+field--which, after all, will not be perfectly level, for all fields
+are more or less undulating--he will note that, though the surface may
+have been smoothed by a roller until it appears like a floor, the
+first rain, where the fall takes place rapidly enough to produce
+surface streams, will create a series of little channels which grow
+larger as they conjoin, the whole appearing to the eye like a very
+detailed map, or rather model, of a river system; it is, indeed, such
+a system in miniature. If he will watch the process by which these
+streamlet beds are carved, he will obtain a tolerably clear idea as to
+that most important work which the greater streams do in carving the
+face of the lands. The water is no sooner gathered into a sheet than,
+guided by the slightest irregularities which it encounters, it begins
+to flow. At first the motion is so slow that it does not disturb its
+bed, but at some points in the bottom of the sheet the movement soon
+becomes swift enough to drag the grains of sand and clay from their
+adhesions, bearing them onward. As soon as this beginning of a channel
+is formed the water moves more swiftly in the clearer way; it
+therefore cuts more rapidly, deepening and enlarging its channel, and
+making its motion yet more free. The tiny rills join the greater, all
+their channels sway to and fro as directed this way and that by chance
+irregularities, until something like river basins are carved out,
+those gentle slopes which form broad valleys where the carving has
+been due to the wanderings of many streams. If the field be large,
+considerable though temporary brooks may be created, which cut
+channels perhaps a foot in depth. At the end of this miniature stream
+system we always find some part of the waste which has been carved
+out. If the streamlet discharges into a pool, we find the tiny
+representative of deltas, which form such an important feature on the
+coast line where large rivers enter seas or lakes. Along the lines of
+the stream we may observe here and there little benches, which are the
+equivalent in all save size of the terraces that are generally to be
+observed along the greater streams. In fact, these accidents of an
+acre help in a most effective way the student to understand the
+greater and more complicated processes of continental erosion.
+
+A normal river--in fact, all the greater streams of the
+earth--originates in high country, generally in a region of mountains.
+Here, because of the elevation of the region, the streams have cut
+deep gorges or extensive valleys, all of which have slopes leading
+steeply downward to torrent beds. Down these inclined surfaces the
+particles worn off from the hard rock by frost and by chemical decay
+gradually work their way until they attain the bed of the stream. The
+agents which assist gravitation in bearing this detritus downward are
+many, but they all work together for the same end. The stroke of the
+raindrop accomplishes something, though but little; the direct washing
+action of the brooklets which form during times of heavy rain, but dry
+out at the close of the storm, do a good deal of the work; thawing and
+freezing of the water contained in the mass of detritus help the
+movement, for, although the thrust is in both directions, it is most
+effective downhill; the wedges of tree roots, which often penetrate
+between and under the stones, and there expand in their process of
+growth, likewise assist the downward motion. The result is that on
+ordinary mountain slopes the layer of fragments constituting the rude
+soil is often creeping at the rate of from some inches to some feet a
+year toward the torrent bed. If there be cliffs at the top of the
+slope, as is often the case, very extensive falls of rock may take
+place from it, the masses descending with such speed that they
+directly attain the stream. If the steeps be low and the rock divided
+into vertical joints, especially where there is a soft layer at the
+base of the steep, detached masses from the precipice may move slowly
+and steadfastly down the slope, so little disturbed in their journey
+that trees growing upon their summits may continue to develop for the
+thousands of years before the mass enters the stream bed.
+
+Although the fall of rocks from precipices does not often take place
+in a conspicuously large way, all great mountain regions which have
+long been inhabited by man abound in traditions and histories of such
+accidents. Within a century or two there have been a dozen or more
+catastrophes of this nature in the inhabited valleys of the Alps. As
+these accidents are at once instructive and picturesque, it is well to
+note certain of them in some detail. At Yvorgne, a little parish on
+the north shore of the Rhône, just above the lake of Geneva, tradition
+tells that an ancient village of the name was overwhelmed by the fall
+of a great cliff. The vast _débris_ forming the steep slope which was
+thus produced now bears famous vineyards, but the vintners fancy that
+they from time to time hear deep in the earth the ringing of the bells
+which belonged to the overwhelmed church. In 1806 the district of
+Goldau, just north of Lake Lucerne, was buried beneath the ruins of a
+peak which, resting upon a layer of clay, slipped away like a
+launching ship on the surface of the soft material. The _débris_
+overwhelmed a village and many detached houses, and partly filled a
+considerable lake. The wind produced by this vast rush of falling rock
+was so great that people were blown away by it; some, indeed, were
+killed in this singular manner.
+
+The most interesting field of these Swiss mountain falls is a high
+mountain valley of amphitheatrical form, known as the Diablerets, or
+the devil's own district. This great circus, which lies at the height
+of about four thousand feet above the sea, is walled around on its
+northern side by a precipice, above which rest, or rather once
+rested, a number of mountain peaks of great bulk. The region has long
+been valued for the excellent pasturage which the head of the valley
+affords. Two costly roads, indeed, have been built into it to afford
+footpaths for the flocks and herds and their keepers in the summer
+season. Through this human experience with the valley, we have a
+record of what has gone on in this part of the mountain wilderness.
+Within the period of history and tradition, three very great mountain
+falls have occurred in this field, each having made its memory good by
+widespread disaster which it brought to the people of the _chalets_.
+The last of these was brought about by the fall of a great peak which
+spread itself out in a vast field of ruins in the valley below. The
+belt of destruction was about half a mile wide and three miles long.
+When the present writer last saw it, a quarter of a century ago, it
+was still a wilderness of great rocks, but here and there the process
+of their decay was giving a foothold for herbage, and in a few
+centuries the field will doubtless be so verdure-clad that its story
+will not be told on its face. It is likely, however, to be preserved
+in the memory of the people, and this through a singular and pathetic
+tradition which has grown up about the place, one which, if not true,
+comes at least among the legends which we should like to believe.
+
+As told the present writer by a native of the district, it happened
+when, in the nighttime the mountain came down, the herdsmen and their
+cows gathered in the _chalets_--stout buildings which are prepared to
+resist avalanches of snow. In one of these, which was protected from
+crushing by the position of the stones which covered it, a solitary
+herdsman found himself alive in his unharmed dwelling. With him in the
+darkness were the cows, a store of food and water, and his provisions
+for the long summer season. With nothing but hope to animate him, he
+set to work burrowing upward among the rocks, storing the _débris_ in
+the room of the _chalet_. He toiled for some months, but finally
+emerged to the light of day, blanched by his long imprisonment in the
+darkness, but with the strength to bear him to his home. In place of
+the expected warm welcome, the unhappy man found himself received as a
+ghost. He was exorcised by the priest and driven away to the distance.
+It was only when long afterward his path of escape was discovered that
+his history became known.
+
+Returning to the account of the _débris_ which descends at varied
+speed into the torrents, we find that when the detritus encounters the
+action of these vigorous streams it is rapidly ground to pieces while
+it is pushed down the steep channels to the lower country. Where the
+stones are of such size that the stream can urge them on, they move
+rapidly; at least in times when the torrent is raging. They beat over
+each other and against the firm-set rocks; the more they wear, the
+smaller they become, and the more readily they are urged forward.
+Where the masses are too large to be stirred by the violent current,
+they lie unmoved until the pounding of the rolling stones reduces them
+to the proportions where they may join the great procession.
+Ordinarily those who visit mountains behold their torrents only in
+their shrunken state, when the waters stir no stones, and fail even to
+bear a charge of mud, all detachable materials having been swept away
+when the streams course with more vigour. In storm seasons the
+conditions are quite otherwise; then the swollen torrents, their
+waters filled with clay and sand, bear with them great quantities of
+boulders, the collisions of which are audible above the muffled roar
+of the waters, attesting the very great energy of the action.
+
+When the waste on a mountain slope lies at a steep angle, particularly
+where the accumulation is due to the action of ancient glaciers, it
+not infrequently happens that when the ground is softened with frost
+great masses of the material rush down the slope in the manner of
+landslides. The observer readily notes that in many mountain regions,
+as, for instance, in the White Mountains of New Hampshire, the steep
+slopes are often seamed by the paths of these great landslides. Their
+movement, indeed, is often begun by sliding snow, which gives an
+impulse to the rocks and earth which it encounters in its descent. At
+a place known as the Wylie Notch, in the White Mountains, in the early
+part of this century, a family of that name was buried beneath a mass
+of glacial waste which had hung on the mountain slope from the ancient
+days until a heavy rain, following on a period of thaw, impelled the
+mass down the slope. Although there have been few such catastrophes
+noted in this country, it is because our mountains have not been much
+dwelt in. As they become thickly inhabited as the Alps are, men are
+sure to suffer from these accidents.
+
+As the volume of a mountain torrent increases through the junction of
+many tributaries, the energy of its moving waters becomes sufficient
+to sweep away the fragments which come to its bed. Before this stage
+is attained the stream rarely touches the solid under rock of the
+mountain, the base of the current resting upon the larger loose stones
+which it was unable to stir. In this pebble-paved section, because the
+stream could not attack the foundation rock, we find no gorges--in
+fact, the whole of this upper section of the torrent system is
+peculiarly conditioned by the fact that the streams are dealing not
+with bed-rock, but with boulders or smaller loose fragments. If they
+cut a little channel, the materials from either side slip the faster,
+and soon repave the bed. But when the streams have by a junction
+gained strength, and can keep their beds clear, they soon carve down a
+gorge through which they descend from the upper mountain realm to the
+larger valleys, where their conjoined waters take on a riverlike
+aspect. It should be noted here that the cutting power of the water
+moving in the torrent or in the wave, the capacity it has for abrading
+rock, resides altogether in the bits of stone or cutting tools with
+which it is armed. Pure water, because of its fluidity, may move over
+or against firm-set stones for ages without wearing them; but in
+proportion as it moves rocky particles of any size, the larger they
+are, the more effective the work, it wears the rock over which it
+flows. A capital instance of this may be found where a stream from a
+hose is used in washing windows. If the water be pure, there is no
+effect upon the glass; but if it be turbid, containing bits of sand,
+in a little while the surface will appear cloudy from the multitude of
+line scratches which the hard bits impelled by the water have
+inflicted upon it. A somewhat similar case occurs where the wind bears
+sand against window panes or a bottle which has long lain on the
+shore. The glass will soon be deeply carved by the action, assuming
+the appearance which we term "ground." This principle is made use of
+in the arts. Glass vessels or sheets are prepared for carving by
+pasting paper cut into figures on their surfaces. The material is then
+exposed to a jet of air or steam-impelling sand grains; in a short
+time all the surface which has not been protected by paper has its
+polish destroyed and is no longer translucent.
+
+The passage from the torrent to the river, though not in a
+geographical way distinct, is indicated to the observant eye by a
+simple feature--namely, the appearance of alluvial terraces, those
+more or less level heaps of water-borne _débris_ which accumulate
+along the banks of rivers, which, indeed, constitute the difference
+between those streams and torrents. Where the mountain waters move
+swiftly, they manage to bear onward the waste which they receive. Even
+where the blocks of stone cling in the bed, it is only a short time
+before they are again set in motion or ground to pieces. If by chance
+the detritus accumulates rapidly, the slope is steepened and the work
+of the torrent made more efficient. As the torrent comes toward the
+base of the mountains, where it neither finds nor can create steep
+slopes over which to flow, its speed necessarily diminishes. With each
+reduction in this feature its carrying power very rapidly diminishes.
+Thus water flowing at the rate of ten miles an hour can urge stones
+four times the mass that it can move when its speed is reduced to half
+that rate. The result is that on the lowlands, with their relatively
+gentle slopes, the combined torrents, despite the increase in the
+volume of the stream arising from their confluence, have to lay down a
+large part of their load of detritus.
+
+If we watch where a torrent enters a mountain river, we observe that
+the main stream in a way sorts over the waste contributed to it,
+bearing on only those portions which its rate of flow will permit it
+to carry, leaving the remainder to be built into the bank in the form
+of a rude terrace. This accumulation may not extend far below the
+point where the torrent which imported the _débris_ joins the main
+stream; a little farther down, however, we are sure to find another
+such junction and a second accumulation of terrace material. As these
+contributions increase, the terrace accumulations soon become
+continuous, lying on one side or the other of the river, sometimes
+bordering both banks of the stream. In general, it can be said that so
+long as the rate of fall of the torrent exceeds one hundred feet to
+the mile it does not usually exhibit these shelves of detritus. Below
+that rate of descent they are apt to be formed. Much, however, depends
+upon the amount of detritus which the stream bears and the coarseness
+of it; moreover, where the water goes through a gorge in the manner of
+a flume with steep rocky sides, it can urge a larger amount before it
+than when it traverses a wide valley, through which it passes, it may
+be, in a winding way.
+
+At first sight it may seem rather a fine distinction to separate
+torrents from rivers by the presence or absence of terraces. As we
+follow down the stream, however, and study its action in relation to
+these terraces, and the peculiar history of the detritus of which they
+are composed, we perceive that these latter accumulations are very
+important features. Beginning at first with small and imperfect
+alluvial plains, the river, as it descends toward the sea, gaining in
+store of water and in the amount of _débris_ which comes with that
+water from the hills, while the rate of fall and consequent speed of
+the current are diminished, soon comes to a stage where it is engaged
+in an endless struggle with the terrace materials. In times of flood,
+the walls of the terraces compel the tide to flow over the tops of
+these accumulations. Owing to the relative thinness of the water
+beyond the bed, and to the growth of vegetation there, the current
+moves more slowly, and therefore lays down a considerable deposit of
+the silt and sand which it contains. This may result during a single
+flood in lifting the level of the terrace by some inches in height,
+still further serving to restrict the channel. Along the banks of the
+Mississippi and other large rivers the most of this detritus falls
+near the stream; a little of it penetrates to the farther side of the
+plains, which often have a width of ten miles or more. The result is
+that a broad elevation is constructed, a sort of natural mole or
+levee, in a measure damming the flood waters, which can now only enter
+the "back swamps" through the channels of the tributary streams. Each
+of these back swamps normally discharges into the main stream through
+a little river of its own, along the banks of which the natural levees
+do not develop.
+
+We have now to note a curious swinging movement of rivers which was
+first well observed by the skilful engineers of British India. This
+movement can best be illustrated by its effects. If on any river which
+winds through alluvial plains a jetty is so constructed as to deflect
+the stream at any point, the course which it follows will be altered
+during its subsequent flow, it may be, for the distance of hundreds of
+miles. It will be perceived that in its movements a river normally
+strikes first against one shore and then against the other. Its water
+in a general way moves as does a billiard ball when it flies from one
+cushion to another. It is true that in a torrent we have the same
+conditions of motion; but there the banks are either of hard rock or,
+if of detritus, they are continually moving into the stream in the
+manner before described. In the case of the river, however, its points
+of collision are often on soft banks, which are readily undermined by
+the washing action of the stream. In the ordinary course of events,
+the river beginning, we may imagine, with a straight channel, had its
+current deflected by some obstacle, it may be even by the slight
+pressure of a tributary stream, is driven against one bank; thence it
+rebounds and strikes the other. At each point of impinge it cuts the
+alluvium away. It can bear on only a small portion of that which it
+thus obtains; the greater part of the material is deposited on the
+opposite side of the stream, but a little lower down, where it makes a
+shallow. On these shallows water-loving plants and even certain trees,
+such as the willows and poplars, find a foothold. When the stream
+rises, the sediment settles in this tangle, and soon extends the
+alluvial plain from the neighbouring bank, or in rarer cases the river
+comes to flow on either side of an island of its own construction. The
+natural result of this billiard-ball movement of the waters is that
+the path of the stream is sinuous. The less its rate of fall and the
+greater the amount of silt it obtains from its tributaries, the more
+winding its course becomes. This gain in those parts of the river's
+curvings where deposition tends to take place may be accelerated by
+tree-planting. Thus a skilful owner of a tract of land on the south
+bank of the Ohio River, by assiduously planting willow trees on the
+front of his property, gained in the course of thirty years more than
+an acre in the width of his arable land. When told by the present
+writer that he was robbing his neighbours on the other side of the
+stream, he claimed that their ignorance of the laws of river motion
+was sufficient evidence that they did not deserve to own land.
+
+In the primitive state of a country the water-loving plants,
+particularly the trees which flourish in excessively humid conditions,
+generally make a certain defence against these incursions of the
+streams. But when a river has gained an opening in the bank it can,
+during a flood, extend its width often to the distance of hundreds of
+feet. During the inundations of the Mississippi the river may at times
+be seen to eat away acres of land in a single day along one of the
+outcurves of its banks. The undermined forests falling into the flood
+join the great procession of drift timber, composed of trees which
+have been similarly uprooted, which occupies the middle part of the
+stream. This driftwood belt often has a width of three or four hundred
+feet, the entangled stems and branches making it difficult for a boat
+to pass from one side of the river to the other.
+
+[Illustration: Fig. 11.--Oxbows and cut-off. Showing the changes in
+the course of a river in its alluvial plain.]
+
+When the curves of a river have been developed to a certain point (see
+Fig. 11), when they have attained what is called the "oxbow" form, it
+often happens that the stream breaks through the isthmus which
+connects one of the peninsulas with the mainland. Where, as is not
+infrequently the case, the bend has a length of ten miles or more, the
+water just above and below the new-made opening is apt to differ in
+height by some feet. Plunging down the declivity, the stream, flowing
+with great velocity, soon enlarges the channel so that its whole tide
+may take the easier way. When this result is accomplished, the old
+curve is deserted, sand bars are formed across their mouths, which may
+gradually grow to broad alluvial plains, so that the long-surviving,
+crescent-shaped lake, the remnant of the river bed, may be seen far
+from the present course of the ever-changing stream. Gradually the
+accumulations of vegetable matter and the silt brought in by floods
+efface this moat or oxbow cut-off, as it is so commonly termed.
+
+As soon as the river breaks through the neck of a peninsula in the
+manner above described, the current of the stream becomes much swifter
+for many miles below and above the opening. Slowly, however, the
+slopes are rearranged throughout its whole course, yet for a time the
+stream near the seat of the change becomes straighter than before, and
+this for the reason that its swifter current is better able to dispose
+of the _débris_ which is supplied to it. The effect of a change in the
+current produced by such new channels as we have described as forming
+across the isthmuses of bends is to perturb the course of the stream
+in all its subsequent downward length. Thus an oxbow cut-off formed
+near the junction of the Ohio and Mississippi may tend more or less to
+alter the swings of the Mississippi all the way to the Gulf of Mexico.
+
+Although the swayings of the streams to and fro in their alluvial
+plains will give the reader some idea as to the struggle which the
+greater rivers have with the _débris_ which is committed to them, the
+full measure of the work and its consequences can only be appreciated
+by those who have studied the phenomena on the ground. A river such
+as the Mississippi is endlessly endeavouring to bear its burden to the
+sea. If its slope were a uniform inclined plane, the task might
+readily be accomplished; but in this, as in almost all other large
+water ways, the slope of the bed is ever diminishing with its onward
+course. The same water which in the mountain torrent of the
+Appalachians or Cordilleras rolled along stones several feet in
+diameter down slopes of a hundred feet or more to the mile can in the
+lower reaches of the stream move no pebbles which are more than one
+fourth of an inch in diameter over slopes which descend on the average
+about half a foot in a mile. Thus at every stage from the torrent to
+the sea the detritus has from time to time to rest within the alluvial
+banks, there awaiting the decay which slowly comes, and which may
+bring it to the state where it may be dissolved in the water, or
+divided into fragments so small that the stream may bear them on. A
+computation which the present writer has made shows that, on the
+average, it requires about forty thousand years for a particle of
+stone to make its way down the Mississippi to the sea after it has
+been detached from its original bed. Of course, some bits may make the
+journey straightforwardly; others may require a far greater time to
+accomplish the course which the water itself makes at most in a few
+weeks. This long delay in the journey of the detritus--a delay caused
+by its frequent rests in the alluvial plain--brings about important
+consequences which we will now consider.
+
+As an alluvial plain is constructed, we generally find at the base
+pebbly material which fell to the bottom in the current of the main
+stream as the shores grew outward. Above this level we find the
+deposits laid down by the flood waters containing no pebbles, and this
+for the reason that those weightier bits remained in the stream bed
+when the tide flowed over the plain. As the alluvial deposit is laid
+down, a good deal of vegetable matter was built into it. Generally
+this has decayed and disappeared. On the surface of the plain there
+has always been growing abundant vegetation, the remains of which
+decayed on the surface in the manner which we may observe at the
+present day. This decomposing vegetable matter within and upon the
+porous alluvial material produces large quantities of carbonic acid, a
+gas which readily enters the rain water, and gives it a peculiar power
+of breaking up rock matter. Acting on the _débris_, this gas-charged
+water rapidly brings about a decay of the fragments. Much of the
+material passes at once into solution in this water, and drains away
+through the multitudinous springs which border the river. As this
+matter is completely dissolved, as is sugar in water, it goes straight
+away to the sea without ever again entering the alluvium. In many, if
+not most, cases this dissolving work which is going on in alluvial
+terraces is sufficient to render a large part of the materials which
+they contain into the state where it disappears in an unseen manner;
+thus while the annual floods are constantly laying down accumulations
+on the surface of these plains, the springs are bearing it away from
+below.
+
+In this way, through the decomposition which takes place in them, all
+those river terraces where much vegetable matter is mingled with the
+mineral substances, become laboratories in which substances are
+brought into solution and committed to the seas. We find in the water
+of the ocean a great array of dissolved mineral substances; it,
+indeed, seems probable that the sea water contains some share, though
+usually small, of all the materials which rivers encounter in their
+journey over and under the lands. As the waters of the sea obtain but
+little of this dissolved matter along the coast, it seems likely that
+the greater share of it is brought into the state of solution in the
+natural laboratories of the alluvial plains.
+
+Here and there along the sides of the valleys in which the rivers flow
+we commonly find the remains of ancient plains lying at more or less
+considerable heights above the level of the streams. Generally these
+deposits, which from their form are called terraces, represent the
+stages of down-wearing by which the stream has carved out its way
+through the rocks. The greater part of these ancient alluvial plains
+has been removed through the ceaseless swinging of the stream to and
+fro in the valley which it has excavated.
+
+In all the states of alluvial plains, whether they be the fertile
+deposits near the level of the streams which built them, or the poorer
+and ruder surfaced higher terraces, they have a great value to
+mankind. Men early learned that these lands were of singularly uniform
+goodness for agricultural use. They are so light that they were easily
+delved with the ancient pointed sticks or stone hoes, or turned by the
+olden, wooden plough. They not only give a rich return when first
+subjugated, but, owing to the depth of the soil and the frequency with
+which they are visited by fertilizing inundations, they yield rich
+harvests without fertilizing for thousands of years. It is therefore
+not surprising that we find the peoples who depended upon tillage for
+subsistence first developed on the great river plains. There, indeed,
+were laid the foundations of our higher civilization; there alone
+could the state which demands of its citizens fixed abodes and
+continuous labour take rise. In the conditions which these fields of
+abundance afforded, dense populations were possible, and all the arts
+which lead toward culture were greatly favoured. Thus it is that the
+civilization of China, India, Persia, and Egypt, the beginnings of
+man's higher development, began near the mouths of the great river
+valleys. These fields were, moreover, most favourably placed for the
+institution of commerce, in that the arts of navigation, originating
+in the sheltered reaches of the streams, readily found its way through
+the estuaries to the open sea.
+
+Passing down the reaches of a great river as it approaches the sea, we
+find that the alluvial plains usually widen and become lower. At
+length we attain a point where the flood waters cover the surface for
+so large a part of the year that the ground is swampy and untillable
+unless it is artificially and at great expense of labour won to
+agriculture in the manner in which this task has been effected in the
+lower portion of the Rhine Valley. Still farther toward the sea, the
+plain gradually dips downward until it passes below the level of the
+waters. Through this mud-flat section the stream continues to cut
+channels, but with the ever-progressive slowing of its motion the
+burden of fine mud which it carries drops to the bottom, and
+constantly closes the paths through which the water escapes. Every few
+years they tend to break a new way on one side or the other of their
+former path. Some of the greatest engineering work done in modern
+times has been accomplished by the engineers engaged in controlling
+the exits of large rivers to the sea. The outbreak of the Yellow River
+in 1887, in which the stream, hindered by its own accumulations,
+forced a new path across its alluvial plains, destroyed a vast deal of
+life and property, and made the new exit seventy miles from the path
+which it abandoned.
+
+Below the surface of the open water the alluvial deposits spread out
+into a broad fan, which slopes gradually to a point where, in the
+manner of the continental shelf, the bottom descends steeply into deep
+water.
+
+It is the custom of naturalists to divide the lower section of river
+deposits--that part of the accumulation which is near the sea--from
+the other alluvial plains, terming the lower portion the delta. The
+word originally came into use to describe that part of the alluvium
+accumulated by the Nile near its mouth, which forms a fertile
+territory shaped somewhat like the fourth letter of the Greek
+alphabet. Although the definition is good in the Egyptian instance,
+and has a certain use elsewhere, we best regard all the detritus in a
+river valley which is in the state of repose along the stream to its
+utmost branches as forming one great whole. It is, indeed, one of the
+most united of the large features which the earth exhibits. The
+student should consider it as a continuous inclined plane of
+diminishing slope, extending from the base of the torrents to the
+sea, and of course ramifying into the several branches of the river
+system. He should further bear in mind the fact that it is a vast
+laboratory where rock material is brought into the soluble state for
+delivery to the seas.
+
+The diversity in the form of river valleys is exceedingly great.
+Almost all the variety of the landscape is due to this impress of
+water action which has operated on the surface in past ages. When
+first elevated above the sea, the surface of the land is but little
+varied; at this stage in the development the rivers have but shallow
+valleys, which generally cut rather straight away over the plain
+toward the sea. It is when the surface has been uplifted to a
+considerable height, and especially when, as is usually the case, this
+uplifting action has been associated with mountain-building, that
+valleys take on their accented and picturesque form. The reason for
+this is easily perceived: it lies in the fact that the rocks over
+which the stream flows are guided in the cutting which they effect by
+the diversities of hardness in the strata that they encounter. The
+work which it does is performed by the hard substances that are
+impelled by the current, principally by the sand and pebbles. These
+materials, driven along by the stream, become eroding tools of very
+considerable energy. As will be seen when we shortly come to describe
+waterfalls, the potholes formed at those points afford excellent
+evidence as to the capacity of stream-impelled bits of stone to cut
+away the firmest bed rocks. Naturally the ease with which this carving
+work is done is proportionate to the energy of the currents, and also
+to the relative hardness of the moving bits and the rocks over which
+they are driven.
+
+So long as the rocks lie horizontally in their natural construction
+attitude the course of the stream is not much influenced by the
+variations in hardness which the bed exhibits. Where the strata are
+very firm there is likely to be a narrow gorge, the steeps of which
+rise on either side with but slight alluvial plains; where the beds
+are soft the valley widens, perhaps again to contract where in the
+course of its descent it encounters another hard layer. Where,
+however, the beds have been subjected to mountain-building, and have
+been thrown into very varied attitudes by folding and faulting, the
+stream now here and now there encounters beds which either restrain
+its flow or give it freedom. The stream is then forced to cut its way
+according to the positions of the various underlying strata. This
+effect upon its course is not only due to the peculiarities of
+uplifted rocks, but to manifold accidents of other nature: veins and
+dikes, which often interlace the beds with harder or softer partitions
+than the country rock; local hardenings in the materials, due to
+crystallization and other chemical processes, often create
+indescribable variations which are more or less completely expressed
+in the path of the stream.
+
+When a land has been newly elevated above the sea there is often--we
+may say, indeed, generally--a very great difference between the height
+of its head waters and the ocean level. In this condition of a country
+the rivers have what we may call a new aspect; their valleys are
+commonly narrow and rather steep, waterfalls are apt to abound, and
+the alluvial terraces are relatively small in extent. Stage by stage
+the torrents cut deeper; the waste which they make embarrasses the
+course of the lower waters, where no great amount of down-cutting is
+possible for the reason that the bed of the stream is near sea level.
+At the same time the alluvial materials, building out to sea, thus
+diminish the slope of the stream. In the extreme old age of the river
+system the mountains are eaten down so that the torrent section
+disappears, and the stream becomes of something like a uniform slope;
+the higher alluvial plains gradually waste away, until in the end the
+valley has no salient features. At this stage in the process, or even
+before it is attained, the valley is likely to be submerged beneath
+the sea, where it is buried beneath the deposits formed on the floor;
+or a further uplift of the land may occur with the result that the
+stream is rejuvenated; or once more endowed with the power to create
+torrents, build alluvial plains, and do the other interesting work of
+a normal river.
+
+It rarely, if ever, happens that a river valley attains old age before
+it has sunk beneath the sea or been refreshed by further upliftings.
+In the unstable conditions of the continents, one or the other of
+these processes, sometimes in different places both together, is apt
+to be going on. Thus if we take the case of the Mississippi and its
+principal tributaries, the Ohio and Missouri, we find that for many
+geological ages the mountains about their sources have frequently, if
+not constantly, grown upward, so that their torrent sections, though
+they have worn down tens of thousands of feet, are still high above
+the sea level, perhaps on the average as high as they have ever been.
+At the same time the slight up-and-down swayings of the shore lands,
+amounting in general to less than five hundred feet, have greatly
+affected the channels of the main river and its tributaries in their
+lower parts. Not long ago the Mississippi between Cairo and the Gulf
+flowed in a rather steep-sided valley probably some hundreds of feet
+in depth, which had a width of many miles. Then at the close of the
+last Glacial period the region sank down so that the sea flooded the
+valley to a point above the present junction of the Ohio River with
+the main stream. Since then alluvial plains have filled this estuary
+to even beyond the original mouth. In many other of our Southern
+rivers, as along the shore from the Mississippi to the Hudson, the
+streams have not brought in enough detritus to fill their drowned
+valleys, which have now the name of bays, of which the Delaware and
+Chesapeake on the Atlantic coast, and Mobile Bay on the Gulf of
+Mexico, are good examples. The failure of Chesapeake and Delaware Bays
+to fill with _débris_ in the measure exhibited by the more southern
+valleys is due to the fact that the streams which flow into them to a
+great extent drain from a region thickly covered with glacial waste, a
+mass which holds the flood waters, yielding the supply but slowly to
+the torrents, which there have but a slight cutting power.
+
+In our sketch of river valleys no attention has been given to the
+phenomena of waterfalls, those accidents of the flow which, as we have
+noted, are particularly apt to characterize rivers which have not yet
+cut down to near the sea level. Where the normal uniform descent which
+is characteristic of a river's bed is interrupted by a sudden steep,
+the fact always indicates the occurrence of one of a number of
+geological actions. The commonest cause of waterfalls is due to a
+sudden change in the character of horizontal or at least nearly level
+beds over which the stream may flow. Where after coursing for a
+distance over a hard layer the stream comes to its edge and drops on a
+soft or easily eroded stratum, it will cut this latter bed away, and
+create a more or less characteristic waterfall. Tumbling down the face
+of the hard layer, the stream acquires velocity; the _débris_ which it
+conveys is hurled against the bottom, and therefore cuts powerfully,
+while before, being only rubbed over the stone as it moved along, it
+cut but slightly. Masses of ice have the same effect as stones. Bits
+dropping from the ledge are often swept round and round by the eddies,
+so that they excavate an opening which prevents their chance escape.
+In these confined spaces they work like augers, boring a deep,
+well-like cavity. As the bits of stone wear out they are replaced by
+others, which fall in from above. Working in this way, the fragments
+often develop regular well-like depressions, the cavities of which
+work back under the cliffs, and by the undermining process deprive the
+face of the wall of its support, so that it tumbles in ruin to the
+base, there to supply more material for the potholing action.
+
+Waterfalls of the type above described are by far the commonest of
+those which occur out of the torrent districts of a great river
+system. That of Niagara is an excellent specimen of the type, which,
+though rarely manifested in anything like the dignity of the great
+fall, is plentifully shown throughout the Mississippi Valley and the
+basin of the Great Lakes. Within a hundred miles of Niagara there are
+at least a hundred small waterfalls of the same type. Probably three
+quarters of all the larger accidents of this nature are due to the
+conditions of a hard bed overlying softer strata.
+
+Falls are also produced in very many instances by dikes which cross
+the stream. So, too, though rarely, only one striking instance being
+known, an ancient coral reef which has become buried in strata may
+afford rock of such hardness that when the river comes to cross it it
+forms a cascade, as at the Falls of the Ohio, at Louisville, Ky. It is
+a characteristic of all other falls, except those first mentioned,
+that they rarely plunge with a clean downward leap over the face of a
+precipice which recedes at its base, but move downward over an
+irregular sloping surface.
+
+In the torrent district of rivers waterfalls are commonly very
+numerous, and are generally due to the varying hardness in the rocks
+which the streams encounter. Here, where the cutting action is going
+on with great rapidity, slight differences in the resistance which the
+rocks make to the work will lead to great variations in the form of
+the bed over which they flow, while on the more gently sloping bottoms
+of the rivers, where the _débris_ moves slowly, such variations would
+be unimportant in their effect. When the torrents escape into the main
+river valleys, in regions where the great streams have cut deep
+gorges, they often descend from a great vertical height, forming
+wonderful waterfalls, such as those which occur in the famous
+Lauterbrunnen Valley of Switzerland or in that of the Yosemite in
+California. This group of cascades is peculiar in that the steep of
+the fall is made not by the stream itself, but by the action of a
+greater river or of a glacier which may have some time taken its
+place.
+
+Waterfalls have an economic as well as a picturesque interest in that
+they afford sources of power which may be a very great advantage to
+manufacturers. Thus along the Atlantic coast the streams which come
+from the Appalachian highlands, and which have hardly escaped from
+their torrent section before they attain the sea, afford numerous
+cataracts which have been developed so that they afford a vast amount
+of power. Between the James on the south and the Ste. Croix on the
+north more than a hundred of these Appalachian rivers have been turned
+to economic use. The industrial arts of this part of the country
+depend much upon them for the power which drives their machinery. The
+whole of the United States, because of the considerable size of its
+rivers and their relatively rapid fall, is richly endowed with this
+source of energy, which, originating in the sun's heat and conveyed
+through the rain, may be made to serve the needs of man. In view of
+the fact that recent inventions have made it possible to convert this
+energy of falling water into the form of electricity, which may be
+conveyed to great distances, it seems likely that our rivers will in
+the future be a great source of national wealth.
+
+We must turn again to river valleys, there to trace certain actions
+less evident than those already noted, but of great importance in
+determining these features of the land. First, we have to note that in
+the valley or region drained by a river there is another degrading or
+down-wearing action than that which is accomplished by the direct work
+of the visible stream. All over such a valley the underground waters,
+soaking through the soil and penetrating through the underlying rock,
+are constantly removing a portion of the mineral matter which they
+take into solution and bear away to the sea. In this way, deprived of
+a part of their substance, the rocks are continually settling down by
+underwear throughout the whole basin, while they are locally being cut
+down by the action of the stream. Hence in part it comes about that in
+a river basin we find two contrasted features--the general and often
+slight slope of a country toward the main stream and its greater
+tributaries, and the sharp indentation of the gorge in which the
+streams flow, these latter caused by the immediate and recent action
+of the streams.
+
+If now the reader will conceive himself standing at any point in a
+river basin, preferably beyond the realms of the torrents, he may with
+the guidance of the facts previously noted, with a little use of the
+imagination, behold the vast perceptive which the history of the river
+valley may unfold to him. He stands on the surface of the soil, that
+_débris_ of the rocks which is just entering on its way to the ocean.
+In the same region ten thousand years ago he would have stood upon a
+surface from one to ten feet higher than the present soil covering. A
+million years ago his station would have been perhaps five hundred
+feet higher than the surface. Ten million years in the past, a period
+less than the lifetime of certain rivers, such as the French Broad
+River in North Carolina, the soil was probably five thousand feet or
+more above its present plane. There are, indeed, cases where river
+valleys appear to have worked down without interruption from the
+subsidence of the land beneath the sea to the depth of at least two
+miles. Looking upward through the space which the rocks once occupied,
+we can conceive the action of the forces in their harmonious
+co-operation which have brought the surface slowly downward. We can
+imagine the ceaseless corrosion due to the ground water, bringing
+about a constant though slow descent of the whole surface. Again and
+again the streams, swinging to and fro under the guidance of the
+underlying rock, or from the obstacles which the _débris_ they carried
+imposed upon them, have crossed the surface. Now and then perhaps the
+wearing was intensified by glacial action, for an ice sheet often cuts
+with a speed many times as great as that which fluid water can
+accomplish. On the whole, this exercise of the constructive
+imagination in conceiving the history of a river valley is one of the
+most enlarging tasks which the geologist can undertake.
+
+Where in a river valley there are many lateral streams, and especially
+where the process of solution carried on by the underground waters is
+most effective, as compared with erosive work done in the bed of the
+main river, we commonly find the valley sloping gently toward its
+centre, the rivers having but slight steeps near their banks. On the
+other hand, where, as occasionally happens, a considerable stream fed
+by the rain and snow fall in its torrent section courses for a great
+distance over high, arid plains, on which the ground water and the
+tributaries do but little work, the basin may slope with very slight
+declivity to the river margins, and there descend to great depths,
+forming very deep gorges, of which the Colorado Cañon is the most
+perfect type. As instances of these contrasted conditions, we may
+take, on the one hand, the upper Mississippi, where the grades toward
+the main stream are gentle and the valley gorge but slightly
+exhibited; on the other, the above-mentioned Colorado, which bears a
+great tide of waters drawn from the high and relatively rainy region
+of the Rocky Mountains across the vast plateau lying in an almost
+rainless country. In this section nearly all the down-wearing has been
+brought about in the direct path of the stream, which has worn the
+elevated plain into a deep gorge during the slow uprising of the
+table-land to its present height. In this way a defile nearly a mile
+in depth has been created in a prevailingly rather flat country. This
+gorge has embranchments where the few great tributaries have done like
+work, but, on the whole, this river flows in an almost unbroken
+channel, the excavation of which has been due to its swift,
+pebble-bearing waters.
+
+The tendency of a newly formed river is to cut a more or less distinct
+cañon. As the basin becomes ancient, this element of the gorge tends
+to disappear, the reason for this being that, while the river bed is
+high above the sea, the current is swift and the down-cutting rapid,
+while the slow subsidence of the country on either side--a process
+which goes on at a uniform rate--causes the surface of that region to
+be left behind in the race for the sea level. As the stream bed comes
+nearer the sea level its rate of descent is diminished, and so the
+outlying country gradually overtakes it.
+
+In regions where the winters are very cold the effect of ice on the
+development of the stream beds both in the torrent and river sections
+of the valley is important. This work is accomplished in several
+diverse ways. In the first place, where the stream is clear and the
+current does not flow too swiftly, the stones on the bottom radiate
+their heat through the water, and thus form ice on their surfaces,
+which may attain considerable thickness. As ice is considerably
+lighter than water, the effect is often to lift up the stones of the
+bed if they be not too large; when thus detached from the bottom, they
+are easily floated down stream until the ice melts away. The ice which
+forms on the surface of the water likewise imprisons the pebbles along
+the banks, and during the subsequent thaw may carry them hundreds of
+miles toward the sea. It seems likely, from certain observations made
+by the writer, that considerable stones may thus be carried from the
+Alleghany River to the main Mississippi.
+
+Perhaps the most important effect of ice on river channels is
+accomplished when in a time of flood the ice field which covered the
+stream, perhaps to the depth of some feet, is broken up into vast
+floes, which drift downward with the current. When, as on the Ohio,
+these fields sometimes have the area of several hundred acres, they
+often collide with the shores, especially where the stream makes a
+sharp bend. Urged by their momentum, these ice floes pack into the
+semblance of a dam, which may have a thickness of twenty, thirty, or
+even fifty feet. Beginning on the shore, where the collision takes
+place, the dam may swiftly develop clear across the stream, so that in
+a few minutes the way of the waters is completely blocked. The
+on-coming ice shoots up upon the accumulation, increases its height,
+and extends it up stream, so that in an hour the mass completely bars
+the current. The waters then heap up until they break their way over
+the obstacle, washing its top away, until the whole is light enough
+to be forced down the stream, where, by the friction it encounters on
+the bottom and sides of the channel, it is broken to pieces. It is
+easy to see that such moving dams of ice may sweep the bed of a river
+as with a great broom.
+
+Sometimes where the gorges do not form a stationary dam large cakes of
+ice become turned on edge and pack together so that they roll down the
+stream like great wheels, grinding the bed rock as they go.
+
+In high northern countries, as in Siberia, the rivers, even the
+deepest, often become so far frozen that their channels are entirely
+obstructed. Where, as in the case of these Siberian rivers, the flow
+is from south to north, it often happens that the spring thaw sets in
+before the more northern beds of the main stream are released from
+their bondage of frost. In this case the inundations have to find new
+paths on either side of the obstructed way. The result is a type of
+valleys characterized by very irregular and changeable stream beds,
+the rivers having no chance to organize themselves into the shapely
+curves which they ordinarily follow.
+
+The supply which finds its way to a river is composed, as has been
+already incidentally noted, in part of the water which courses
+underground for a greater or less distance before it emerges to the
+surface, and in part of that which moves directly over the ground.
+These two shares of water have somewhat different histories. On the
+share of these two depends the stability of the flow. Where, as in New
+England and other glaciated countries, the surface of the earth is
+covered with a thick layer of sand and gravel, which, except when
+frozen, readily admits the water; the rainfall is to a very great
+extent absorbed by the earth, and only yielded slowly to the streams.
+In these cases floods are rare and of no great destructive power.
+Again, where also the river basin is covered by a dense mantle of
+forests, the ground beneath which is coated, as is the case in
+primeval woods, with a layer of decomposing vegetation a foot or more
+in depth, this spongy mass retains the water even more effectively
+than the open-textured glacial deposits above referred to. When the
+woods, however, are removed from such an area, the rain may descend to
+the streams almost as speedily as it finds its way to the gutters from
+the house roofs. It thus comes about that all regions, when reduced to
+tillage, and where the rainfall is enough to maintain a good
+agriculture, are, except when they have a coating of glacial waste,
+exceedingly liable to destructive inundations.
+
+Unhappily, the risk of river floods is peculiarly great in all the
+regions of the United States lying much to the east of the Rocky
+Mountains, except in the basin of the Great Lakes and in the district
+of New England, where the prevalence of glacial sands and gravels
+affords the protection which we have noted. Throughout this region the
+rainfall is heavy, and the larger part of it is apt to come after the
+ground has become deeply snow-covered. The result is a succession of
+devastating floods which already are very damaging to the works of
+man, and promise to become more destructive as time goes on. More than
+in any other country, we need the protection which forests can give us
+against these disastrous outgoings of our streams.
+
+
+                            LAKES.
+
+In considering the journey of water from the hilltops to the sea, we
+should take some account of those pauses which it makes on its way
+when for a time it falls into the basin of a lake. These arrests in
+the downward motion of water, which we term lakes, are exceedingly
+numerous; their proper discussion would, indeed, require a
+considerable volume. We shall here note only the more important of
+their features, those which are of interest to the general student.
+
+The first and most noteworthy difference in lakes is that which
+separates the group of dead seas from the living basins of fresh
+water. When a stream attains a place where its waters have to expand
+into the lakelike form, the current moves in a slow manner, and the
+broad surface exposed to the air permits a large amount of
+evaporation. If the basin be large in proportion to the amount of the
+incurrent water, this evaporation may exceed the supply, and produce a
+sea with no outlet, such as we find in the Dead Sea of Judea, in that
+at Salt Lake, Utah, and in a host of other less important basins. If
+the rate of evaporation be yet greater in proportion to the flow, the
+lake may altogether dry away, and the river be evaporated before it
+attains the basin where it might accumulate. In that case the river is
+said to sink, but, in place of sinking into the earth, its waters
+really rise into the air. Many such sinks occur in the central portion
+of the Rocky Mountain district. It is important to note that the
+process of evaporation we are describing takes place in the case of
+all lakes, though only here and there is the air so dry that the
+evaporation prevents the basin from overflowing at the lowest point on
+its rim, forming a river which goes thence to the sea. Even in the
+case of the Great Lakes of North America a considerable part of the
+water which flows into them does not go to the St. Lawrence and thence
+to the sea. As long as the lake finds an outlet to the sea its waters
+contain but little more dissolved mineral matter than that we find in
+the rivers. But because all water which has been in contact with the
+earth has some dissolved mineral substances, while that which goes
+away by evaporation is pure water, a lake without an outlet gradually
+becomes so charged with these materials that it can hold no more in
+solution, but proceeds to lay them down in deposits of that compound
+substance which from its principal ingredient we name salt. The water
+of dead seas, because of the additional weight of the substances which
+it holds, is extraordinarily buoyant. The swimmer notes a difference
+in this regard in the waters of rivers and fresh-water lakes and those
+of the sea, due to this same cause. But in those of dead seas,
+saturated with saline materials, the human body can not sink as it
+does in the ordinary conditions of immersion. It is easy to understand
+how the salt deposits which are mined in many parts of the world have
+generally, if not in all cases, been formed in such dead seas.[5]
+
+[Footnote 5: In some relatively rare cases salt deposits are formed in
+lagoons along the shores of arid lands, where the sea occasionally
+breaks over the beach into the basin, affording waters which are
+evaporated, leaving their salt behind them.]
+
+It is an interesting fact that almost all the known dead seas have in
+recent geological times been living lakes--that is, they poured over
+their brims. In the Cordilleras from the line between Canada and the
+United States to central Mexico there are several of these basins. All
+of those which have been studied show by their old shore lines that
+they were once brimful, and have only shrunk away in modern times.
+These conditions point to the conclusion that the rainfall in
+different regions varies greatly in the course of the geologic ages.
+Further confirmation of this is found in the fact that very great salt
+deposits exist on the coast of Louisiana and in northern
+Europe--regions in which the rainfall is now so great in proportion to
+the evaporation that dead seas are impossible.
+
+Turning now to the question of how lake basins are formed, we note a
+great variety in the conditions which may bring about their
+construction. The greatest agent, or at least that which operates in
+the construction of the largest basins, are the irregular movements of
+the earth, due to the mountain-building forces. Where this work goes
+on on a large scale, basin-shaped depressions are inevitably formed.
+If all those which have existed remained, the large part of the lands
+would be covered by them. In most cases, however, the cutting action
+of the streams has been sufficient to bring the drainage channels down
+to the bottom of the trough, while the influx of sediments has served
+to further the work by filling up the cavities. Thus at the close of
+the Cretaceous period there was a chain of lakes extending along the
+eastern base of the Rocky Mountains, constituting fresh-water seas
+probably as large as the so-called Great Lakes of North America. But
+the rivers, by cutting down and tilling up, have long since
+obliterated these water areas. In other cases the tiltings of the
+continent, which sometimes oppose the flow of the streams, may for a
+time convert the upper part of a river basin which originally sloped
+gently toward the sea into a cavity. Several cases of this description
+occurred in New England in the closing stages of the Glacial period,
+when the ground rose up to the northward.
+
+We have already noted the fact that the basin of a dead sea becomes in
+course of time the seat of extensive salt deposits. These may, indeed,
+attain a thickness of many hundred feet. If now in the later history
+of the country the tract of land with the salt beneath it were
+traversed by a stream, its underground waters may dissolve out the
+salt and in a way restore the basin to its original unfilled
+condition, though in the second state that of a living lake. It seems
+very probable that a portion at least of the areas of Lakes Ontario,
+Erie, and Huron may be due to this removal of ancient salt deposits,
+remains of which lie buried in the earth in the region bordering these
+basins.
+
+By far the commonest cause of lake basins is found in the
+irregularities of the surface which are produced by the occupation of
+the country by glaciers. When these great sheets of ice lie over a
+land, they are in motion down the slopes on which they rest; they wear
+the bed rocks in a vigorous manner, cutting them down in proportion to
+their hardness. As these rocks generally vary in the resistance which
+they oppose to the ice, the result is that when the glacier passes
+away the surface no longer exhibits the continued down slope which the
+rivers develop, but is warped in a very complicated way. These
+depressions afford natural basins in which lakes gather; they may vary
+in extent from a few square feet to many square miles. When a glacier
+occupies a country, the melting ice deposits on the surface of the
+earth a vast quantity of rocky _débris_, which was contained in its
+mass. This detritus is irregularly accumulated; in part it is disposed
+in the form of moraines or rude mounds made at the margin of the
+glacier, in part as an irregular sheet, now thick, now thin, which
+covers the whole of the field over which the ice lay. The result of
+this action is the formation of innumerable pools, which continue to
+exist until the streams have cut channels through which their waters
+may drain away, or the basins have become filled with detritus
+imported from the surrounding country or by peat accumulations which
+the plants form in such places.
+
+Doubtless more than nine tenths of all the lake basins, especially
+those of small size, which exist in the world are due to
+irregularities of the land surface which are brought about by glacial
+action. Although the greater part of these small basins have been
+obliterated since the ice left this country, the number still
+remaining of sufficient size to be marked on a good map is
+inconceivably great. In North America alone there are probably over a
+hundred and fifty thousand of these glacial lakes, although by far the
+greater part of those which existed when the glacial sheet disappeared
+have been obliterated.
+
+Yet another interesting group of fresh-water lakes, or rather we
+should call them lakelets from their small size, owes its origin to
+the curious underground excavations or caverns which are formed in
+limestone countries. The water enters these caverns through what are
+termed "sink holes"--basins in the surface which slope gently toward a
+central opening through which the water flows into the depths below.
+The cups of the sink holes rarely exceed half a mile in diameter, and
+are usually much smaller. Their basins have been excavated by the
+solvent and cutting actions of the rain water which gathers in them to
+be discharged into the cavern below. It often happens that after a
+sink hole is formed some slight accident closes the downward-leading
+shaft, so that the basin holds water; thus in parts of the United
+States there are thousands of these nearly circular pools, which in
+certain districts, as in southern Kentucky, serve to vary the
+landscape in much the same manner as the glacial lakes of more
+northern countries.
+
+Some of the most beautiful lakes in the world, though none more than a
+few miles in diameter, occupy the craters of extinct volcanoes. When
+for a time, or permanently, a volcano ceases to do its appointed work
+of pouring forth steam and molten rock from the depths of the earth,
+the pit in the centre of the cone gathers the rain water, forming a
+deep circular lake, which is walled round by the precipitous faces of
+the crater. If the volcano reawakens, the water which blocks its
+passage may be blown out in a moment, the discharge spreading in some
+cases to a great distance from the cone, to be accumulated again when
+the vent ceases to be open. The most beautiful of these volcanic lakes
+are to be found in the region to the north and south of Rome. The
+original seat of the Latin state was on the shores of one of these
+crater pools, south of the Eternal City. Lago Bolsena, which lies to
+the northward, and is one of the largest known basins of this nature,
+having a diameter of about eight miles, is a crater lake. The volcanic
+cone to which it belongs, though low, is of great size, showing that
+in its time of activity, which did not endure very long, this crater
+was the seat of mighty ejections. The noblest specimen of this group
+of basins is found in Crater Lake, Oregon, now contained in one of the
+national parks of the United States.
+
+Inclosed bodies of water are formed in other ways than those
+described; the list above given includes all the important classes of
+action which produce these interesting features. We should now note
+the fact that, unlike the seas, the lakes are to be regarded as
+temporary features in the physiography of the land. One and all, they
+endure for but brief geologic time, for the reason that the streams
+work to destroy them by filling them with sediment and by carving out
+channels through which their waters drain away. The nature of this
+action can well be conceived by considering what will take place in
+the course of time in the Great Lakes of North America. As Niagara
+Falls cut back at the average rate of several feet a year, it will be
+but a brief geologic period before they begin to lower the waters of
+Lake Erie. It is very probable, indeed, that in twenty thousand years
+the waters of that basin will be to a great extent drained away. When
+this occurs, another fall or rapid will be produced in the channel
+which leads from Lake Huron to Lake Erie. This in turn will go through
+its process of retreat until the former expanse of waters disappears.
+The action will then be continued at the outlets of Lakes Michigan and
+Superior, and in time, but for the interposition of some actions which
+recreate these basins, their floors will be converted into dry land.
+
+It is interesting to note that lakes owe in a manner the preservation
+of their basins to an action which they bring about on the waters that
+flow into them. These rivers or torrents commonly convey great
+quantities of sediment, which serve to rasp their beds and thus to
+lower their channels. In all but the smaller lakelets these turbid
+waters lay down all their sediment before they attain the outlet of
+the basin. Thus they flow away over the rim rock in a perfectly pure
+state--a state in which, as we have noted before, water has no
+capacity for abrading firm rock. Thus where the Niagara River passes
+from Lake Erie its clean water hardly affects the stone over which it
+flows. It only begins to do cutting work where it plunges down the
+precipice of the Falls and sets in motion the fragments which are
+constantly falling from that rocky face. These Falls could not have
+begun as they did on the margin of Lake Ontario except for the fact
+that when the Niagara River began to flow, as in relatively modern
+times, it found an old precipice on the margin of Lake Ontario, formed
+by the waves of the lake, down which the waters fell, and where they
+obtained cutting tools with which to undermine the steep which forms
+the Falls.
+
+Many great lakes, particularly those which we have just been
+considering, have repeatedly changed their outlets, according as the
+surface of the land on which they lie has swayed up and down in
+various directions, or as glacial sheets have barred or unbarred the
+original outlets of the basins. Thus in the Laurentian Lakes above
+Ontario the geologist finds evidence that the drainage lines have
+again and again been changed. For a time during the Glacial period,
+when Lake Ontario and the valley of the St. Lawrence was possessed by
+the ice, the discharge was southward into the upper Mississippi or the
+Ohio. At a later stage channels were formed leading from Georgian Bay
+to the eastern part of Ontario. Yet later, when the last-named lake
+was bared, an ice dam appears to have remained in the St. Lawrence,
+which held back the waters to such a height that they discharged
+through the valley of the Mohawk into the Hudson. Furthermore, at some
+time before the Glacial period, we do not know just when, there
+appears to have been an old Niagara River, now filled with drift,
+which ran from Lake Erie to Ontario, a different channel from that
+occupied by the present stream.
+
+The effects of lakes on the river systems with which they are
+connected is in many ways most important. Where they are of
+considerable extent, or where even small they are very numerous, they
+serve to retain the flood waters, delivering them slowly to the
+excurrent streams. In rising one foot a lake may store away more water
+than the river by its consequent rise at the point of outflow will
+carry away in many months, and this for the simple reason that the
+lake may be many hundred or even thousand times as wide as the stream.
+Moreover, as before noted, the sediment gathered by the stream above
+the level of the lake is deposited in its basin, and does not affect
+the lower reaches of the river. The result is that great rivers, such
+as drain from the Laurentian Lakes, flow clear water, are exempt from
+floods, are essentially without alluvial plains or terraces, and form
+no delta deposits. In all these features the St. Lawrence River
+affords a wonderful contrast to the Mississippi. Moreover, owing to
+the clear waters, though it has flowed for a long time, it has never
+been able to cut away the slight obstructions which form its rapids,
+barriers which probably would have been removed if its waters had been
+charged with sediment.
+
+[Illustration: _Muir Glacier, Alaska, showing crevasses and dust
+layer on surface of ice._]
+
+
+
+
+                         CHAPTER VI.
+
+                          GLACIERS.
+
+
+We have already noted the fact that the water in the clouds is very
+commonly in the frozen state; a large part of that fluid which is
+evaporated from the sea attains the solid form before it returns to
+the earth. Nevertheless, in descending, at least nine tenths of the
+precipitation returns to the fluid state, and does the kind of work
+which we have noted in our account of water. Where, however, the water
+arrives on the earth in the frozen condition, it enters on a rôle
+totally different from that followed by the fluid material.
+
+Beginning its descent to the earth in a snowflake, the little mass
+falls slowly, so that when it comes against the earth the blow which
+it strikes is so slight that it does no effective work. In the state
+of snow, even in the separate flakes, the frozen water contains a
+relatively large amount of air. It is this air indeed, which, by
+dividing the ice into many flakes that reflect the light, gives it the
+white colour. This important point can be demonstrated by breaking
+transparent ice into small bits, when we perceive that it has the hue
+of snow. Much the same effect is given where glass is powdered, and
+for the same reason.
+
+As the snowflakes accumulate layer on layer they imbed air between
+them, so that when the material falls in a feathery shape--say to the
+depth of a foot--more than nine tenths of the mass is taken up by the
+air-containing spaces. As these cells are very small, the circulation
+in them is slight, and so the layer becomes an admirable
+non-conductor, having this quality for the same reason that feathers
+have it--i.e., because the cells are small enough to prevent the
+circulation of the air, so that the heat which passes has to go by
+conduction, and all gases are very poor conductors. The result is that
+a snow coating is in effect an admirable blanket. When the sun shines
+upon it, much of the heat is reflected, and as the temperature does
+not penetrate it to any depth, only the superficial part is melted.
+This molten water takes up in the process of melting a great deal of
+heat, so that when it trickles down into the mass it readily
+refreezes. On the other hand, the heat going out from the earth, the
+store accumulated in its superficial parts in the last warm season,
+together with the small share which flows out from the earth's
+interior, is held in by this blanket, which it melts but slowly. Thus
+it comes about that in regions of long-enduring snowfall the ground,
+though frozen to the depth of a foot or more at the time when the
+accumulation took place, may be thawed out and so far warmed that the
+vegetation begins to grow before the protecting envelope of snow has
+melted away. Certain of the early flowers of high latitudes, indeed,
+begin to blossom beneath the mantle of finely divided ice.
+
+In those parts of the earth which for the most part receive only a
+temporary coating of snow the effect of this covering is
+inconsiderable. The snow water is yielded to the earth, from which it
+has helped to withdraw the frost, so that in the springtime, the
+growing season of plants, the ground contains an ample store of
+moisture for their development. Where the snowfall accumulates to a
+great thickness, especially where it lodges in forests, the influence
+of the icy covering is somewhat to protract the winter and thus to
+abbreviate the growing season.
+
+Where snow rests upon a steep slope, and gathers to the depth of
+several feet, it begins to creep slowly down the declivity in a manner
+which we may often note on house roofs. This motion is favoured by the
+gradual though incomplete melting of the flakes as the heat
+penetrates the mass. Making a section through a mass of snow which has
+accumulated in many successive falls, we note that the top may still
+have the flaky character, but that as we go down the flakes are
+replaced by adherent shotlike bodies, which have arisen from the
+partial melting and gathering to their centres of the original
+expanded crystalline bits. In this process of change the mass can move
+particle by particle in the direction in which gravity impels it. The
+energy of its motion, however, is slight, yet it can urge loose stones
+and forest waste down hill. Sometimes, as in the cemetery at Augusta,
+Me., where stone monuments or other structures, such as iron railings,
+are entangled in the moving mass, it may break them off and convey
+them a little distance down the slope.
+
+So long as the summer sun melts the winter's snow, even if the ground
+be bare but for a day, the rôle of action accomplished by the snowfall
+is of little geological consequence. When it happens that a portion of
+the deposit holds through the summer, the region enters on the glacial
+state, and its conditions undergo a great revolution, the consequences
+of which are so momentous that we shall have to trace them in some
+detail. Fortunately, the considerations which are necessary are not
+recondite, and all the facts are of an extremely picturesque nature.
+
+Taking such a region as New England, where all the earth is
+life-bearing in the summer season, and where the glacial period of the
+winter continues but for a short time, we find that here and there on
+the high mountains the snow endures throughout most of the summer, but
+that all parts of the surface have a season when life springs into
+activity. On the top of Mount Washington, in the White Mountains of
+New Hampshire, in a cleft known as Tuckerman's Ravine, where the
+deposit accumulates to a great depth, the snow-ice remains until
+midsummer. It is, indeed, evident that a very slight change in the
+climatal conditions of this locality would establish a permanent
+accumulation of frozen water upon the summit of the mountain. If the
+crest were lifted a thousand feet higher, without any general change
+in the heat or rainfall of the district, this effect would be
+produced. If with the same amount of rainfall as now comes to the
+earth in that region more of it fell as snow, a like condition would
+be established. Furthermore, with an increase of rainfall to something
+like double that which now descends the snow bore the same proportion
+to the precipitation which it does at present, we should almost
+certainly have the peak above the permanent snow line, that level
+below which all the winter's fall melts away. These propositions are
+stated with some care, for the reason that the student should perceive
+how delicate may be--indeed, commonly is--the balance of forces which
+make the difference between a seasonal and a perennial snow covering.
+
+As soon as the snow outlasts the summer, the region which it occupies
+is sterilized to life. From the time the snow begins to hold over the
+warm period until it finally disappears, that field has to be reckoned
+out of the habitable earth, not only to man, but to the lowliest
+organisms.[6]
+
+[Footnote 6: In certain fields of permanent snow, particularly near their
+boundaries, some very lowly forms of vegetable life may develop on a
+frozen surface, drawing their sustenance from the air, and supplied with
+water by the melting which takes place during the summertime. These
+forms include the rare phenomenon termed red snow.]
+
+If the snow in a glaciated region lay where it fell, the result would
+be a constant elevation of the deposit year by year in proportion to
+the annual excess of deposition over the melting or evaporation of the
+material. But no sooner does the deposit attain any considerable
+thickness than it begins to move in the directions of least
+resistance, in accordance with laws which the students of glaciers are
+just beginning to discern. In small part this motion is accomplished
+by avalanches or snow slides, phenomena which are in a way important,
+and therefore merit description. Immediately after a heavy snowfall,
+in regions where the slopes are steep, it often happens that the
+deposit which at first clung to the surface on which it lay becomes so
+heavy that it tends to slide down the slope; a trifling action, the
+slipping, indeed, of a single flake, may begin the movement, which at
+first is gradual and only involves a little of the snow. Gathering
+velocity, and with the materials heaped together from the junction of
+that already in motion with that about to be moved, the avalanche in
+sliding a few hundred feet down the slope may become a deep stream of
+snow-ice, moving with great celerity. At this stage it begins to break
+off masses of ice from the glaciers over which it may flow, or even to
+move large stones. Armed with these, it rends the underlying earth.
+After it has flowed a mile it may have taken up so much earth and
+material that it appears like a river of mud. Owing to the fact that
+the energy which bears it downward is through friction converted into
+heat, a partial melting of the mass may take place, which converts it
+into what we call slush, or a mixture of snow and water. Finally, the
+torrent is precipitated into the bottom of a valley, where in time the
+frozen water melts away, leaving only the stony matter which it bore
+as a monument to show the termination of its flow.
+
+It was the good fortune of the writer to see in the Swiss Oberland one
+very great avalanche, which came from the high country through a
+descent of several thousand feet to the surface of the Upper
+Grindelwald Glacier. The first sign of the action was a vague tremor
+of the air, like that of a great organ pipe when it begins to vibrate,
+but before the pulsations come swiftly enough to make an audible note.
+It was impossible to tell when this tremor came, but the wary guide,
+noting it before his charge could perceive anything unusual, made
+haste for the middle of the glacier. The vibration swelled to a roar,
+but the seat of the sound amid the echoing cliffs was indeterminable.
+Finally, from a valley high up on the southern face of the glacier,
+there leaped forth first a great stone, which sprang with successive
+rebounds to the floor of ice. Then in succession other stones and
+masses of ice which had outrun the flood came thicker and thicker,
+until at the end of about thirty seconds the steep front of the
+avalanche appeared like a swift-moving wall. Attaining the cliffs, it
+shot forth as a great cataract, which during the continuance of the
+flow--which lasted for several minutes--heaped a great mound of
+commingled stones and ice upon the surface of the glacier. The mass
+thus brought down the steep was estimated at about three thousand
+cubic yards, of which probably the fiftieth part was rock material. An
+avalanche of this volume is unusual, and the proportion of stony
+matter borne down exceptionally great; but by these sudden motions of
+the frozen water a large part of the snow deposited above the zone of
+complete melting is taken to the lower valleys, where it may disappear
+in the summer season, and much of the erosion accomplished in the
+mountains is brought about by these falls.
+
+In all Alpine regions avalanches are among the most dreaded accidents.
+Their occurrence, however, being dependent upon the shape of the
+surface, it is generally possible to determine in an accurate way the
+liability of their happening in any particular field. The Swiss take
+precaution to protect themselves from their ravages as other folk do
+to procure immunity from floods. Thus the authorities of many of the
+mountain hamlets maintain extensive forests on the sides of the
+villages whence the downfall may be expected, experience having shown
+that there is no other means so well calculated to break the blow
+which these great snowfalls can deliver, as thick-set trees which,
+though they are broken down for some distance, gradually arrest the
+stream.
+
+As long as the region occupied by permanent snow is limited to sharp
+mountain peaks, relief by the precipitation of large masses to the
+level below the snow line is easily accomplished, but manifestly this
+kind of a discharge can only be effective from a very small field.
+Where the relief is not brought about by these tumbles of snow,
+another mode of gravitative action accomplishes the result, though in
+a more roundabout way, through the mechanism of glaciers.
+
+We have already noted the fact that the winter's snow upon our
+hillsides undergoes a movement in the direction of the slope. What we
+have now to describe in a rather long story concerning glaciers rests
+upon movements of the same nature, though they are in certain features
+peculiarly dependent on the continuity of the action from year to
+year. It is desirable, however, that the student should see that there
+is at the foundation no more mystery in glacial motion than there is
+in the gradual descent of the snow after it has lain a week on a
+hillside. It is only in the scale and continuity of the action that
+the greatest glacial envelope exceeds those of our temporary
+winters--in fact, whenever the snow falls the earth it covers enters
+upon an ice period which differs only in degree from that from which
+our hemisphere is just escaping.
+
+Where the reader is so fortunate as to be able to visit a region of
+glaciers, he had best begin his study of their majestic phenomena by
+ascending to those upper realms where the snow accumulates from year
+to year. He will there find the natural irregularities of the rock
+surface in a measure evened over by a vast sheet of snow, from which
+only the summits of the greater mountains rise. He may soon satisfy
+himself that this sheet is of great depth, for here and there it is
+intersected by profound crevices. If the visit is made in the season
+when snow falls, which is commonly during most of the year, he may
+observe, as before noted in our winter's snow, that the deposit,
+though at first flaky, attains at a short distance below the surface a
+somewhat granular character, though the shotlike grains fall apart
+when disturbed. Yet deeper, ordinarily a few feet below the surface,
+these granules are more or less cemented together; the mass thus loses
+the quality of snow, and begins to appear like a whitish ice. Looking
+down one of the crevices, where the light penetrates to the depth of a
+hundred feet or more, he may see that the bluish hue somewhat
+increases with the depth. A trace of this colour is often visible even
+in the surface snow on the glacier, and sometimes also in our ordinary
+winter fields. In a hole made with a stick a foot or more in depth a
+faint cerulean glimmer may generally be discerned; but the increased
+blueness of the ice as we go down is conspicuous, and readily leads us
+to the conclusion that the air, to which, as we before noted, the
+whiteness of the snow is due, is working out of the mass as the
+process of compaction goes on. In a glacial district this snow mass
+above the melting line is called the _névé_.
+
+Remembering that the excess of snow beyond the melting in a _névé_
+district amounts, it may be, to some feet of material each year, we
+easily come to the conclusion that the mass works down the slope in
+the manner which it does even where the coating is impermanent. This
+supposition is easily confirmed: by observing the field we find that
+the sheet is everywhere drawing away from the cliffs, leaving a deep
+fissure between the _névé_ and the precipices. This crevice is called
+by the German-Swiss guides the _Bergschrund_. Passage over it is
+often one of the most difficult feats to accomplish which the Alpine
+explorer has to undertake. In fact, the very appearance of the
+surface, which is that of a river with continuous down slopes, is
+sufficient evidence that the mass is slowly flowing toward the
+valleys. Following it down, we almost always come to a place where it
+passes from the upper valleys to the deeper gorges which pierce the
+skirts of the mountain. In going over this projection the mass of
+snow-ice breaks to pieces, forming a crowd of blocks which march down
+the slope with much more speed than they journeyed when united in the
+higher-lying fields. In this condition and in this part of the
+movement the snow-ice forms what are called the _seracs_, or curds, as
+the word means in the French-Swiss dialect. Slipping and tumbling
+down the steep slope on which the _seracs_ develop, the ice becomes
+broken into bits, often of small size. These fragments are quickly
+reknit into the body of ice, which we shall hereafter term the
+glacier, and in this process the expulsion of the air goes on more
+rapidly than before, and the mass assumes a more transparent icelike
+quality.
+
+The action of the ice in the pressures and strains to which it is
+subjected in joining the main glacier and in the further part of its
+course demand for their understanding a revision of those notions as
+to rigidity and plasticity which we derive from our common experience
+with objects. It is hard to believe that ice can be moulded by
+pressure into any shape without fracturing, provided the motion is
+slowly effected, while at the same time it is as brittle as ice to a
+sudden blow. We see, however, a similar instance of contrasted
+properties in the confection known as molasses candy, a stick of which
+may be indefinitely bent if the flexure is slowly made, but will fly
+to pieces like glass if sharply struck. Ice differs from the sugary
+substance in many ways; especially we should note that while it may be
+squeezed into any form, it can not be drawn out, but fractures on the
+application of a very slight tension. The conditions of its movement
+we will inquire into further on, when we have seen more of its action.
+
+Entering on the lower part of its course, that where it flows into the
+region below the snow line, the ice stream is now confined between the
+walls of the valley, a channel which in most cases has been shaped
+before the ice time, by a mountain torrent, or perhaps by a slower
+flowing river. In this part of its course the likeness of a glacial
+stream to one of fluid water is manifest. We see that it twists with
+the turn of the gorge, widens where the confining walls are far apart,
+and narrows where the space is constricted. Although the surface is
+here and there broken by fractures, it is evident that the movement of
+the frozen current, though slow, is tolerably free. By placing stakes
+in a row across the axis of a glacier, and observing their movement
+from day to day, or even from hour to hour if a good theodolite is
+used for the purpose, we note that the movement of the stream is
+fastest in the middle parts, as in the case of a river, and that it
+slows toward either shore, though it often happens, as in a stream of
+molten water, that the speediest part of the current is near one side.
+Further observations have indicated that the movement is most rapid on
+the surface and least at the bottom, in which the stream is also
+riverlike. It is evident, in a word, that though the ice is not fluid
+in strict sense, the bits of which it is made up move in substantially
+the manner of fluids--that is, they freely slip over each other. We
+will now turn our attention to some important features of a detailed
+sort which glaciers exhibit.
+
+If we visit a glacier during the part of the year when the winter
+snows are upon it, it may appear to have a very uninterrupted surface.
+But as the summer heat advances, the mask of the winter coating goes
+away, and we may then see the structure of the ice. First of all we
+note in all valley glaciers such as we are observing that the stream
+is overlaid by a quantity of rocky waste, the greater part of which
+has come down with the avalanches in the manner before described,
+though a small part may have been worn from the bed over which the ice
+flows. In many glaciers, particularly as we approach their
+termination, this sheet of earth and rock materials often covers the
+ice so completely that the novice in such regions finds it difficult
+to believe that the ice is under his feet. If the explorer is minded
+to take the rough scramble, he can often walk for miles on these
+masses of stone without seeing, much less setting foot on any frozen
+water. In some of the Alaskan glaciers this coating may bear a forest
+growth. In general, this material, which is called moraine, is
+distributed in bands parallel to the sides of the glaciers, and the
+strips may amount to a half dozen or more. Those on the sides of the
+ice have evidently been derived from the precipices which they have
+passed. Those in the middle have arisen from the union of the moraines
+formed in two or more tributary valleys.
+
+[Illustration: Fig. 12.--Map of glaciers and moraines near Mont Blanc.]
+
+Where the avalanches fall most plentifully, the stones lie buried with
+the snow, and only melt out when the stream attains the region where
+the annual waste of its surface exceeds the snowfall. In this section
+we can see how the progressive melting gradually brings the rocky
+_débris_ into plain view. Here and there we will find a boulder
+perched on a pedestal of ice, which indicates a recent down-wearing of
+the field. A frequent sound in these regions arises from the tumble of
+the stones from their pedestals or the slipping of the masses from the
+sharp ridge which is formed by the protection given to the ice through
+the thick coating of detritus on its surface. These movements of the
+moraines often distribute their waste over the glacier, so that in its
+lower part we can no longer trace the contributions from the several
+valleys, the whole area being covered by the _débris_. At the end of
+the ice stream, where its forward motion is finally overcome by the
+warmth which it encounters, it leaves in a rude heap, extending often
+like a wall across the valley, all the coarse fragments which it
+conveys. This accumulation, composed of all the lateral moraines which
+have gathered on the ice by the fall of avalanches, is called the
+terminal moraine. As the ice stream itself shrinks, a portion of the
+detritus next the boundary wall is apt to be left clinging against
+those slopes. It is from the presence of these heaps in valleys now
+abandoned by glaciers that we obtain some information as to the former
+greater extent of glacial action.
+
+The next most noticeable feature is the crevasse. These fractures
+often exist in very great numbers, and constitute a formidable barrier
+in the explorer's way. The greater part of these ruptures below the
+_serac_ zone run from the sides of the stream toward the centre
+without attaining that region. These are commonly pointed up stream;
+their formation is due to the fact that, owing to the swifter motion
+in the central parts of the stream, the ice in that section draws away
+from the material which is moving more slowly next the shore. As
+before noted, these ice fractures when drawn out naturally form
+fissures at right angles to the direction of the strain. In the middle
+portions of the ice other fissures form, though more rarely, which
+appear to depend on local strains brought about through the
+irregularity of the surface over which the ice is flowing.
+
+If the observer is fortunate, he may in his journey over the glacier
+have a chance to see and hear what goes on when crevasses are formed.
+First he will hear a deep, booming sound beneath his feet, which
+merges into a more splintering note as the crevice, which begins at
+the bottom or in the distance, comes upward or toward him. When the
+sound is over, he may not be able to see a trace of the fracture,
+which at first is very narrow. But if the break intersect any of the
+numerous shallow pools which in a warm summer's day are apt to cover a
+large part of the surface, he may note a line of bubbles rushing up
+through the water, marking the escape of the air from the glacier,
+some remnant of that which is imprisoned in the original snow. Even
+where this indication is wanting, he can sometimes trace the crevice
+by the hissing sound of the air streams where they issue from the ice.
+If he will take time to note what goes on, he can usually in an hour
+or two behold the first invisible crack widen until it may be half an
+inch across. He may see how the surface water hastens down the
+opening, a little river system being developed on the surface of the
+ice as the streams make their way to one or more points of descent. In
+doing this work they excavate a shaft which often becomes many feet in
+diameter, down which their waters thunder to the base of the glacier.
+This well-like opening is called a _moulin_, or mill, a name which, as
+we shall see, is well deserved from the work which falling waters
+accomplish. Although the institution of the _moulin_ shaft depends
+upon the formation of a crevice, it often happens that as the ice
+moves farther on its journey its walls are again thrust together,
+soldered in the manner peculiar to ice, so that no trace of the
+rupture remains except the shaft which it permitted to form. Like
+everything else in the glacier, the _moulin_ slowly moves down the
+slope, and remains open as long as it is the seat of descending waters
+produced by the summer melting. When it ceases to be kept open from
+the summer, its walls are squeezed together in the fashion that the
+crevices are closed.
+
+Forming here and there, and generally in considerable numbers, the
+crevices of a glacier entrap a good deal of the morainal _débris_,
+which falls through them to the bottom of the glacier. Smaller bits
+are washed into the _moulin_, by the streams arising from the melting
+ice, which is brought about by the warm sun of the summer, and
+particularly by the warm rains of that season. On those glaciers
+where, owing to the irregularity of the bottom over which the ice
+flows, these fractures are very numerous, it may happen that all the
+detritus brought upon the surface of the glacier by avalanches finds
+its way to the floor of the ice.
+
+Although it is difficult to learn what is going on at the under
+surface of the glacier, it is possible directly and indirectly to
+ascertain much concerning the peculiar and important work which is
+there done. The intrepid explorer may work his way in through the
+lateral fissures, and even with care safely descend some of the
+fissures which penetrate the central parts of a shallow ice stream.
+There, it may be at the depth of a hundred feet or more, he will find
+a quantity of stones, some of which may be in size like to a small
+house held in the body of the ice, but with one side resting upon the
+bed rock. He may be so fortunate as to see the stone actually in
+process of cutting a groove in the bed rock as it is urged forward by
+the motion of the glacier. The cutting is not altogether in the fixed
+material, for the boulder itself is also worn and scored in the work.
+Smaller pebbles are caught in the space between the erratic and the
+motionless rock and ground to bits. If in his explorations the student
+finds his way to the part of the floor on which the waters of a
+_moulin_ fall, he may have a chance to observe how the stones set in
+motion serve to cut the bed rock, forming elongated potholes much as
+in the case of ordinary waterfalls, or at the base of those shafts
+which afford the beginnings of limestone caverns.
+
+The best way to penetrate beneath the glacier is through the arch of
+the stream which always flows from the terminal face of the ice river.
+Even in winter time every large glacier discharges at its end a
+considerable brook, the waters of which have been melted from the ice
+in small part by the outflow of the earth's heat; mainly, however, by
+the warmth produced in the friction of the ice on itself and on its
+bottom--in other words, by the conversion of that energy of position,
+of which we have often to speak, into heat. In the summer time this
+subglacial stream is swollen by the surface waters descending through
+the crevices and the _moulins_ which come from them, so that the
+outflow often forms a considerable river, and thus excavates in the
+ice a large or at least a long cavern, the base of which is the bed
+rock. In the autumn, when the superficial melting ceases, this gallery
+can often be penetrated for a considerable distance, and affords an
+excellent way to the secrets of the under ice. The observer may here
+see quantities of the rock material held in the grip of the ice, and
+forced to a rude journey over the bare foundation stones. Now and then
+he may find the glacial mass in large measure made up of stones, the
+admixture extending many feet above the bottom of the cavern, perhaps
+to the very top of the arch. He may perchance find that these stones
+are crushing each other where they are in contact. The result will be
+brought about by the difference in the rate of advance of the ice,
+which moves the faster the higher it is above the surface over which
+it drags, and thus forces the stones on one level over those below.
+Where the waters of the subglacial stream have swept the bed rock
+clean of _débris_ its surface is scored, grooved, and here and there
+polished in a manner which is accomplished only by ice action, though
+some likeness to it is afforded where stones have been swept over for
+ages by blowing sand. Here and there, often in a way which interrupts
+the cavern journey, the shrunken stream, unable to carry forward the
+_débris_, deposits the material in the chamber, sometimes filling the
+arch so completely that the waters are forced to make a detour. This
+action is particularly interesting, for the reason that in regions
+whence glaciers have disappeared the deposits formed in the old ice
+arches often afford singularly perfect moulds of those caverns which
+were produced by the ancient subglacial streams. These moulds are
+termed _eskers_.
+
+If the observer be attentive, he will note the fact that the waters
+emerging from beneath the considerable glacier are very much charged
+with mud. If he will take a glass of the water at the point of escape,
+he will often find, on permitting it to settle, that the sediment
+amounts to as much as one twentieth of the volume. While the greater
+part of this detritus will descend to the bottom of the vessel in the
+course of a day, a portion of it does not thus fall. He may also note
+that this mud is not of the yellowish hue which he is accustomed to
+behold in the materials laid down by ordinary rivers, but has a
+whitish colour. Further study will reveal the fact that the difference
+is due to the lack of oxidation in the case of the glacial detritus.
+River muds forming slowly and during long-continued exposure to the
+action of the air have their contained iron much oxidized, which gives
+them a part of their darkened appearance. Moreover, they are somewhat
+coloured with decayed vegetable matter. The waste from beneath the
+glacier has been quickly separated from the bed rock, all the faces of
+the grains are freshly fractured, and there is no admixture of organic
+matter. The faces of the particles thus reflect light in substantially
+the same way as powdered glass or pulverized ice, and consequently
+appear white.
+
+A little observation will show the student that this very muddy
+character of waters emerging from beneath the glacier is essentially
+peculiar to such streams as we have described. Ascending any of the
+principal valleys of Switzerland, he may note that some of the streams
+flow waters which carry little sediment even in times when they are
+much swollen, while others at all seasons have the whitish colour. A
+little further exploration, or the use of a good map, will show him
+that the pellucid streams receive no contributions of glacial water,
+while those which look as if they were charged with milk come, in part
+at least, from the ice arches. From some studies which the writer has
+made in Swiss valleys, it appears that the amount of erosion
+accomplished on equal areas of similar rock by the descent of the
+waters in the form of a glacier or in that of ordinary torrents
+differs greatly. Moving in the form of ice, or in the state of
+ice-confined streams, the mass of water applies very many times as
+much of its energy of position to grinding and bearing away the rocks
+as is accomplished where the water descends in its fluid state.
+
+The effect of the intense ice action above noted is rapidly to wear
+away the rocks of the valley in which the glacier is situated. This
+work is done not only in a larger measure but in a different way from
+that accomplished by torrents. In the case of the latter, the stream
+bed is embarrassed by the rubbish which comes into it; only here and
+there can it attack the bed rock by forcing the stones over its
+surface. Only in a few days of heavy rain each year is its work at all
+effective; the greater part of the energy of position of its waters is
+expended in the endless twistings and turnings of its stream, which
+result only in the development of heat which flies away into the
+atmosphere. In the ice stream, owing to its slow movement and to the
+detritus which it forces along the bottom, a vastly greater part of
+the energy which impels it down the slope is applied to rock cutting.
+None of the boulders, even if they are yards in diameter, obstruct its
+motion; small and great alike are to it good instruments wherewith to
+attack the bed rocks. The fragments are never left to waste by
+atmospheric decay, but are to a very great extent used up in
+mechanical work, while the most of the detritus which comes to a
+torrent is left in a coarse state when it is delivered to the stream;
+the larger part of that which the glacier transports is worn out in
+its journey. To a great extent it is used up in attacking the bed
+rock. In most cases the _débris_ in the terminal moraine is evidently
+but a small part of what entered the ice during its journey from the
+uplands; the greater part has been worn out in the rude experiences to
+which it has been subjected.
+
+It is evident that even in the regions now most extensively occupied
+by glaciers the drainage systems have been shaped by the movement of
+ordinary streams--in other words, ice action is almost everywhere,
+even in the regions about the poles, an incidental feature in the work
+of water, coming in only to modify the topography, which is mainly
+moulded by the action of fluid water. When, owing to climatal changes,
+a valley such as those of the Alps is occupied by a glacial stream,
+the new current proceeds at once, according to its evident needs, to
+modify the shape of its channel. An ordinary torrent, because of the
+swiftness of its motion, which may, in general, be estimated at from
+three to five miles an hour, can convey away the precipitation over a
+very narrow bed. Therefore its channel is usually not a hundredth part
+as wide as the gorge or valley in which it lies. But when the
+discharge takes place by a glacier, the speed of which rarely exceeds
+four or five feet a day, the ice stream because of its slow motion has
+to fill the trough from side to side, it has to be some thousand times
+as deep and wide as the torrent. The result is that as soon as the
+glacial condition arises in a country the ice streams proceed to
+change the old V-shaped torrent beds into those which have a broad
+U-like form. The practised eye can in a way judge how long a valley
+has been subjected to glacial action by the extent to which it has
+been widened by this process.
+
+In the valleys of Switzerland and other mountain districts which have
+been attentively studied it is evident that glacial action has played
+a considerable part in determining their forms. But the work has been
+limited to that part of the basin in which the ice is abundantly
+provided with cutting tools in the stone which have found their way to
+the base of the stream. In the region of the _névé_, where the
+contributions of rocky matter to the surface of the deposit made from
+the few bare cliffs which rise above the sheet of snow is small, the
+snow-ice does no cutting of any consequence. Where it passes over the
+steep at the head of the deep valley into which it drains, and is
+riven into the _seracs_, such stony matter as it may have gathered is
+allowed to fall to the bottom, and so comes into a position where it
+may do effective work. From this _serac_ section downward the now
+distinct ice river, being in general below the snow line, has
+everywhere cliffs, on either side from which the contributions of rock
+material are abundant. Hence this part of the glacier, though it is
+the wasting portion of its length, does all the cutting work of any
+consequence which is performed. It is there that the underrunning
+streams become charged with sediment, which, as we have noted, they
+bear in surprising quantities, and it is therefore in this section of
+the valley that the impress of the ice work is the strongest. Its
+effect is not only to widen the valley and deepen it, but also to
+advance the deep section farther up the stream and its tributaries.
+The step in the stream beds which we find at the _seracs_ appears to
+mark the point in the course of the glacier where, owing to the
+falling of stones to its base, as well as to its swifter movements and
+the firmer state of the ice, it does effective wearing.
+
+There are many other features connected with glaciers which richly
+repay the study of those who have a mind to explore in the manner of
+the physicist interested in ice actions the difficult problems which
+they afford; but as these matters are not important from the point of
+view of this work, no mention of them will here be made. We will now
+turn our attention to that other group of glaciers commonly termed
+continental, which now exist about either pole, and which at various
+times in the earth's history have extended far toward the equator,
+mantling over vast extents of land and shallow sea. The difference
+between the ice streams of the mountains and those which we term
+continental depends solely on the areas of the fields and the depth of
+the accumulation. In an ordinary Alpine region the _névé_ districts,
+where the snow gathers, are relatively small. Owing to the rather
+steep slopes, the frozen water is rapidly discharged into the lower
+valleys, where it melts away. Both in the _névé_ and in the distinct
+glacier of the lower grounds there are, particularly in the latter,
+projecting peaks, from which quantities of stone are brought down by
+avalanches or in ordinary rock falls, so that the ice is abundantly
+supplied with cutting tools, which work from its surface down to its
+depths.
+
+As the glacial accumulation grows in depth there are fewer peaks
+emerging from it, and the streams which it feeds rise the higher until
+they mantle over the divides between the valleys. Thus by
+imperceptible stages valley glaciers pass to the larger form, usually
+but incorrectly termed continental. We can, indeed, in going from the
+mountains in the tropics to the poles, note every step in this
+transition, until in Greenland we attain the greatest ice mass in the
+world, unless that about the southern pole be more extensive. In the
+Greenland glacier the ice sheet covers a vast extent of what is
+probably a mountain country, which is certainly of this nature in the
+southern part of the island, where alone we find portions of the earth
+not completely covered by the deep envelope. Thanks to the labours of
+certain hardy explorers, among whom Nansen deserves the foremost
+place, we now know something as to the conditions of this vast ice
+field, for it has been crossed from shore to shore. The results of
+these studies are most interesting, for they afford us a clew as to
+the conditions which prevail over a large part of the earth during the
+Glacial period from which the planet is just escaping, and in the
+earlier ages when glaciation was likewise extensive. We shall
+therefore consider in a somewhat detailed way the features which the
+Greenland glacier presents.
+
+Starting from the eastern shore of that land, if we may thus term a
+region which presents itself mainly in the form of ice, we find next
+the shore a coast line not completely covered with ice and snow, but
+here and there exhibiting peaks which indicate that if the frozen
+mantle were removed the country would appear deeply intersected with
+fiords in the manner exhibited in the regions to the south of
+Greenland or the Scandinavian peninsula. The ice comes down to the
+sea through the valleys, often facing the ocean for great distances
+with its frozen cliffs. Entering on this seaward portion of the
+glacier, the observer finds that for some distance from the coast line
+the ice is more or less rifted with crevices, the formation of which
+is doubtless due to irregularities of the rock bottom over which it
+moves. These ruptures are so frequent that for some miles back it is
+very difficult to find a safe way. Finally, however, a point is
+attained where these breaks rather suddenly disappear, and thence
+inward the ice rises at the rate of upward slope of a few feet to the
+mile in a broad, nearly smooth incline. In the central portion of the
+region for a considerable part of the territory the ice has very
+little slope. Thence it declines toward the other shore, exhibiting
+the same features as were found on the eastern versant until near the
+coast, when again the surface is beset with crevices which continue to
+the margin of the sea.
+
+Although the explorations of the central field of Greenland are as yet
+incomplete, several of these excursions into or across the interior
+have been made, and the identity of the observations is such that we
+can safely assume the whole region to be of one type. We can
+furthermore run no risk in assuming that what we find in Greenland, at
+least so far as the unbroken nature of the central ice field is
+concerned, is what must exist in every land where the glacial envelope
+becomes very deep. In Greenland it seems likely that the depth of the
+ice is on the average more than half a mile, and in the central part
+of the realm the sheet may well have a much greater profundity; it may
+be nearly a mile deep. The most striking feature--that of a vast
+unbroken expanse, bordered by a region where the ice is ruptured--is
+traceable wherever very extensive and presumably deep deposits of ice
+have been examined. As we shall see hereafter, these features teach us
+much as to the conditions of glacial action--a matter which we shall
+have to examine after we have completed our general survey as to the
+changes which occur during glacial periods.
+
+In the present state of that wonderful complex of actions which we
+term climate, glaciers are everywhere, so far as our observations
+enable us to judge, generally in process of decrease. In Switzerland,
+although the ancients even in Roman days were in contact with the ice,
+they were so unobservant that they did not even remark that the ice
+was in motion. Only during the last two centuries have we any
+observations of a historic sort which are of value to the geologist.
+Fortunately, however, the signs written on the rock tell the story,
+except for its measurement in terms of years, as clearly as any
+records could give it. From this testimony of the rocks we perceive
+that in the geological yesterday, though it may have been some tens of
+thousands of years ago, the Swiss glaciers, vastly thickened, and with
+their horizontal area immensely expanded, stretched over the Alpine
+country, so that only here and there did any of the sharper peaks rise
+above the surface. These vast glaciers, almost continually united on
+their margins, extended so far that every portion of what is now the
+Swiss Republic was covered by them. Their front lay on the southern
+lowlands of Germany, on the Jura district of France; on the south, it
+stretched across the valley of the Po as far as near Milan. We know
+this old ice front by the accumulations of rock _débris_ which were
+brought to it from the interior of the mountain realm. We can
+recognise the peculiar kinds of stone, and with perfect certainty
+trace them to the bed rock whence they were riven. Moreover, we can
+follow back through the same evidence the stages of retreat of the
+glaciers, until they lost their broad continental character and
+assumed something like their present valley form. Up the valley of any
+of the great rivers, as, for instance, that of the Rhône above the
+lake of Geneva, we note successive terminal moraines which clearly
+indicate stages in the retreat of the ice when for a time it ceased to
+go backward, or even made a slight temporary readvance. It is easily
+seen that on such occasions the stones carried to the ice front would
+be accumulated in a heap, while during the time when day by day the
+glacier was retreating the rock waste would be left broadcast over the
+valley.
+
+As we go up from the course of the glacial streams we note that the
+successive moraines have their materials in a progressively less
+decayed state. Far away from the heap now forming, and in proportion
+to the distance, the stones have in a measure rotted, and the heaps
+which they compose are often covered with soil and occupied by
+forests. Within a few miles of the ice front the stones still have a
+fresh aspect. When we arrive within, say, half a mile of the moraine
+now building, we come to the part of the glacial retreat of which we
+have some written or traditional account. This is in general to the
+effect that the wasting of the glaciers is going on in this century as
+it went on in the past. Occasionally periods of heavy snow would
+refresh the ice streams, so that for a little time they pushed their
+fronts farther down the valley. The writer has seen during one of
+these temporary advances the interesting spectacle of ice destroying
+and overturning the soil of a small field which had been planted in
+grain.
+
+It should be noted that these temporary advances of the ice are not
+due to the snowfall of the winter or winters immediately preceding the
+forward movement. So slow is the journey of the ice from the _névé_
+field to the end of a long glacier that it may require centuries for
+the store accumulated in the uplands to affect the terminal portion of
+the stream. We know that the bodies of the unhappy men who have been
+lost in the crevices of the glacier are borne forward at a uniform and
+tolerably computable rate until they emerge at the front, where the
+ice melts away. In at least one case the remains have appeared after
+many years in the _débris_ which is contributed to the moraine. On
+account of this slow feeding of the glacial stream, we naturally may
+expect to find, as we do, in fact, that a great snowfall of many
+years ago, and likewise a period when the winter's contribution has
+been slight, would influence the position of the terminal point of the
+ice stream at different times, according to its length. If the length
+of the flow be five miles, it may require twenty or thirty years for
+the effect to be evident; while if the stream be ten miles long, the
+influence may not be noted in less than threescore years. Thus it
+comes about that at the present time in the same glacial district some
+streams may be advancing while others are receding, though, on the
+whole, the ice is generally in process of shrinkage. If the present
+rate of retreat should be maintained, it seems certain that at the end
+of three centuries the Swiss glaciers as a whole will not have
+anything like their present area, and many of the smaller streams will
+entirely disappear.
+
+Following the method of the illustrious Louis Agassiz, who first
+attentively traced the evidence which shows the geologically recent
+great extension of glaciers by studying the evidence of the action in
+fields they no longer occupy, geologists have now inspected a large
+part of the land areas with a view to finding the proofs of such ice
+work. So far as these indications are concerned, the indications which
+they have had to trace are generally of a very unmistakable character.
+Rarely, indeed, does a skilled student of such phenomena have to
+search in any region for more than a day before he obtains indubitable
+evidence which will enable him to determine whether or not the field
+has recently been occupied by an enduring ice sheet--one which
+survives the summer season and therefore deserves the name of glacier.
+The indications which he has to consider consist in the direction and
+manner in which the surface materials have been carried, the physical
+conditions of these materials, the shape of the surface of the
+underlying rock as regards its general contour, and the presence or
+absence of scratches and groovings on its surface. As these records of
+ice action are of first importance in dealing with this problem, and
+as they afford excellent subjects for the study of those who dwell in
+glaciated regions, we shall note them in some detail.
+
+The geologist recognises several ways in which materials may be
+transported on the surface of the earth. They may be cast forth by
+volcanoes, making their journey by being shot through the air, or by
+flowing in lava streams; it is always easy at a glance, save in very
+rare instances, to determine whether fragments have thus been
+conveyed. Again, the detritus may be moved by the wind; this action is
+limited; it only affects dust, sand, and very small pebbles, and is
+easily discriminated. The carriage may be effected by river or marine
+currents; here, again, the size of the fragments moved is small, and
+the order of their arrangement distinctly traceable. The fragments may
+be conveyed by ice rafts; here, too, the observer can usually limit
+the probabilities he has to consider by ascertaining, as he can
+generally do, whether the region which he is observing has been below
+a sea or lake. In a word, the before-mentioned agents of
+transportation are of somewhat exceptional influence, and in most
+cases can, as explanations of rock transportation, be readily
+excluded. When, therefore, the geologist finds a country abundantly
+covered with sand, pebbles, and boulders arranged in an irregular way,
+he has generally only to inquire whether the material has been carried
+by rivers or by glaciers. This discrimination can be quickly and
+critically effected. In the first place, he notes that rivers only in
+their torrent sections can carry large fragments of rock, and that in
+all cases the fragments move down hill. Further, that where deposits
+are formed, they have more or less the form of alluvial deposits. If
+now the observations show that the rock waste occupying the surface of
+any region has been carried up hill and down, across the valleys,
+particularly if there are here and there traces of frontal moraines,
+the geologist is entitled to suppose--he may, indeed, be sure--that
+the carriage has been effected by a glacial sheet.
+
+Important corroborative evidence of ice action is generally to be
+found by inspecting the bed rock below the detritus, which indicates
+glacial action. Even if it be somewhat decayed, as is apt to be the
+case where the ice sheet long since passed away, the bed rock is
+likely to have a warped surface; it is cast into ridges and furrows of
+a broad, flowing aspect, such as liquid water never produces, which,
+indeed, can only be created by an ice sheet moving over the surface,
+cutting its bed in proportion to the hardness of the material.
+Furthermore, if the bed rock have a firm texture, and be not too much
+decayed, we almost always find upon it grooves or scratches, channels
+carved by the stones embedded in the body of the ice, and drawn by its
+motion over the fixed material. Thus the proof of glacial extension in
+the last ice epoch is made so clear that accurate maps can be prepared
+showing the realm of its action. This task is as yet incomplete,
+although it is already far advanced.
+
+While the study of glaciers began in Europe, inquiries concerning
+their ancient extension have been carried further and with more
+accuracy in North America than in any other part of the world. We may
+therefore well begin our description of the limits of the ice sheets
+with this continent. Imagining a seafarer to have approached America
+by the North Atlantic, as did the Scandinavians, and that his voyage
+came perhaps a hundred thousand years or more before that of Leif
+Ericsson, he would have found an ice front long before he attained the
+present shores of the land. This front may have extended from south of
+Greenland, off the shores of the present Grand Banks of Newfoundland,
+thence and westward to central or southern New Jersey. This cliff of
+ice was formed by a sheet which lay on the bottom of the sea. On the
+New Jersey coast the ice wall left the sea and entered on the body of
+the continent. We will now suppose that the explorer, animated with
+the valiant scientific spirit which leads the men of our day to seek
+the poles, undertook a land journey along the ice front across the
+continent. From the New Jersey coast the traveller would have passed
+through central Pennsylvania, where, although there probably detached
+outlying glaciers lying to the southward as far as central Virginia,
+the main front extended westward into the Ohio Valley. In southern
+Ohio a tongue of the ice projected southwardly until it crossed the
+Ohio River, where Cincinnati now lies, extending a few miles to the
+southward of the stream. Thence it deflected northwardly, crossing the
+Mississippi, and again the Missouri, with a tongue or lobe which went
+far southward in that State. Then again turning to the northwest, it
+followed in general the northern part of the Missouri basin until it
+came to within sight of the Rocky Mountains. There the ice front of
+the main glacier followed the trend of the mountains at some distance
+from their face for an unknown extent to the northward. In the
+Cordilleras, as far south as southern Colorado, and probably in the
+Sierra Nevada to south of San Francisco, the mountain centres
+developed local glaciers, which in some places were of very great
+size, perhaps exceeding any of those which now exist in Switzerland.
+It will thus be seen that nearly one half of the present land area of
+North America was beneath a glacial covering, though, as before noted,
+the region about the Gulf of Mexico may have swayed upward when the
+northern portion of the land was borne down by the vast load of ice
+which rested upon it. Notwithstanding this possible addition to the
+land, our imaginary explorer would have found the portion of the
+continent fit for the occupancy of life not more than half as great as
+it is at present.
+
+In the Eurasian continent there was no such continuous ice sheet as in
+North America, but the glaciers developed from a number of different
+centres, each moving out upon the lowlands, or, if its position was
+southern, being limited to a particular mountain field. One of these
+centres included Scandinavia, northern Germany, Great Britain about as
+far south as London, and a large part of Ireland, the ice covering the
+intermediate seas and extending to the westward, so that the passage
+of the North Atlantic was greatly restricted between this ice front
+and that of North America. Another centre, before noted, was formed in
+the Alps; yet another, of considerable area, in the Pyrenees; other
+less studied fields existed in the Apennines, in the Caucasus, the
+Ural, and the other mountains of northern Asia. Curiously enough,
+however, the great region of plains in Siberia does not appear to have
+been occupied by a continuous ice sheet, though the similar region in
+North America was deeply embedded in a glacier. Coincident with this
+development of ice in the eastern part of the continent, the ice
+streams of the Himalayan Mountains, some of which are among the
+greatest of our upland glaciers, appear to have undergone but a
+moderate extension. Many other of the Eurasian highlands were probably
+ice-bound during the last Glacial period, but our knowledge concerning
+these local fields is as yet imperfect.
+
+In the southern hemisphere the lands are of less extent and, on the
+whole, less studied than in the northern realm. Here and there where
+glaciers exist, as in New Zealand and in the southern part of South
+America, observant travellers have noticed that these ice fields have
+recently shrunk away. Whether the time of greatest extension and of
+retreat coincided with that of the ice sheets in the north is not yet
+determined; the problem, indeed, is one of some difficulty, and may
+long remain undecided. It seems, however, probable that the glaciers
+of the southern hemisphere, like those in the north, are in process of
+retreat. If this be true, then their time of greatest extension was
+probably the same as that of the ice sheets about the southern pole.
+From certain imperfect reports which we have concerning evidences of
+glaciation in Central America and in the Andean district in the
+northern part of South America, it seems possible that at one time the
+upland ice along the Cordilleran chain existed from point to point
+along that system of elevations, so that the widest interval between
+the fields of permanent snow with their attendant glaciers did not
+much exceed a thousand miles.
+
+Observing the present gradual retreat of those ice remnants which
+remain mere shreds and patches of the ancient fields, it seems at
+first sight likely that the extension and recession of the great
+glaciers took place with exceeding slowness. Measured in terms of
+human life, in the manner in which we gauge matters of man's history,
+this process was doubtless slow. There are reasons, however, to
+believe that the coming and going were, in a geological sense, swift;
+they may have, indeed, been for a part of the time of startling
+rapidity. Going back to the time of geological yesterday, before the
+ice began its development in the northern hemisphere, all the evidence
+we can find appears to indicate a temperate climate extending far
+toward the north pole. The Miocene deposits found within twelve
+degrees, or a little more than seven hundred miles, of the north pole,
+and fairly within the realm of lowest temperature which now exists on
+the earth, show by the plant remains which they contain that the
+conditions permitted the growth of forests, the plants having a
+tolerably close resemblance to those which now freely develop in the
+southern portion of the Mississippi Valley. Among them there are
+species which had the habit of retaining their broad, rather soft
+leaves throughout the winter season. The climate appears, in a word,
+to have been one where the mean annual temperature must have been
+thirty degrees or more higher than the present average of that realm.
+Although such conditions near the sea level are not inconsistent with
+the supposition that glaciers existed in the higher mountains of the
+north, they clearly deny the possibility of the realm being occupied
+by continental glaciers.
+
+Although the Pliocene deposits formed in high latitudes have to a
+great extent been swept away by the subsequent glacial wearing, they
+indicate by their fossils a climatal change in the direction of
+greater cold. We trace this change, though obscurely, in a
+progressive manner to a point where the records are interrupted, and
+the next interpretable indication we have is that the ice sheet had
+extended to somewhere near the limits which we have noted. We are then
+driven to seek what we can concerning the sojourn of the ice on the
+land by the amount of wearing which it has inflicted upon the areas
+which it occupied. This evidence has a certain, though, as we shall
+see, a limited value.
+
+When the students of glacial action first began the great task of
+interpreting these records, they were led to suppose that the amount
+of rock cutting which was done by the ice was very great. Observing
+what goes on, in the manner we have noted, beneath a valley glacier
+such as those of Switzerland, they saw that the ice work went on
+rapidly, and concluded that if the ice remained long at work in a
+region it must do a vast deal of erosion. They were right in a part of
+their premises, but, as we shall see, probably in another part wrong.
+Looking carefully over the field where the ice has operated, we note
+that, though at first sight the area appears to have lost all trace of
+its preglacial river topography, this aspect is due mainly to the
+irregular way in which the glacial waste is laid down. Close study
+shows us that we may generally trace the old stream valleys down to
+those which were no larger than brooks. It is true that these channels
+are generally and in many places almost altogether filled in with
+rubbish, but a close study of the question has convinced the writer,
+and this against a previous view, that the amount of erosion in New
+England and Canada, where the work was probably as great as anywhere,
+has not on the average exceeded a hundred feet, and probably was much
+less than that amount.
+
+Even in the region north of Lake Ontario, over which the ice was deep
+and remained for a long time, the amount of erosion is singularly
+small. Thus north of Kingston the little valleys in the limestone
+rocks which were cut by the preglacial streams, though somewhat
+encumbered with drift, remain almost as distinct as they are on
+similar strata in central Kentucky, well south of the field which the
+ice occupied. In fact, the ice sheet appears to have done the greatest
+part of its work and to have affected the surface most in the belt of
+country a few hundred miles in width around the edges of the sheet. It
+was to be expected that in a continental glacier, as in those of
+mountain valleys, the most of the _débris_ should be accumulated about
+the margin where the materials dropped from the ice. But why the
+cutting action should be greatest in that marginal field is not at
+first sight clear. To explain this and other features as best we may,
+we shall now consider the probable history of the great ice march in
+advance and retreat, and then take up the conditions which brought
+about its development and its disappearance.
+
+Ice is in many ways the most remarkable substance with which the
+physicist has to deal, and among its eminent peculiarities is that it
+expands in freezing, while the rule is that substances contract in
+passing from the fluid to the solid state. On this account frozen
+water acts in a unique manner when subjected to pressure. For each
+additional atmosphere of pressure--a weight amounting to about fifteen
+pounds to the square inch--the temperature at which the ice will melt
+is lowered to the amount of sixteen thousandths of a degree
+centigrade. If we take a piece of ice at the temperature of freezing
+and put upon it a sufficient weight, we inevitably bring about a small
+amount of melting. Where we can examine the mass under favourable
+conditions, we can see the fluid gather along the lines of the
+crystals or other bits of which the ice is composed. We readily note
+this action by bringing two pieces of ice together with a slight
+pressure; when the pressure is removed, they will adhere. The adhesion
+is brought about not by any stickiness of the materials, for the
+substance has no such property. It is accomplished by melting along
+the line of contact, which forms a film of water, that at once
+refreezes when the pressure is withdrawn. When a firm snowball is
+made by even pressing snow, innumerable similar adhesions grow up in
+the manner described. The fact is that, given ice at the temperature
+at which it ordinarily forms, pressure upon it will necessarily
+develop melting.
+
+The consequences of pressure melting as above described are in
+glaciers extremely complicated. Because the ice is built into the
+glacier at a temperature considerably below the freezing point, it
+requires a great thickness of the mass before the superincumbent
+weight is sufficient to bring about melting in its lower parts. If we
+knew the height at which a thermometer would have stood in the surface
+ice of the ancient glacier which covered the northern part of North
+America, we could with some accuracy compute how thick it must have
+been before the effect of pressure alone would have brought about
+melting; but even then we should have to reckon the temperature
+derived from the grinding of the ice over the floor and the crushing
+of rocks there effected, as well as the heat which is constantly
+though slowly coming forth from the earth's interior. The result is
+that we can only say that at some depth, probably less than a mile,
+the slowly accumulating ice would acquire such a temperature that,
+subjected to the weight above it, the material next the bottom would
+become molten, or at least converted into a sludgelike state, in which
+it could not rub against the bottom, or move stones in the manner of
+ordinary glaciers.
+
+As fast as the ice assumed this liquid or softened state, it would be
+squeezed out toward the region where, because of the thinning of the
+glacier, it would enter a field where pressure melting did not occur.
+It would then resume the solid state, and thence journey to the margin
+of the ice in the ordinary manner. We thus can imagine how such a
+glacier as occupied the northern part of this continent could have
+moved from the central parts toward its periphery, as we can not do if
+we assume that the glacier everywhere lay upon the bed rock. There is
+no slope from Lake Erie to the Ohio River at Cincinnati. Knowing that
+the ice moved down this line, there are but two methods of accounting
+for its motion: either the slope of the upper surface to the northward
+was so steep that the mass would have been thus urged down, the upper
+parts dragging the bottom along with them, or the ice sheet for the
+greater part of its extent rested upon pressure-molten water, or
+sludge ice, which was easily squeezed out toward the front. The first
+supposition appears inadmissible, for the reason that the ice would
+have to be many miles deep at Hudson Bay in order that its upper
+surface should have slope enough to overcome the rigidity of the
+material and bring about the movement. We know that any such depth is
+not supposable.
+
+The recent studies in Greenland supply us with strong corroborative
+evidence for the support of the view which is here urged. The wide
+central field of that area, where the ice has an exceeding slight
+declivity, and is unruptured by crevices, can not be explained except
+on the supposition that it rests on pressure-molten water. The thinner
+section next the shore, where the glacier is broken up by those
+irregular movements which its wrestle with the bottom inevitably
+induces, shows that there it is in contact with the bed rock, for it
+behaves exactly as do the valley glaciers of like thickness.
+
+The view above suggested as to the condition of continental glaciers
+enables us to explain not only their movements, but the relatively
+slight amount of wearing which they brought about on the lands they
+occupied. Beginning to develop in mountain regions, or near the poles
+on the lowlands, these sheets, as soon as they attained the thickness
+where the ice at their bottom became molten, would rapidly advance for
+great distances until they attained districts where the melting
+exceeded the supply of frozen material. In this excursion only the
+marginal portion of the glacier would do erosive work. This would
+evidently be continued for the greatest amount of time near the front
+or outer rim of the ice field, for there, we may presume, that for
+the longest time the cutting rim would rest upon the bed rock of the
+country. As the ice receded, this rim would fall back; thus in the
+retreat as in the advance the whole of the field would be subjected to
+a certain amount of erosion. On this supposition we should expect to
+find that the front of a continental glacier, fed with pressure-molten
+water from all its interior district, which became converted into ice,
+would attain much warmer regions than the valley streams, where all
+the flow took place in the state of ice, and, furthermore, that the
+speed of the going on the margin would be much more rapid than in the
+Alpine streams. These suppositions are well borne out by the study of
+existing continental ice sheets, which move with singular rapidity at
+their fronts, and by the ancient glaciers, which evidently extended
+into rather warm fields. Thus, when the ice front lay at the site of
+Cincinnati, at six hundred feet above the sea, there were no glaciers
+in the mountains of North Carolina, though those rise more than five
+thousand feet higher in the air, and are less than two hundred miles
+farther south. It is therefore evident that the continental glacier at
+this time pushed southward into a comparatively warm country in a way
+that no stream moving in the manner of a valley glacier could possibly
+have done.
+
+The continental glaciers manage in many cases to convey detritus from
+a great distance. Thus, when the ice sheet advanced southwardly from
+the regions north of the Great Lakes, they conveyed quantities of the
+_débris_ from that section as far south as the Ohio River. In part
+this rubbish was dragged forward by the ice as the sheet advanced; in
+part it was urged onward by the streams of liquid water formed by the
+ordinary process of ice melting. Such subglacial rivers appear to have
+been formed along the margins of all the great glaciers. We can
+sometimes trace their course by the excavation which they have made,
+but more commonly by the long ridges of stratified sand and gravel
+which were packed into the caverns excavated by these subglacial
+rivers, which are known to glacialists as _eskers_, or as serpent
+kames. In many cases we can trace where these streams flowed up stream
+in the old river valleys until they discharged over their head waters.
+Thus in the valley of the Genesee, which now flows from Pennsylvania,
+where it heads against the tributaries of the Ohio and Susquehanna, to
+Lake Ontario, there was during the Glacial epoch a considerable river
+which discharged its waters into those of the Ohio and the Susquehanna
+over the falls at the head of its course.
+
+[Illustration: _Front of Muir Glacier, showing ice entering the sea;
+also small icebergs._]
+
+The effect of widespread glacial action on a country such as North
+America appears to have been, in the first place, to disturb the
+attitude of the land by bearing down portions of its surface, a
+process which led to the uprising of other parts which lay beyond the
+realm of the ice. Within the field of glaciation, so far as the ice
+rested bodily on the surface, the rocks were rapidly worn away. A
+great deal of the _débris_ was ground to fine powder, and went far
+with the waters of the under-running streams. A large part was
+entangled in the ice, and moved forward toward the front of the
+glacier, where it was either dropped at the margin or, during the
+recession of the glacier, was laid upon the surface as the ice melted
+away. The result of this erosion and transportation has been to change
+the conditions of the surface both as regards soil and drainage. As
+the reader has doubtless perceived, ordinary soil is, outside of the
+river valleys, derived from the rock beneath where it lies. In
+glaciated districts the material is commonly brought from a
+considerable distance, often from miles away. These ice-made soils are
+rarely very fertile, but they commonly have a great endurance for
+tillage, and this for the reason that the earth is refreshed by the
+decay of the pebbles which they contain. Moreover, while the tillable
+earth of other regions usually has a limited depth, verging downward
+into the semisoil or subsoil which represent the little changed bed
+rocks, glacial deposits can generally be ploughed as deeply as may
+prove desirable.
+
+The drainage of a country recently affected by glaciers is always
+imperfect. Owing to the irregular erosion of the bed rocks, and to the
+yet more irregular deposition of the detritus, there are very numerous
+lakes which are only slowly filled up or by erosion provided with
+drainage channels. Though several thousand years have passed by since
+the ice disappeared from North America, the greater part of the area
+of these fresh-water basins remains, the greater number of them,
+mostly those of small size, have become closed.
+
+Where an ice stream descends into the sea or into a large lake, the
+depth of which is about as great as the ice is thick, the relative
+lightness of the ice tends to make it float, and it shortly breaks off
+from the parent mass, forming an iceberg. Where, as is generally the
+case in those glaciers which enter the ocean, a current sweeps by the
+place where the berg is formed, it may enter upon a journey which may
+carry the mass thousands of miles from its origin. The bergs separated
+from the Greenland glaciers, and from those about the south pole, are
+often of very great size; sometimes, indeed, they are some thousand
+feet in thickness, and have a length of several miles. It often
+happens that these bergs are formed of ice, which contains in its
+lower part a large amount of rock _débris_. As the submerged portion
+of the glacier melts in the sea water, these stones are gradually
+dropped to the bottom, so that the cargo of one berg may be strewed
+along a line many hundred miles in length. It occasionally happens
+that the ice mass melts more slowly in those parts which are in the
+air than in its under-water portions. It thus becomes top-heavy and
+overturns, in which case such stony matter as remains attains a
+position where it may be conveyed for a greater distance than if the
+glacier were not capsized. It is likely, indeed, that now and then
+fragments of rock from Greenland are dropped on the ocean floor in the
+part of the Atlantic which is traversed by steamers between our
+Atlantic ports and Great Britain.
+
+Except for the risks which they bring to navigators, icebergs have no
+considerable importance. It is true they somewhat affect the
+temperature of sea and air, and they also serve to convey fragments of
+stone far out to sea in a way that no other agent can effect; but, on
+the whole, their influence on the conditions of the earth is
+inconsiderable.
+
+Icebergs in certain cases afford interesting indices as to the motion
+of oceanic currents, which, though moving swiftly at a depth below the
+surface, do not manifest themselves on the plain of the sea. Thus in
+the region about Greenland, particularly in Davis Strait, bergs have
+been seen forcing their way southward at considerable speed through
+ordinary surface ice, which was either at rest or moving in the
+opposite direction. The train of these bergs, which moves upward from
+the south polar continent, west of Patagonia, indicates also in a very
+emphatic way the existence of a very strong northward-setting current
+in that part of the ocean.
+
+                  *       *       *       *       *
+
+We have now to consider the causes which could bring about such great
+extensions of the ice sheet as occurred in the last Glacial period.
+Here again we are upon the confines of geological knowledge, and in a
+field where there are no well-cleared ways for the understanding. In
+facing this problem, we should first note that those who are of the
+opinion that a Glacial period means a very cold climate in the regions
+where the ice attained its extension are probably in error. Natural as
+it may seem to look for exceeding cold as the cause of glaciation, the
+facts show us that we can not hold this view. In Siberia and in the
+parts of North America bordering on the Arctic Sea the average cold is
+so intense that the ground is permanently frozen--as it is, for
+instance, in the Klondike district--to the depth of hundreds of feet,
+only the surface thawing out during the warm summers. All this region
+is cold enough for glaciers, but there is not sufficient snowfall to
+maintain them. On the other hand, in Greenland, and in a less though
+conspicuous degree in Scandinavia, where the waters of the North
+Atlantic somewhat diminish the rigour of the cold, and at the same
+time bring about a more abundant snowfall, the two actions being
+intimately related, we have very extensive glaciers. Such facts, which
+could be very much extended, make it clear that the climate of glacial
+periods must have been characterized by a great snowfall, and not by
+the most intense cold.
+
+It is evident that what would be necessary again to envelop the boreal
+parts of North America with a glacial sheet would not be a
+considerable decrease of heat, but an increase in the winter's
+contribution of frozen water. Even if the heat released by this
+snowfall elevated the average temperature of the winter, as it
+doubtless would in a considerable measure, it would not melt off the
+snow. That snowfall tends to warm the air by setting free the heat
+which was engaged in keeping the water in a state of vapour is
+familiarly shown by the warming which attends an ordinary snowstorm.
+Even if the fall begin with a temperature of about 0° Fahr., the air
+is pretty sure to rise to near the freezing point.
+
+It is evident that no great change of temperature is required in order
+to bring about a very considerable increase in the amount of snowfall.
+In the ordinary succession of seasons we often note the occurrence of
+winters during which the precipitation of snow is much above the
+average, though it can not be explained by a considerable climatal
+change. We have to account for these departures from the normal
+weather by supposing that the atmospheric currents bring in more than
+the usual amount of moisture from the sea during the period when great
+falls of snow occur. In fact, in explaining variations in the humidity
+of the land, whether those of a constant nature or those that are to
+be termed accidental, we have always to look to those features which
+determine the importation of vapour from the great field of the ocean
+where it enters the air. We should furthermore note that these
+peculiarities of climate are dependent upon rather slight geographic
+accidents. Thus the snowfall of northern Europe, which serves to
+maintain the glaciation of that region, and, curiously enough, in some
+measure its general warmth, depends upon the movement of the Gulf
+Stream from the tropics to high latitudes. If by any geographical
+change, such as would occur if Central America were lowered so as to
+make a free passage for its waters to the westward, the glaciers of
+Greenland and of Scandinavia would disappear, and at the same time the
+temperature of those would be greatly lowered. Thus the most evident
+cause of glaciation must be sought in those alterations of the land
+which affect the movement of the oceanic currents.
+
+Applying this principle to the northern hemisphere, we can in a way
+imagine a change which would probably bring about a return of such an
+ice period as that from which the boreal realm is now escaping. Let us
+suppose that the region of not very high land about Bering Strait
+should sink down so as to afford the Kuro Siwo, or North Pacific
+equivalent of our Gulf Stream, an opportunity to enter the Arctic Sea
+with something like the freedom with which the North Atlantic current
+is allowed to penetrate to high latitudes. It seems likely that this
+Pacific current, which in volume and warmth is comparable to that of
+the Atlantic, would so far elevate the temperature of the arctic
+waters that their wide field would be the seat of a great evaporation.
+Noting once again the fact that the Greenland glaciers, as well as
+those of Norway, are supplied from seas warmed by the Gulf Stream, we
+should expect the result of this change would be to develop similar
+ice fields on all the lands near that ocean.
+
+Applying the data gathered by Dr. Croll for the Gulf Stream, it seems
+likely that the average annual temperature induced in the Arctic Sea
+by the free entrance of the Japan current would be between 20° and 30°
+Fahr. This would convert this wide realm of waters into a field of
+great evaporation, vastly increasing the annual precipitation. It
+seems also certain that the greater part of this precipitation would
+be in the form of snow. It appears to the writer that this cause alone
+may be sufficient to account for the last Glacial period in the
+northern hemisphere. As to the probability that the region about
+Bering Strait may have been lowered in the manner required by this
+view, it may be said that recent studies on the region about Mount St.
+Elias show that during or just after the ice epoch the shores in that
+portion of Alaska were at least four thousand feet lower than at
+present. As this is but a little way from the land which we should
+have to suppose to be lowered in order to admit the Japan current, we
+could fairly conclude that the required change occurred. As for the
+cause of the land movement, geologists are still in doubt. They know,
+however, that the attitudes of the land are exceedingly unstable, and
+that the shores rarely for any considerable time maintain their
+position. It is probable that these swayings of the earth's surface
+are due to ever-changing combinations of the weight in different parts
+of the crust and the strains arising from the contraction of its inner
+parts.
+
+In the larger operations of Nature the effects which we behold,
+however simple, are rarely the products of a single cause. In fact,
+there are few actions so limited that they can fairly be referred to
+one influence. It is therefore proper to state that there are many
+other actions besides those above noted which probably enter into
+those complicated equations which determine the climatal conditions of
+the earth. To have these would carry us into difficult and speculative
+inquiries.
+
+As before remarked, all the regions which have been subjected to
+glaciation are still each year brought temporarily into the glacial
+state. This fact serves to show us that the changes necessary to
+produce great ice sheets are not necessarily of a startling nature,
+however great the consequences may be. Assuming, then, that relatively
+slight alterations of climate may cause the ice sheet to come and go,
+we may say that all the influences which have been suggested by the
+students of glaciation, and various other slighter causes which can
+not be here noted, may have co-operated to produce the peculiar
+result. In this equation geographic change has affected the course of
+the ocean currents, and has probably been the most influential, or at
+least the commonest, cause to which we must attribute the extension of
+ice sheets. Next, alterations of the solar heat may be looked to as a
+change-bringing action; unfortunately, however, we have no direct
+evidence that this is an efficient cause. Thirdly, the variations in
+the eccentricity of the earth's orbit, combined with the precession of
+the equinoxes and the rotation of the apsides, may be regarded as
+operative. The last of all, changes in the constitution of the
+atmosphere, have to be taken into account. To these must be added, as
+before remarked, many less important actions which influence this
+marvellously delicate machine, the work of which is expressed in the
+phenomena assembled under the name of climate.
+
+Evidence is slowly accumulating which serves to show that glacial
+periods of greater or less importance have been of frequent occurrence
+at all stages in the history of the earth of which we have a distinct
+record. As these accidents write their history upon the ground alone,
+and in a way impermanently, it is difficult to trace the ice times of
+ancient geological periods. The scratches on the bed rocks, and the
+accumulations of detritus formed as the ice disappeared, have alike
+been worn away by the agents of decay. Nevertheless, we can trace here
+and there in the older strata accumulations of pebbly matter often
+containing large boulders, which clearly were shaped and brought
+together by glacial action. These are found in some instances far
+south of the region occupied by the glaciers during the last ice
+epoch. They occur in rocks of the Cambrian or Silurian age in eastern
+Tennessee and western North Carolina; they are also found in India
+beyond the limits to which glaciers have attained in modern times.
+
+In closing this inadequate account of glacial action, a story which
+for its complete telling would require many volumes, it is well for
+the reader to consider once again how slight are the changes of
+climate which may alternately withdraw large parts of the land from
+the uses of life, and again quickly restore the fields to the service
+of plants and animals. He may well imagine that these changes, by
+driving living creatures to and fro, profoundly affect the history of
+their development. This matter will be dealt with in the volume
+concerning the history of organic beings.
+
+When the ice went off from the northern part of this continent, the
+surface of the country, which had been borne down by the weight of the
+glacier, still remained depressed to a considerable depth below the
+level of the sea, the depression varying from somewhere about one
+hundred feet in southern New England to a thousand feet or more in
+high latitudes. Over this region, which lay beneath the level of the
+sea, the glacier, when it became thin enough to float, was doubtless
+broken up into icebergs, in the manner which we now behold along the
+coast of Greenland. Where the shore was swept by a strong current,
+these bergs doubtless drifted away; but along the most of the coast
+line they appear to have lain thickly grouped next the shores,
+gradually delivering their loads of stones and finer _débris_ to the
+bottom. These masses of floating ice in many cases seem to have
+prevented the sea waves from attaining the shore, and thus hindered
+the formation of those beaches which in their present elevated
+condition enable us to interpret the old position of the sea along
+coast lines which have been recently elevated. Here and there,
+however, from New Jersey to Greenland, we find bits of these ancient
+shores which clearly tell the story of that down-sinking of the land
+beneath the burden of the ice which is such an instructive feature in
+the history of that period.
+
+
+
+
+                          CHAPTER VII.
+
+                  THE WORK OF UNDERGROUND WATER.
+
+
+We have already noted two means by which water finds its way
+underground. The simplest and largest method by which this action is
+effected is by building in the fluid as the grains of the rock are
+laid down on the floors of seas or lakes. The water thus imprisoned is
+firmly inclosed in the interstices of the stone, it in time takes up
+into its mass a certain amount of the mineral materials which are
+contained in the deep-buried rocks. The other portion of the ground
+water--that with which we are now to be specially concerned--arises
+from the rain which descends into the crevices of the earth; it is
+therefore peculiar to the lands. For convenience we shall term the
+original embedded fluid _rock water_, and that which originates from
+the rain _crevice water_, the two forming the mass of the earth water.
+
+The crevice water of the earth, although forming at no time more than
+a very small fraction of the hidden fluid, is an exceedingly potent
+geological agent, doing work which, though unseen, yet affords the
+very foundations on which rest the life alike of land and sea. When
+this water enters the earth, though it is purified of all mineral
+materials, it has already begun to acquire a share of a gaseous
+substance, carbonic acid, or, as chemists now term it, carbon dioxide,
+which enables the fluid to begin its rôle of marvellous activities. In
+its descent as rain, probably even before it was gathered in drops in
+the cloud realm, the water absorbs a certain portion of this gas from
+the atmosphere. Entering the realm of the soil, where the decaying
+organic matter plentifully gives forth carbon dioxide, a further store
+of the gas is acquired. At the ordinary pressure of the air, water may
+take in many times its bulk of the gas.
+
+The immediate effect of carbonic acid when it is absorbed by water is
+greatly to increase the capacity which that fluid has for taking
+mineral matters into solution. When charged with this gas, in the
+measure in which it may be in the soil, water is able to dissolve
+about fifty times as much limestone as it can in its perfectly pure
+form take up. A familiar instance of this peculiar capacity which the
+gas gives may often be seen where the water from a soda-water fountain
+drips upon the marble slab beneath. In a few years this slab will be
+considerably corroded, though pure water would in the same time have
+had no effect upon it.
+
+The first and by far the most important effect of crevice water is
+exercised upon the soil, which is at once the product of this action,
+and the laboratory where the larger part of the work is done.
+Penetrating between the grains of the detrital covering, held in large
+quantities in the coating, and continually in slow motion, the
+gas-charged water takes a host of substances into solution, and brings
+them into a condition where they may react upon each other in the
+chemical manner. These materials are constantly being offered to the
+roots of plants and brought in contact with the underlying rock which
+has not passed into the state of soil. The changes induced in this
+stony matter lead to its breaking up, or at least to its softening to
+the point where the roots can penetrate it and complete its
+destruction. Thus it comes about that the water which to a great
+extent divides the rocks into the state of soil, which is continually
+wearing away the material on the surface, or leaching it out through
+the springs, is also at work in restoring the layer from beneath.
+
+The greater part of the water which enters the soil does not
+penetrate to any great depth in the underlying rocks, but finds its
+way to the surface after no long journey in the form of small springs.
+Generally those superficial springs do not emerge through distinct
+channels, but move, though slowly, in a massive way down the slopes
+until they enter a water course. Along the banks of any river, however
+small, or along the shores of the sea, a pit a few inches deep just
+above the level of the water will be quickly filled by a flow from
+this sheet which underlies the earth. At a distance from the stream
+this sheet spring is in contact with the bed rocks, and may be many
+feet below the surface, but it comes to the level of the river or the
+sea near their margins. Here and there the shape of the bed rocks,
+being like converging house roofs, causes the superficial springs to
+form small pipelike channels for the escape of their gathered waters,
+and the flow emerges at a definite point. Almost all these sources of
+considerable flow are due to the action of the water on the underlying
+rock, where we shall now follow that portion of the crevice water
+which penetrates deeply into the earth.
+
+Almost all rocks, however firm they may appear to be, are divided by
+crevices which extend from the soil level it may be to the depths of
+thousands of feet. These rents are in part due to the strains of
+mountain-building, which tend to disrupt the firmest stone, leaving
+open fractures. They are also formed in other ways, as by the
+imperfectly understood agencies which produce joint planes. It often
+happens that where rocks are highly tilted water finds its way
+downward between the layers, which are imperfectly soldered together,
+or a bed of coarse material, such as sandstone or conglomerate, may
+afford an easy way by which the water may descend for miles beneath
+the surface. Passing through rocks which are not readily soluble, the
+water, already to a great extent supplied with mineral matter by its
+journey through the soil, may not do much excavating work, and even
+after a long time may only slightly enlarge the spaces in which it
+may be stored or the channels by which it discharges to the surface.
+Hence it comes about that in many countries, even where the waters
+penetrate deeply, they do not afford large springs. It is otherwise
+where the crevice waters enter limestones composed of materials which
+are readily dissolved. In such places we find the rain so readily
+entering the underlying rock that no part of the fall goes at once to
+the brooks, but all has a long underground journey.
+
+In any limestone district where the beds of the material are thick and
+tolerably pure--as, for instance, in the cavern district of southern
+Kentucky--the traveller who enters the region notes at once that the
+usual small streams which in every region of considerable rainfall he
+is accustomed to see intersecting the surface of the country are
+entirely absent. In their place he notes everywhere pitlike
+depressions of bowl-shaped form, the sink holes to which we have
+already adverted. Through the openings in the bottom of these the rain
+waters descend into the depths of the earth. Although the most of
+these depressions have but small openings in their bottom, now and
+then one occurs with a vertical shaft sufficiently large to permit the
+explorer to descend into it, though he needs to be lowered down in the
+manner of a miner who is entering a shaft. In fact, the journey is
+nearly always one of some hazard; it should not be undertaken save
+with many precautions to insure safety.
+
+When one is lowered away through an open sink hole, though the descent
+may at first be somewhat tortuous, the explorer soon finds himself
+swinging freely in the air, it may be at a point some hundred feet
+above the base of the bottle-shaped shaft or dome into which he has
+entered. Commonly the neck of the bottle is formed where the water has
+worked its way through a rather sandy limestone, a rock which was not
+readily dissolved by the water. In the pure and therefore easily cut
+limestone layers the cavity rapidly expands until the light of the
+lantern may not disclose its walls. Farther down there is apt to be a
+shelf composed of another impure limestone, which extends off near the
+middle of the shaft. If the explorer can land upon this shelf, he is
+sure to find that from this imperfect floor the cavern extends off in
+one or more horizontal galleries, which he may follow for a great
+distance until he comes to the point where there is again a well-like
+opening through the hard layer, with another dome-shaped base beneath.
+Returning to the main shaft, the explorer may continue his descent
+until he attains the base of this vertical section of the cave, where
+he is likely to find himself delivered in a pool of water of no great
+depth, the bottom of which is occupied by a quantity of small, hard
+stones of a flinty nature, which have evidently come from the upper
+parts of the cavern. The close observer will have noted that here and
+there in the limestone there are flinty bits, such as those which he
+finds in the pool. From the bottom of the dome a determined inquirer
+can often make his way along the galleries which lead from that level,
+though it may be after a journey of miles to the point where he
+emerges from the cavern on the banks of an open-air river.
+
+Although a journey by way of the sink holes through a cavern system is
+to be commended for the reason that it is the course of the caverning
+waters, it is, on the whole, best to approach the cave through their
+exits along the banks of a stream or through the chance openings which
+are here and there made by the falling in of their roofs. One
+advantage of this cavity of entrance is that we can thus approach the
+cavern in times of heavy rain when the processes which lead to their
+construction are in full activity. Coming in this way to one of the
+domes formed beneath a sink hole, we may observe in rainy weather that
+the water falling down the deep shaft strikes the bottom with great
+force; in many of the Kentucky caves it falls from a greater height
+than Niagara. At such times the stones in the basin at the bottom of
+the shaft are vigorously whirled about, and in their motion they cut
+the rocks in the bottom of the basin--in fact, this cavity is a great
+pot hole, like those at the base of open-air cascades. It is now easy
+to interpret the general principles which determine the architecture
+of the cavern realm.
+
+When it first enters the earth all the work which the water does in
+the initial steps of cavern formation is effected by solution. As the
+crevice enlarges and deepens, the stream acquires velocity, and begins
+to use the bits of hard rock in boring. It works downward in this way
+by the mixed mechanical and chemical action until it encounters a hard
+layer. Then the water creeps horizontally through the soft stratum,
+doing most of its work by solution, until it finds a crevice in the
+floor through which it can excavate farther in the downward direction;
+so it goes on in the manner of steps until it burrows channels to the
+open stream. In time the vertical fall under the sink hole will cut
+through the hard layer, when the water, abandoning the first line of
+exit, will develop another at a lower level, and so in time it comes
+about that there may be several stories of the cave, the lowest being
+the last to be excavated. Of the total work thus done, only a small
+part is accomplished by the falling of the water, acting through the
+boring action of its tools, the bits of stone before mentioned; the
+principal part of the task is done by the solvent action of the
+carbonated waters on the limestone. In the system of caverns known as
+the Mammoth Cave, in Kentucky, the writer has estimated that at least
+nine tenths of the stone was removed in the state of solution.
+
+When first excavated, the chambers of a limestone cavern have little
+beauty to attract the eye. The curves of the walls are sometimes
+graceful, but the aspect of the chambers, though in a measure grand,
+is never charming. When, however, the waters have ceased to carve the
+openings, when they have been drained away by the formation of
+channels on a lower level, there commonly sets in a process known as
+stalactitization, which transforms the scene into one of singular
+beauty. We have already noted the fact that everywhere in ordinary
+rocks there are crevices through which water, moving under the
+pressure of the fluid which is above, may find its way slowly
+downward. In the limestone roofs of caverns, particularly in those of
+the upper story, this ooze of water passes through myriads of unseen
+fissures at a rate so slow that it often evaporates in the dry air
+without dropping to the floor. When it comes out of the rocks the
+water is charged with various salts of lime; when it evaporates it
+leaves the material behind on the roof. Where the outflow is so slight
+that the fluid does not gather into drops, it forms an incrustation of
+limy matter, which often gathers in beautiful flowerlike forms, or
+perhaps in the shape of a sheet of alabaster. Where drops are formed,
+a small, pendent cone grows downward from the ceiling, over which the
+water flows, and on which it evaporates. This cone grows slowly
+downward until it may attain the floor of the chamber, which has a
+height of thirty feet or more. If all the water does not evaporate,
+that which trickles off the apex of the cone, striking on the floor,
+is splashed out into a thin sheet, so that it evaporates in a speedy
+manner, lays down its limestone, and thus builds another and ruder
+cone, which grows upward toward that which is pendent above it.
+Finally, they grow together, enlarged by the process which constructed
+them, until a mighty column may be formed, sculptured as if by the
+hands of a fantastic architect.
+
+[Illustration: Fig. 13.--Stalactites and stalagmites on roof and floor
+of a cavern. The arrows show the direction of the moving water.]
+
+All the while that subterranean streams are cutting the caverns
+downward the open-air rivers into which they discharge are deepening
+their beds, and thereby preparing for the construction of yet lower
+stories of caves. These open-air streams commonly flow in steep-sided,
+narrow valleys, which themselves were caves until the galleries became
+so wide that they could no longer support the roof. Thus we often find
+that for a certain distance the roof over a large stream has fallen
+in, so that the water flows in the open air. Then it will plunge
+under an arch and course, it may be, for some miles, before it again
+arrives at a place where the roof has disappeared, or perhaps attains
+a field occupied by rocks of another character, in which caverns were
+not formed. At places these old river caverns are abandoned by the
+streams, which find other courses. They form natural tunnels, which
+are not infrequently of considerable length. One such in southwestern
+Virginia has been made useful for a railway passing from one valley to
+another, thus sparing the expense of a costly excavation. Where the
+remnant of the arch is small, it is commonly known as a natural
+bridge, of which that in Rockbridge County, in Virginia, is a very
+noble example. Arches of this sort are not uncommon in many cavern
+countries; five such exist in Carter County, Kentucky, a district in
+the eastern part of that State which abounds in caverns, though none
+of them are of conspicuous height or beauty.[7]
+
+[Footnote 7: It is reported that one of these natural bridges of Carter
+County has recently fallen down. This is the natural end of these
+features. As before remarked, they are but the remnants of much more
+extensive roofs which the processes of decay have brought to ruin.]
+
+At this stage of his studies on cavern work the student will readily
+conceive that, as the surface of the country overlying the cave is
+incessantly wearing down, the upper stories of the system are
+continually disappearing, while new ones are forming at the present
+drainage level of the country. In fact, the attentive eye can in such
+a district find here and there evidences of this progressive
+destruction. Not only do the caves wear out from above, but their
+roofs are constantly falling to their floors, a process which is
+greatly aided by the growth of stalactites. Forming in the crevices or
+joints between the stones, these rock growths sometimes prize off
+great blocks. In other cases the weight of the pendent stalactite
+drags the ill-supported masses of the roof to the floor. In this way a
+gallery originally a hundred feet below the surface may work its way
+upward to the light of day. The entrance by which the Mammoth Cave is
+approached appears to have been formed in this manner, and at several
+points in that system of caverns the effect of this action may be
+distinctly observed.
+
+We must now go a step further on the way of subterranean water, and
+trace its action in the depths below the plane of ordinary caves,
+which, as we have noted, do not extend below the level of the main
+streams of the cavern district. The first group of facts to be
+attended to is that exhibited by artesian wells. These occur where
+rocks have been folded down into a basinlike form. It often happens
+that in such a basin the rocks of which it is composed are some of
+them porous, and others impervious to water, and that the porous
+layers outcrop on the high margins of the depression and have
+water-tight layers over them. These conditions can be well represented
+by supposing that we have two saucers, one within the other, with an
+intervening layer of sand which is full of water. If now we bore an
+opening in the bottom of the uppermost saucer, we readily conceive
+that the water will flow up through it. In Nature we often find these
+basins with the equivalent of the sandy layer in the model just
+described rising hundreds of feet above the valley, so that the
+artesian well, so named from the village of Artois, near Paris, where
+the first opening of this nature was made, may yield a stream which
+will mount upward, especially where piped, to a great height. At many
+places in the world it is possible by such wells to obtain a large
+supply of tolerably pure water, but in general it is found to contain
+too large a supply of dissolved mineral matter or sulphuretted gases
+to be satisfactory for domestic purposes. It may be well to note the
+fact that the greater part of the so-called artesian wells, or borings
+which deliver water to a height above the surface, are not true
+artesian sources, in that they do not send up the water by the action
+of gravitation, but under the influence of gaseous pressure.
+
+Where, as in the case of upturned porous beds, the crevice water
+penetrates far below the earth's surface or the open-air streams which
+drain the water away, the fluid acquires a considerable increase of
+temperature, on the average about one degree Fahrenheit for each
+eighty feet of descent. It may, indeed, become so heated that if it
+were at the earth's surface it would not only burst into steam with a
+vast explosive energy, but would actually shine in the manner of
+heated solids. As the temperature of water rises, and as the pressure
+on it increases, it acquires a solvent power, and takes in rocky
+matter in a measure unapproached at the earth's surface. At the depth
+of ten miles water beginning as inert rain would acquire the
+properties which we are accustomed to associate with strong acids.
+Passing downward through fissures or porous strata in the manner
+indicated in the diagram, the water would take up, by virtue of its
+heat and the gases it contained, a share of many mineral substances
+which we commonly regard as insoluble. Gold and even platinum--the
+latter a material which resists all acids at ordinary
+temperatures--enters into the solution. If now the water thus charged
+with mineral stores finds in the depths a shorter way to the surface
+than that which it descended, which may well happen by way of a deep
+rift in the rocks, it will in its ascent reverse the process which it
+followed on going down. It will deposit the several minerals in the
+order of their solubilities--that is, the last to be taken in will be
+the first to be crystallized on the walls of the fissure through which
+the upflow is taking place. The result will be the formation of a vein
+belonging to the variety known as fissure veins.
+
+[Illustration: Fig. 14.--Diagram of vein. The different shadings show
+the variations in the nature of the deposits.]
+
+A vein deposit such as we are considering may, though rarely, be
+composed of a single mineral. Most commonly we find the deposit
+arranged in a banded form in the manner indicated in the figure (see
+diagram 14). Sometimes one material will abound in the lower portions
+of the fissure and another in its higher parts, a feature which is
+accounted for by the progressive cooling and relinquishment of
+pressure to which the water is subjected on its way to the surface.
+With each decrement of those properties some particular substance goes
+out of the fluid, which may in the end emerge in the form of a warm or
+hot spring, the water of which contains but little mineral matter.
+Where, however, the temperature is high, some part of the deposit,
+even a little gold, may be laid down just about the spring in the
+deposits known as sinter, which are often formed at such places.
+
+In many cases the ore deposits are formed not only in the main channel
+of the fissure, but in all the crevices on either side of that way. In
+this manner, much as in the case of the growth of stalactitic matter
+between the blocks of stone in the roofs of a cavern, large fragments
+of rock, known as "horses," are often pushed out into the body of the
+vein. In some instances the growth of the vein appears to enlarge the
+fissure or place of the deposit as the accumulation goes on, the
+process being analogous to that by which a growing root widens the
+crevice into which it has penetrated. In other instances the fissure
+formed by the force has remained wide open, or at most has been but
+partly filled by the action of the water.
+
+It not infrequently happens that the ascending waters of hot springs
+entering limestones have excavated extensive caves far below the
+surface of the earth, these caverns being afterward in part filled by
+the ores of various metals. We can readily imagine that the water at
+one temperature would excavate the cavern, and long afterward, when at
+a lower heat, they might proceed to fill it in. At a yet later stage,
+when the surface of the country had worn down many thousands of feet
+below the original level, the mineral stores of the caverns may be
+brought near the surface of the earth. Some of the most important
+metalliferous deposits of the Cordilleras are found in this group of
+hot-water caverns. These caverns are essentially like those produced
+by cold water, with the exception of the temperature of the fluid
+which does the work and the opposite direction of the flow.
+
+In following crevice water which is free to obey the impulses of
+gravitation far down into the earth, we enter on a realm where the
+rock or construction water, that which was built into the stone at
+the time of its formation, is plentiful. Where these two groups of
+waters come in contact an admixture occurs, a certain portion of the
+rock water joining that in the crevices. Near the surface of the
+ground we commonly find that all the construction water has been
+washed out by this action. Yet if the rocks be compact, or if they
+have layers of a soft and clayey nature, we may find the construction
+water, even in very old deposits, remaining near the surface of the
+ground. Thus in the ancient Silurian beds of the Ohio Valley a boring
+carried a hundred feet below the level of the main rivers commonly
+discovers water which is clearly that laid down in the crevices of the
+material at the time when the rocks were formed in the sea. In all
+cases this water contains a certain amount of gases derived from the
+decomposition of various substances, but principally from the
+alteration of iron pyrite, which affords sulphuretted hydrogen. Thus
+the water is forced to the surface with considerable energy, and the
+well is often named artesian, though it flows by gas pressure on the
+principle of the soda-water fountain, and not by gravity, as in the
+case of true artesian wells.
+
+The passage between the work done by the deeply penetrating surface
+water and that due to the fluid intimately blended with the rock built
+into the mass at the time of its formation is obscure. We are,
+however, quite sure that at great depths beneath the earth the
+construction water acts alone not only in making veins, but in
+bringing about many other momentous changes. At a great depth this
+water becomes intensely heated, and therefore tends to move in any
+direction where a chance fissure or other accident may lessen the
+pressure. Creeping through the rocks, and moving from zones of one
+temperature to another, these waters bring about in the fine
+interstices chemical changes which lead to great alterations in the
+constitution of the rock material. It is probably in part to these
+slow driftings of rock water that beds originally made up of small,
+shapeless fragments, such as compose clay slates, sandstones, and
+limestones, may in time be altered into crystalline rocks, where there
+is no longer a trace of the original bits, all the matter having been
+taken to pieces by the process of dissolving, and reformed in the
+regular crystalline order. In many cases we may note how a crystal
+after being made has been in part dissolved away and replaced by
+another mineral. In fact, many of our rocks appear to have been again
+and again made over by the slow-drifting waters, each particular state
+in their construction being due to some peculiarity of temperature or
+of mineral contents which the fluid held. These metamorphic phenomena,
+though important, are obscure, and their elucidation demands some
+knowledge of petrographic science, that branch of geology which
+considers the principles of rock formation. They will therefore not be
+further considered in this work.
+
+
+                           VOLCANOES.
+
+Of old it was believed that volcanoes represented the outpouring of
+fluid rock which came forth from the central realm of the earth, a
+region which was supposed still to retain the liquid state through
+which the whole mass of our earth has doubtless passed. Recent
+studies, however, have brought about a change in the views of
+geologists which is represented by the fact that we shall treat
+volcanic phenomena in connection with the history of rock water.
+
+In endeavouring to understand the phenomena of volcanoes it is very
+desirable that the student should understand what goes on in a normal
+eruption. The writer may, therefore, be warranted in describing some
+observations which he had an opportunity to make at an eruption of
+Vesuvius in 1883, when it was possible to behold far more than can
+ordinarily be discerned in such outbreaks--in fact, the opportunity of
+a like nature has probably not been enjoyed by any other person
+interested in volcanic action. In the winter of 1882-'83 Vesuvius was
+subjected to a succession of slight outbreaks. At the time of the
+observations about to be noted the crater had been reduced to a cup
+about three hundred feet in diameter and about a hundred feet deep.
+The vertical shaft at the bottom, through which the outbursts were
+taking place, was about a hundred feet across. Taking advantage of a
+heavy gale from the northwest, it was practicable, notwithstanding the
+explosions, to climb to the edge of the crater wall. Looking down into
+the throat of the volcano, although the pit was full of whirling
+vapours and the heat was so great that the protection of a mask was
+necessary, it was possible to see something of what was going on at
+the moment of an explosion.
+
+The pipe of the volcano was full of white-hot lava. Even in a day of
+sunshine, which was only partly obscured by the vapours which hung
+about the opening, the heat of the lava made it very brilliant. This
+mass of fluid rock was in continuous motion, swaying violently up and
+down the tube. From four to six times a minute, at the moment of its
+upswaying, it would burst as by the explosion of a gigantic bubble.
+The upper portion of the mass was blown upward in fragments, the
+discharge being like that of shot from a fowling piece; the fragments,
+varying in size from small, shotlike bits to masses larger than a
+man's head, were shot up sometimes to the height of fifteen hundred
+feet above the point of ejection. The wind, blowing at the rate of
+about forty miles an hour, drove the falling bits of rock to the
+leeward, so that there was no considerable danger to be apprehended
+from them. Some seconds after the explosion they could be heard
+rattling down on the farther slope of the cone. Observations on the
+interval between the discharge and the fall of the fragments made it
+easy to compute the height to which they were thrown.
+
+At the moment when the lava in the pipe opened for the passage of the
+vapour which created the explosion the movement, though performed in
+a fraction of a second, was clearly visible. At first the vapour was
+colourless; a few score feet up it began to assume a faint, bluish
+hue; yet higher, when it was more expanded, the tint changed to that
+of steam, which soon became of the ordinary aspect, and gathered in
+swift-revolving clouds. The watery nature of the vapour was perfectly
+evident by its odour. Though commingled with sulphurous-acid gas, it
+still had the characteristic smell of steam. For a half hour it was
+possible to watch the successive explosions, and even to make rough
+sketches of the scene. Occasionally the explosions would come in quick
+succession, so that the lava was blown out of the tube; again, the
+pool would merely sway up and down in a manner which could be
+explained only by supposing that great bubbles of vapour were working
+their way upward toward the point where they could burst. Each of
+these bubbles probably filled a large part of the diameter of the
+pipe. In general, the phenomena recalled the escape of the jet from a
+geyser, or, to take a familiar instance, that of steam from the pipe
+of a high-pressure engine. When the heat is great, steam may often be
+seen at the mouth of the pipe with the same transparent appearance
+which was observed in the throat of the crater. In the cold air of the
+mountain the vapour was rapidly condensed, giving a rainbow hue in the
+clouds when they were viewed at the right angle. The observations were
+interrupted by the fact that the wind so far died away that large
+balls of the ejected lava began to fall on the windward side of the
+cone. These fragments, though cooled and blackened on their outside by
+their considerable journey up and down through the air, were still so
+soft that they splashed when they struck the surface of cinders.
+
+Watching the cone from a distance, one could note that from time to
+time the explosions, increasing in frequency, finally attained a point
+where the action appeared to be continuous. The transition was
+comparable to that which we may observe in a locomotive which, when it
+first gets under way, gives forth occasional jets of steam, but,
+slowly gaining speed, finally pours forth what to eye and ear alike
+seem to be a continuous outrush. All the evidence that we have
+concerning volcanic outbreaks corroborates that just cited, and is to
+the effect that the essence of the action consists in the outbreak of
+water vapour at a high temperature, and therefore endowed with very
+great expansive force. Along with this steam there are many other
+gases, which always appear to be but a very small part of the whole
+escape of a vaporous nature--in fact, the volcanic steam, so far as
+its chemical composition has been ascertained, has the composition
+which we should expect to find in rock water which had been forced out
+from the rock by the tensions that high temperature creates.
+
+Because of its conspicuous nature, the lava which flows from most
+volcanoes, or is blown out from them in the form of finely divided
+ash, is commonly regarded as the primary feature in a volcanic
+outbreak. Such is not really the case. Volcanic explosions may occur
+with very little output of fluid rock, and that which comes forth may
+consist altogether of the finely divided bits of rock to which we give
+the name of ash. In fact, in all very powerful explosions we may
+expect to find no lava flow, but great quantities of this finely
+divided rock, which when it started from the depths of the earth was
+in a fluid state, but was blown to pieces by the contained vapour as
+it approached the surface.
+
+If the student is so fortunate as to behold a flood of lava coming
+forth from the flanks of a volcano, he will observe that even at the
+very points of issue, where the material is white-hot and appears to
+be as fluid as water, the whole surface gives forth steam. On a still
+day, viewed from a distance, the path of a lava flow is marked by a
+dense cloud of this vapour which comes forth from it. Even after the
+lava has cooled so that it is safe to walk upon it, every crevice
+continues to pour forth steam. Years after the flowing has ceased, and
+when the rock surface has become cool enough for the growth of
+certain plants upon it, these crevices still yield steam. It is
+evident, in a word, that a considerable part of a lava mass, even
+after it escapes from the volcanic pipes, is water which is intimately
+commingled with the rock, probably lying between the very finest
+grains of the heated substance. Yet this lava which has come forth
+from the volcano has only a portion of the water which it originally
+contained; a large, perhaps the greater part, has gone forth in the
+explosive way through the crater. It is reasonably believed that the
+fluidity of lava is in considerable measure due to the water which it
+contains, and which serves to give the mass the consistence of paste,
+the partial fluidity of flour and rock grains being alike brought
+about in the same manner.
+
+So much of the phenomena of volcanoes as has been above noted is
+intended to show the large part which interstitial water plays in
+volcanic action. We shall now turn our attention again to the state of
+the deeply buried rock water, to see how far we may be able by it to
+account for these strange explosive actions. When sediments are laid
+down on the sea floor the materials consist of small, irregularly
+shaped fragments, which lie tumbled together in the manner of a mass
+of bricks which have been shot out of a cart. Water is buried in the
+plentiful interspaces between these bits of stone; as before remarked,
+the amount of this construction water varies. In general, it is at
+first not far from one tenth part of the materials. Besides the fluid
+contained in the distinct spaces, there is a share which is held as
+combined water in the intimate structure of the crystals, if such
+there be in the mass. When this water is built into the stone it has
+the ordinary temperature of the sea bottom. As the depositing actions
+continue to work, other beds are formed on the top of that which we
+are considering, and in time the layer may be buried to the depth of
+many thousand feet. There are reasons to believe that on the floors of
+the oceans this burial of beds containing water may have brought great
+quantities of fluid to the depth of twenty miles or more below the
+outer surface of the rocks.
+
+[Illustration: Fig. 15.--Flow of lava invading a forest. A tree in the
+distance is not completely burned, showing that the molten rock had
+lost much of its original heat.]
+
+The effect of deep burial is to increase the heat of strata. This
+result is accomplished in two different ways. The direct effect
+arising from the imposition of weight, that derived from the mass of
+stratified material, is, as we know, to bring about a down-sinking of
+the earth's crust. In the measure of this falling, heat is engendered
+precisely as it is by the falling of a trip-hammer on the anvil, with
+which action, as is well known, we may heat an iron bar to a high
+temperature. It is true that this down-sinking of the surface under
+weight is in part due to the compression of the rocks, and in part to
+the slipping away of the soft underpinning of more or less fluid rock.
+Yet further it is in some measure brought about by the wrinkling of
+the crust. But all these actions result in the conversion of energy of
+position into heat, and so far serve to raise the temperature of the
+rocks which are concerned in the movements. By far the largest source
+of heat, however, is that which comes forth from the earth's interior,
+and which was stored there in the olden day when the matter forming
+the earth gathered into the mass of our sphere. This, which we may
+term the original heat, is constantly flowing forth into space, but
+makes its way slowly, because of the non-conductive, or, as we may
+phrase it, the "blanketing" effect of the outer rock. The effect of
+the strata is the same as that exercised by the non-conductive
+coatings which are put on steam boilers. A more familiar comparison
+may be had from the blankets used for bedclothing. If on top of the
+first blanket we put a second, we keep warmer because the temperature
+of the lower one is elevated by the heat from our body which is held
+in. In the crust of the earth each layer of rock resists the outflow
+of heat, and each addition lifts the temperature of all the layers
+below.
+
+When water-bearing strata have been buried to the depth of ten miles,
+the temperature of the mass may be expected to rise to somewhere
+between seven hundred and a thousand degrees Fahrenheit. If the depth
+attained should be fifty miles, it is likely that the temperature will
+be five times as great. At such a heat the water which the rocks
+contain tends in a very vigorous way to expand and pass into the state
+of vapour. This it can not readily do, because of its close
+imprisonment; we may say, however, that the tendency toward explosion
+is almost as great as that of ignited gunpowder. Such powder, if held
+in small spaces in a mass of cast steel, could be fired without
+rending the metal. The gases would be retained in a highly compressed,
+possibly in a fluid form. If now it happens that any of the strain in
+the rocks such as lead to the production of faults produce fissures
+leading from the surface into this zone of heated water, the tendency
+of the rocks containing the fluid, impelled by its expansion, will be
+to move with great energy toward the point of relief or lessened
+pressure which the crevice affords. Where rocks are in any way
+softened, pressure alone will force them into a cavity, as is shown by
+the fact that beds of tolerably hard clay stones in deep coal mines
+may be forced into the spaces by the pressure of the rocks which
+overlie them--in fact, the expense of cutting out these in-creeping
+rocks is in some British mines a serious item in the cost of the
+product.
+
+The expansion of the water contained in the deep-lying heated rocks
+probably is by far the most efficient agent in urging them toward the
+plane of escape which the fissure affords. When the motion begins it
+pervades all parts of the rock at once, so that an actual flow is
+induced. So far as the movement is due to the superincumbent weight,
+the tendency is at once to increase the temperature of the moving
+mass. The result is that it may be urged into the fissure perhaps even
+hotter than when it started from the original bed place. In proportion
+as the rocky matter wins its way toward the surface, the pressure upon
+it diminishes, and the contained vapours are freer to expand. Taking
+on the vaporous form, the bubbles gather to each other, and when they
+appear at the throat of the volcano they may, if the explosions be
+infrequent, assume the character above noted in the little eruption of
+Vesuvius. Where, however, the lava ascends rapidly through the
+channel, it often attains the open air with so much vapour in it, and
+this intimately mingled with the mass, that the explosion rends the
+materials into an impalpably fine powder, which may float in the air
+for months before it falls to the earth. With a less violent movement
+the vapour bubbles expand in the lava, but do not rend it apart, thus
+forming the porous, spongy rock known as pumice. With a yet slower
+ascent a large part of the steam may go away, so that we may have a
+flow of lava welling forth from the vent, still giving forth steam,
+but with a vapour whose tension is so lowered that the matter is not
+blown apart, though it may boil violently for a time after it escapes
+into the air.
+
+Although the foregoing relatively simple explanation of volcanic
+action can not be said as yet to be generally accepted by geologists,
+the reasons are sufficient which lead us to believe that it accounts
+for the main features which we observe in this class of explosions--in
+other words, it is a good working hypothesis. We shall now proceed in
+the manner which should be followed in all natural inquiry to see if
+the facts shown in the distribution of volcanoes in space and time
+confirm or deny the view.
+
+The most noteworthy feature in the distribution of volcanoes is that,
+at the present time at least, all active vents are limited to the sea
+floors or to the shore lands within the narrow range of three hundred
+miles from the coast. Wherever we find a coast line destitute of
+volcanoes, as is the case with the eastern coast of North and South
+America, it appears that the shore has recently been carried into the
+land for a considerable distance--in other words, old coast lines are
+normally volcanic; that is, here and there have vents of this nature.
+Thus the North Atlantic, the coasts of which appear to have gone
+inland for a great distance in geologically recent times, is
+non-volcanic; while the Pacific coast, which for a long time has
+remained in its present position, has a singularly continuous line of
+craters near the shore extending from Alaska to Tierra del Fuego. So
+uninterrupted is this line of volcanoes that if they were all in
+eruption it would very likely be possible to journey down the coast
+without ever being out of sight of the columns of vapour which they
+would send forth. On the floor of the sea volcanic peaks appear to be
+very widely distributed; only a few of them--those which attain the
+surface of the water--are really known, but soundings show long lines
+of elevations which doubtless represent cones distributed along fault
+lines, none of the peaks of sufficient height to break the surface of
+the sea. It is likely, indeed, that for one marine volcano which
+appears as an island there are scores which do not attain the surface.
+Volcanic islands exist and generally abound in the ocean and greater
+seas; every now and then we observe a new one forming as a small
+island, which is apt to be washed away by the sea shortly after the
+eruption ceases, the disappearance being speedy, for the reason that
+the volcanic ashes of which these cones are composed drift away like
+snow before the movement of the waves.
+
+If the waters of the ocean and seas were drained away so that we could
+inspect the portion of the earth's surface which they cover as readily
+as we do the dry lands, the most conspicuous feature would be the
+innumerable volcanic eminences which lie hidden in these watery
+realms. Wherever the observer passed from the centres of the present
+lands he would note within the limits of those fields only mountains,
+much modified by river action; hills which the rivers had left in
+scarfing away the strata; and dales which had been carved out by the
+flowing waters. Near the shore lines of the vanished seas he would
+begin to find mountains, hills, and vales occasionally commingled with
+volcanic peaks, those structures built from the materials ejected from
+the vents. Passing the coast line to the seaward, the hills and dales
+would quickly disappear, and before long the mountains would vanish
+from his way, and he would gradually enter on a region of vast rolling
+plains beset by volcanic peaks, generally accumulated in long ranges,
+somewhat after the manner of mountains, but differing from those
+elevations not only in origin but in aspect, the volcanic set of peaks
+being altogether made up of conical, cup-topped elevations.
+
+A little consideration will show us that the fact of volcanoes being
+in the limit to the sea floors and to a narrow fringe of shore next
+certain ocean borders is reconcilable with the view as to their
+formation which we have adopted. We have already noted the fact that
+the continents are old, which implies that the parts of the earth
+which they occupy have long been the seats of tolerably continuous
+erosion. Now and then they have swung down partly beneath the sea, and
+during their submersion they received a share of sediments. But, on
+the whole, all parts of the lands except strips next the coast may be
+reckoned as having been subjected to an excess of wearing action far
+exceeding the depositional work. Therefore, as we readily see,
+underneath such land areas there has been no blanketing process going
+on which has served to increase the heat in the deep underlying rocks.
+On the contrary, it would be easy to show, and the reader may see it
+himself, that the progressive cooling of the earth has probably
+brought about a lowering of the temperature in all the section from
+the surface to very great depths, so that not only is the rock water
+unaffected by increase of heat, but may be actually losing
+temperature. In other words, the conditions which we assume bring
+about volcanic action do not exist beneath the old land.
+
+Beneath the seas, except in their very greatest depths, and perhaps
+even there, the process of forming strata is continually going on.
+Next the shores, sometimes for a hundred or two miles away to seaward,
+the principal contribution may be the sediment worn from the lands by
+the waves and the rivers. Farther away it is to a large extent made up
+of the remains of animals and plants, which when dying give their
+skeletons to form the strata. Much of the materials laid down--perhaps
+in all more than half--consist of volcanic dust, ashes, and pumice,
+which drifts very long times before it finds its way to the bottom. We
+have as yet no data of a precise kind for determining the average rate
+of accumulation of sediments upon the sea floor, but from what is
+known of the wearing of the lands, and the amount of volcanic waste
+which finds its way to the seas, it is probably not less than about a
+foot in ten thousand years; it is most likely, indeed, much to exceed
+this amount. From data afforded by the eruptions in Java and in other
+fields where the quantity of volcanic dust contributed to the seas can
+be estimated, the writer is disposed to believe that the average rate
+of sedimentation on the sea floors is twice as great as the estimate
+above given.
+
+Accumulating at the average rate of one foot in ten thousand years, it
+would require a million years to produce a hundred feet of sediments;
+a hundred million to form ten thousand feet, and five hundred million
+to create the thickness of about ten miles of bed. At the rate of two
+feet in ten thousand years, the thickness accumulated would be about
+twenty miles. When we come to consider the duration of the earth's
+geologic history, we shall find reasons for believing that the
+formation of sediment may have continued for as much as five hundred
+million years.
+
+The foregoing inquiries concerning the origin of volcanoes show that
+at the present time they are clearly connected with some process which
+goes on beneath the sea. An extension of the inquiry indicates that
+this relation has existed in earlier geological times; for, although
+the living volcanoes are limited to places within three hundred miles
+of the sea, we find lava flows, ashes, and other volcanic
+accumulations far in the interior of the continents, though the energy
+which brought them forth to the earth's surface has ceased to operate
+in those parts of the land. In these cases of continental volcanoes it
+generally, if not always, appears that the cessation of the activity
+attended the removal of the shore line of the ocean or the
+disappearance of great inland seas. Thus the volcanoes of the
+Yellowstone district may have owed their activity to the immense
+deposits of sediment which were formed in the vast fresh-water lakes
+which during the later Cretaceous and early Tertiary times stretched
+along the eastern face of the Rocky Mountains, forming a Mediterranean
+Sea in North America comparable to that which borders southern Europe.
+It thus appears that the arrangement of volcanoes with reference to
+sea basins has held for a considerable period in the past. Still
+further, when we look backward through the successive formations of
+the earth's crust we find here and there evidences in old lava flows,
+in volcanic ashes, and sometimes in the ruins of ancient cones which
+have been buried in the strata, that igneous activity such as is now
+displayed in our volcanoes has been, since the earliest days of which
+we have any record, a characteristic feature of the earth. There is no
+reason to suppose that this action has in the past been any greater or
+any less than in modern days. All these facts point to the conclusion
+that volcanic action is due to the escape of rock water which has been
+heated to high temperatures, and which drives along with it as it
+journeys toward a crevice the rock in which it has been confined.
+
+We will now notice some other explanations of volcanic action which
+have obtained a certain credence. First, we may note the view that
+these ejections from craters are forced out from a supposed liquid
+interior of the earth. One of the difficulties of this view is that we
+do not know that the earth's central parts are fluid--in fact, many
+considerations indicate that such is not the case. Next, we observe
+that we not infrequently find two craters, each containing fluid lava,
+with the fluid standing at differences of height of several thousand
+feet, although the cones are situated very near each other. If these
+lavas came from a common internal reservoir, the principles which
+control the action of fluids would cause the lavas to be at the same
+elevation. Moreover, this view does not provide any explanation of the
+fact that volcanoes are in some way connected with actions which go on
+on the floors of great water basins. There is every reason to believe
+that the fractures in the rocks under the land are as numerous and
+deep-going as those beneath the sea. If it were a mere question of
+access to a fluid interior, volcanoes should be equally distributed on
+land and sea floors. Last of all, this explanation in no wise accounts
+for the intermixture of water with the fluid rock. We can not well
+believe that water could have formed a part of the deeper earth in the
+old days of original igneous fusion. In that time the water must have
+been all above the earth in the vaporous state.
+
+Another supposition somewhat akin to that mentioned is that the water
+of the seas finds its way down through crevices beneath the floors of
+the ocean, and, there coming in contact with an internal molten mass,
+is converted into steam, which, along with the fluid rock, escapes
+from the volcanic vent. In addition to the objections urged to the
+preceding view, we may say concerning this that the lava, if it came
+forth under these circumstances, would emerge by the short way, that
+by which the water went down, and not by the longer road, by which it
+may be discharged ten thousand feet or more above the level of the
+sea.
+
+The foregoing general account of volcanic action should properly be
+followed by some account of what takes place in characteristic
+eruptions. This history of these matters is so ample that it would
+require the space of a great encyclopædia to contain them. We shall
+therefore be able to make only certain selections which may serve to
+illustrate the more important facts.
+
+By far the best-known volcanic cone is that of Vesuvius, which has
+been subjected to tolerably complete record for about twenty-four
+hundred years. About 500 B.C. the Greeks, who were ever on the search
+for places where they might advantageously plant colonies, settled on
+the island of Ischia, which forms the western of what is now termed
+the Bay of Naples. This island was well placed for tillage as well as
+for commerce, but the enterprising colonists were again and again
+disturbed by violent outbreaks of one or more volcanoes which lie in
+the interior of this island; at one time it appears that the people
+were driven away by these explosions.
+
+In these pre-Christian days Vesuvius, then known as Monte Somma, was
+not known to be a volcano, it never having shown any trace of
+eruption. It appeared as a regularly shaped mountain, somewhat over
+two thousand feet high, with a central depression about three miles in
+diameter at the top, and perhaps two miles over at the bottom, which
+was plainlike in form, with some lakes of bitter water in the centre.
+The most we know of this central cavity is connected with the
+insurrection of the slaves led by Spartacus, the army of the revolters
+having camped for a time on the plain encircled by the crater walls.
+The outer slopes of the mountain afforded then a remarkably fertile
+soil; some traces, indeed, of the fertility have withstood the modern
+eruptions which have desolated its flanks. This wonderful Bay of
+Naples became the seat of the fairest Roman culture, as well as of a
+very extended commerce. Toward the close of the first century of our
+era the region was perhaps richer, more beautifully cultivated, and
+the seat of a more elaborate luxury than any part of the shore line of
+Europe at the present day. At the foot of the mountain, on the eastern
+border of the bay, the city of Pompeii, with a population of about
+fifty thousand souls, was a considerable port, with an extensive
+commerce, particularly with Egypt. The charming town was also a place
+of great resort for rich Egyptians who cared to dwell in Europe. On
+the flanks of the mountain there was at least one large town,
+Herculaneum, which appears to have been an association of rich men's
+residences. On the eastern side of the bay, at a point now known as
+Baiæ, the Roman Government had a naval station, which in the year 79
+was under the command of the celebrated Pliny, a most voluminous
+though unscientific writer on matters of natural history. With him in
+that year there was his nephew, commonly known as the younger Pliny,
+then a student of eighteen years, but afterward himself an author.
+These facts are stated in some detail, for they are all involved in
+the great tragedy which we are now to describe.
+
+For many years there had been no eruption about the Bay of Naples. The
+volcanoes on Ischia had been still for a century or more, and the
+various circular openings on the mainland had been so far quiet that
+they were not recognised as volcanoes. Even the inquisitive Pliny,
+with his great learning, was so little of a geologist that he did not
+know the signs which indicate the seat of volcanic action, though they
+are among the most conspicuous features which can meet the eye. The
+Greeks would doubtless have recognised the meaning of these physical
+signs. In the year 63 the shores of the Bay of Naples were subjected
+to a distinctive earthquake. Others less severe followed in subsequent
+years. In an early morning in the year 79, a servant aroused the elder
+Pliny at Baiæ with the news that there was a wonderful cloud rising
+from Monte Somma. The younger Pliny states that in form it was like a
+pine tree, the common species in Italy having a long trunk with a
+crown of foliage on its summit, shaped like an umbrella. This crown of
+the column grew until it spread over the whole landscape, darkening
+the field of view. Shortly after, a despatch boat brought a message to
+the admiral, who at once set forth for the seat of the disturbance. He
+invited his nephew to accompany him, but the prudent young man relates
+in his letters to Tacitus, from whom we know the little concerning the
+eruption which has come down to us, that he preferred to do some
+reading which he had to attend to. His uncle, however, went straight
+forward, intending to land at some point on the shore at the foot of
+the cone. He found the sea, however, so high that a landing was
+impossible; moreover, the fall of rock fragments menaced the ship. He
+therefore cruised along the shore for some distance, landing at a
+station probably near the present village of Castellamare. At this
+point the fall of ashes and pumice was very great, but the sturdy old
+Roman had his dinner and slept after it. There is testimony that he
+snored loudly, and was aroused only when his servants began to fear
+that the fall of ashes and stones would block the way out of his
+bedchamber. When he came forth with his attendants, their heads
+protected by planks resting on pillows, he set out toward Pompeii,
+which was probably the place where he sought to land. After going some
+distance, the brave man fell dead, probably from heart disease; it is
+said that he was at the time exceedingly asthmatic. No sooner were his
+servants satisfied that the life had passed from his body than they
+fled. The remains were recovered after the eruption had ceased. The
+younger Pliny further relates that after his uncle left, the cloud
+from the mountain became so dense that in midday the darkness was that
+of midnight, and the earthquake shocks were so violent that wagons
+brought to the courtyard of the dwelling to bear the members of the
+household away were rolled this way and that by the quakings of the
+earth.
+
+Save for the above-mentioned few and unimportant details concerning
+the eruption, we have no other contemporaneous account. We have,
+indeed, no more extended story until Dion Cassius, writing long after
+the event, tells us that Herculaneum and Pompeii were overwhelmed; but
+he mixes his story with fantastic legends concerning the appearance of
+gods and demons, as is his fashion in his so-called history. Of all
+the Roman writers, he is perhaps the most untrustworthy. Fortunately,
+however, we have in the deposits of ashes which were thrown out at the
+time of this great eruption some basis for interpreting the events
+which took place. It is evident that for many hours the Vesuvian
+crater, which had been dormant for at least five hundred years, blew
+out with exceeding fury. It poured forth no lava streams; the energy
+of the uprushing vapours was too great for that. The molten rock in
+their path was blown into fine bits, and all the hard material cast
+forth as free dust. In the course of the eruption, which probably did
+not endure more than two days, possibly not more than twenty-four
+hours, ash enough was poured forth to form a thick layer which spread
+far over the neighbouring area of land and sea floor. It covered the
+cities of Herculaneum and Pompeii to a depth of more than twenty feet,
+and over a circle having a diameter of twenty miles the average
+thickness may have been something like this amount. So deep was it
+that, although almost all the people of these towns survived, it did
+not seem to them worth while to undertake to excavate their dwelling
+places. At Pompeii the covering did not overtop the higher of the low
+houses. An amount of labour which may be estimated at not over one
+thirtieth of the value, or at least the cost which had been incurred
+in building the city, would have restored it to a perfectly
+inhabitable state. The fact that it was utterly abandoned probably
+indicates a certain superstitious view in connection with the
+eruption.
+
+The fact that the people had time to flee from Herculaneum and
+Pompeii, bearing with them their more valuable effects, is proved by
+the excavations at these places which have been made in modern times.
+The larger part of Pompeii and a considerable portion of Herculaneum
+have been thus explored; only rarely have human remains been found.
+Here and there, particularly in the cellars, the labourers engaged in
+the work of disinterring the cities note that their picks enter a
+cavity; examining the space, they find they have discovered the
+remains of a human skeleton. It has recently been learned that by
+pouring soft plaster of Paris into these openings a mould may be
+obtained which gives in a surprisingly perfect manner the original
+form of the body. The explanation of this mould is as follows: Along
+with the fall of cinders in an eruption there is always a great
+descent of rain, arising from the condensation of the steam which
+pours forth from the volcano. This water, mingling with the ashes,
+forms a pasty mud, which often flows in vast streams, and is
+sometimes known as mud lava. This material has the qualities of
+cement--that is, it shortly "sets" in a manner comparable to plaster
+of Paris or ordinary mortar. During the eruption of 79 this mud
+penetrated all the low places in Pompeii, covering the bodies of the
+people, who were suffocated by the fumes of the volcanic emanations.
+We know that these people were not drowned by the inundation; their
+attitudes show that they were dead before the flowing matter
+penetrated to where they lay.
+
+It happened that Pompeii lay beyond the influence of the subsequent
+great eruptions of Vesuvius, so that it afterward received only slight
+ash showers. Herculaneum, on the other hand, has century by century
+been more and more deeply buried until at the present time it is
+covered by many sheets of lava. This is particularly to be regretted,
+for the reason that, while Pompeii was a seaport town of no great
+wealth or culture, Herculaneum was the residence place of the gentry,
+people who possessed libraries, the records of which can be in many
+cases deciphered, and from which we might hope to obtain some of the
+lost treasures of antiquity. The papyrus rolls on which the books of
+that day were written, though charred by heat and time, are still
+interpretable.
+
+After the great explosion of 79, Vesuvius sank again into repose. It
+was not until 1056 that vigorous eruptions again began. From time to
+time slight explosions occurred, none of which yielded lava flows; it
+was not until the date last mentioned that this accompaniment of the
+eruption began to appear. In 1636, after a repose of nearly a century
+and a half, there came a very great outbreak, which desolated a wide
+extent of country on the northwestern side of the cone. At this stage
+in the history of the crater the volcanic flow began to attain the
+sea. Washing over the edge of the old original crater of Monte Somma,
+and thus lowering its elevation, these streams devastated, during the
+eruption just mentioned and in various other outbreaks, a wide field
+of cultivated land, overwhelming many villages. The last considerable
+eruption which yielded large quantities of lava was that of 1872,
+which sent its tide for a distance of about six miles.
+
+Since 1636 the eruptions of Vesuvius have steadily increased in
+frequency, and, on the whole, diminished in violence. In the early
+years of its history the great outbreaks were usually separated by
+intervals of a century or more, and were of such energy that the lava
+was mostly blown to dust, forming clouds so vast that on two occasions
+at least they caused a midnight darkness at Constantinople, nearly
+twelve hundred miles away. This is as if a volcano at Chicago should
+completely hide the sun in the city of Boston. In the present state of
+Vesuvius, the cone may be said to be in slight, almost continuous
+eruption. The old central valley which existed before the eruption of
+79, and continued to be distinct for long after that time, has been
+filled up by a smaller cone, bearing a relatively tiny crater of vent,
+the original wall being visible only on the eastern and northern parts
+of its circuit, and here only with much diminished height. On the
+western face the slope from the base of the mountain to the summit of
+the new cone is almost continuous, though the trained eye can trace
+the outline of Monte Somma--its position in a kind of bench, which is
+traceable on that side of the long slope leading from the summit of
+the new cone to the sea. The fact that the lavas of Vesuvius have
+broken out on the southwestern side, while the old wall of the cone
+has remained unbroken on the eastern versant, has a curious
+explanation. The prevailing wind of Naples is from the southwest,
+being the strong counter trades which belong in that latitude. In the
+old days when the Monte Somma cone was constructed these winds caused
+the larger part of the ashes to fall on the leeward side of the cone,
+thus forming a thicker and higher wall around that part of the crater.
+
+From the nature of the recent eruptions of Vesuvius it appears likely
+that the mountain is about to enter on a second period of inaction.
+The pipes leading through the new cone are small, and the mass of this
+elevation constitutes a great plug, closing the old crater mouth. To
+give vent to a large discharge of steam, the whole of this great mass,
+having a depth of nearly two thousand feet, would have to be blown
+away. It seems most likely that when the occasion for such a discharge
+comes, the vapours of the eruption will seek a vent through some other
+of the many volcanic openings which lie to the westward of this great
+cone. The history of these lesser volcanoes points to the conclusion
+that when the path by way of Vesuvius is obstructed they may give
+relief to the steam which is forcing its course to the surface. Two or
+three times since the eruption of Pliny, during periods when Vesuvius
+had long been quiet, outbreaks have taken place on Ischia or in the
+Phlægræn Fields, a region dotted with small craters which lies to the
+west of Naples. The last of these occurred in 1552, and led to the
+formation of the beautiful little cone known as Monte Nuovo. This
+eruption took place near the town of Puzzuoli, a place which was then
+the seat of a university, the people of which have left us records of
+the accident.
+
+[Illustration: Fig. 16.--Diagrammatic sections through Mount Vesuvius,
+showing changes in the form of the cone. (From Phillips.)]
+
+The outbreak which formed Monte Nuovo was slight but very
+characteristic. It occurred in and beside a circular pool known as the
+Lucrine Lake, itself an ancient crater. At the beginning of the
+disturbance the ground opened in ragged cavities, from which mud and
+ashes and great fragments of hard rock were hurled high in the air,
+some of the stones ascending to a height of several thousand feet.
+With slight intermissions this outbreak continued for some days,
+resulting in the formation of a hill about five hundred feet high,
+with a crater in its top, the bottom of which lay near the level of
+the sea. Although this volcanic elevation, being made altogether of
+loose fragments, is rapidly wearing down, while the crater is filling
+up, it remains a beautiful object in the landscape, and is also
+noteworthy for the fact that it is the only structure of this nature
+which we know from its beginning. In the Phlægræn Field there are a
+number of other craters of small size, with very low cones about them.
+These appear to have been the product of brief, slight eruptions. That
+known as the Solfatara, though not in eruption during the historic
+period, is interesting for the fact that from the crevices of the
+rocks about it there comes forth a continued efflux of carbonic-acid
+gas. This substance probably arises from the effect of heat contained
+in old lavas which are in contact with limestone in the deep
+under-earth. We know such limestones are covered by the lavas of
+Vesuvius, for the reason that numerous blocks of the rock are thrown
+out during eruptions, and are often found embedded in the lava
+streams. It is an interesting fact that these craters of the
+Phlægræn Field, lying between the seats of vigorous eruption on
+Ischia and at Vesuvius, have never been in vigorous eruption. Their
+slight outbreaks seem to indicate that they have no permanent
+connection with the sources whence those stronger vents obtain their
+supply of heated steam.
+
+The facts disclosed by the study of the Vesuvian system of volcanoes
+afford the geologist a basis for many interesting conclusions.
+
+In the first place, he notes that the greater part of the cones, all
+those of small size, are made up of finely divided rock, which may
+have been more or less cemented by the processes of change which
+go on within it. It is thus clear that the lava flows are
+unessential--indeed, we may say accidental--contributions to the mass.
+In the case of Vesuvius they certainly do not amount to as much as one
+tenth of the elevation due to the volcanic action. The share of the
+lava in Vesuvius is probably greater than the average, for during the
+last six centuries this vent has been remarkably lavigerous.[8]
+Observation on the volcanoes of other districts show that the Vesuvian
+group is in this regard not peculiar. Of nearly two hundred cones
+which the writer has examined, not more than one tenth disclose
+distinct lavas.
+
+[Footnote 8: I venture to use this word in place of the phrase
+"lava-yielding" for the reason that the term is needed in the
+description of volcanoes.]
+
+An inspection of the old inner wall of Monte Somma in that portion
+where it is best preserved, on the north side of the Atria del
+Cavallo, or Horse Gulch--so called for the reason that those who
+ascended Vesuvius were accustomed to leave their saddle animals
+there--we perceive that the body of the old cone is to a considerable
+extent interlaced with dikes or fissures which have been filled with
+molten lava that has cooled in its place. It is evident that during
+the throes of an eruption, when the lava stands high in the crater,
+these rents are frequently formed, to be filled by the fluid rock. In
+fact, lava discharges, though they may afterward course for long
+distances in the open air, generally break their way underground
+through the cindery cone, and first are disclosed at the distance of a
+mile or more from the inner walls of the crater. Their path is
+probably formed by riftings in the compacted ashes, such as we trace
+on the steep sides of the Atria del Cavallo, as before noted. For the
+further history of these fissures, we shall have to refer to facts
+which are better exhibited in the cone of Ætna.
+
+The amount of rock matter which has been thrown forth from the
+volcanoes about the Bay of Naples is very great. Only a portion of it
+remains in the region around these cones; by far the greater part has
+been washed or blown away. After each considerable eruption a wide
+field is coated with ashes, so that the tilled grounds appear as if
+entirely sterilized; but in a short time the matter in good part
+disappears, a portion of it decays and is leached away, and the most
+of the remainder washes into the sea. Only the showers, which
+accumulate a deep layer, are apt to be retained on the surface of the
+country. A great deal of this powdered rock drifts away in the wind,
+sometimes in great quantities, as in those cases where it darkened the
+sky more than a thousand miles from the cone. Moreover, the water of
+the steam which brought about the discharges and the other gases which
+accompanied the vapour have left no traces of their presence, except
+in the deep channels which the rain of the condensing steam have
+formed on the hillsides. Nevertheless, after all these subtractions
+are made, the quantity of volcanic matter remaining on the surface
+about the Bay of Naples would, if evenly distributed, form a layer
+several hundred feet in thickness--perhaps, indeed, a thousand feet in
+depth--over the territory in which the vents occur. All this matter
+has been taken in relatively recent times from the depths of the
+earth. The surprising fact is that no considerable and, indeed, no
+permanent subsidence of the surface has attended this excavation. We
+can not believe that this withdrawal of material from the under-earth
+has resulted in the formation of open underground spaces. We know full
+well that any such, if it were of considerable size, would quickly be
+crushed in by the weight of the overlying rocks. We have, indeed, to
+suppose that these steam-impelled lavas, which are driven toward the
+vent whence they are to go forth in the state of dust or fluid, come
+underground from distances away, probably from beneath the floors of
+the sea to the westward.
+
+Although the shores of the Bay of Naples have remained in general with
+unchanged elevation for about two thousand years, they have here and
+there been subjected to slight oscillations which are most likely
+connected with the movement of volcanic matter toward the vents where
+it is to find escape. The most interesting evidence of this nature is
+afforded by the studies which have been made on the ruins of the
+Temple of Serapis at Puzzuoli. This edifice was constructed in
+pre-Christian times for the worship of the Egyptian god Serapis, whose
+intervention was sought by sick people. The fact that this divinity of
+the Nile found a residence in this region shows how intimate was the
+relation between Rome and Egypt in this ancient day. The Serapeium was
+built on the edge of the sea, just above its level. When in modern
+days it began to be studied, its floor was about on its original
+level, but the few standing columns of the edifice afford indubitable
+evidence that this part of the shore has been lowered to the amount of
+twenty feet or more and then re-elevated. The subsidence is proved by
+the fact that the upper part of the columns which were not protected
+by the _débris_ accumulated about them have been bored by certain
+shellfish, known as _Lithodomi_, which have the habit of excavating
+shelters in soft stone, such as these marble columns afford. At
+present the floor on which the ruin stands appears to be gradually
+sinking, though the rate of movement is very slow.
+
+Another evidence that the ejections may travel for a great distance
+underground on their way to the vent is afforded by the fact that
+Vesuvius and Ætna, though near three hundred miles apart, appear to
+exchange activities--that is, their periods of outbreak are not
+simultaneous. Although these elements of the chronology of the two
+cones may be accidental, taken with similar facts derived from other
+fields, they appear to indicate that vents, though far separated from
+each other, may, so to speak, be fed from a common subterranean
+source. It is a singular fact in this connection that the volcano of
+Stromboli, though situated between these two cones, is in a state of
+almost incessant activity. This probably indicates that the last-named
+vent derives its vapours from another level in the earth than the
+greater cones. In this regard volcanoes probably behave like springs,
+of which, indeed, they may be regarded as a group. The reader is
+doubtless aware that hot and cold springs often escape very near
+together, the difference in the temperature being due to the depth
+from which their waters come forth.
+
+As the accidents of volcanic explosion are of a nature to be very
+damaging to man, as well as to the lower orders of Nature, it is fit
+that we should note in general the effect of the Neapolitan eruptions
+on the history of civilization in that region. As stated above, the
+first Greek settlements in this vicinity--those on the island of
+Ischia--were much disturbed by volcanic outbreaks, yet the island
+became the seat of a permanent and prosperous colony. The great
+eruption of 79 probably cost many hundred lives, and led to the
+abandonment of two considerable cities, which, however, could at small
+cost have been recovered to use. Since that day various eruptions have
+temporarily desolated portions of the territory, but only in very
+small fields have the ravages been irremediable. Where the ground was
+covered with dust, it has in most places been again tillable, and so
+rapid is the decay of the lavas that in a century after their flow has
+ceased vines can in most cases be planted on their surfaces. The city
+of Naples, which lies amid the vents, though not immediately in
+contact with any of them, has steadfastly grown and prospered from the
+pre-Christian times. It is doubtful if any lives have ever been lost
+in the city in consequence of an eruption, and no great inconvenience
+has been experienced from them. Now and then, after a great ash
+shower, the volcanic dust has to be removed, but the labour is less
+serious than that imposed on many northern cities by a snowstorm.
+Through all these convulsions the tillage of the district has been
+maintained. It has ever been the seat of as rich and profitable a
+husbandry as is afforded by any part of Italy. In fact, the ash
+showers, as they import fine divided rock very rich in substances
+necessary for the growth of plants, have in a measure served to
+maintain the fertility of the soil, and by this action have in some
+degree compensated for the injury which they occasionally inflict.
+Comparing the ravages of the eruptions with those inflicted by war,
+unnecessary disease, or even bad politics, and we see that these
+natural accidents have been most merciful to man. Many a tyrant has
+caused more suffering and death than has been inflicted by these rude
+operations of Nature.
+
+From the point of view of the naturalist, Ætna is vastly more
+interesting than Vesuvius. The bulk of the cone is more than twenty
+times as great as that of the Neapolitan volcano, and the magnitude of
+its explosions, as well as the range of phenomena which they exhibit,
+incomparably greater. It happens, however, that while human history of
+the recorded kind has been intimately bound up with the tiny Vesuvian
+cone, partly because the relatively slight nature of its disturbances
+permitted men to dwell beside it, the larger Ætna has expelled culture
+from the field near its vent, and has done the greater part of its
+work in the vast solitude which it has created.[9]
+
+[Footnote 9: In part the excellent record of Vesuvius is due to the fact
+that since the early Christian centuries the priests of St. Januarius,
+the patron of Naples, have been accustomed to carry his relics in
+procession whenever an eruption began. The cessation of the outbreak has
+been written down to the credit of the saint, and thus we are provided
+with a long story of the successive outbreaks.]
+
+Ætna has been in frequent eruption for a very much longer time than
+Vesuvius. In the odes of Pindar, in the sixth century before Christ,
+we find records of eruptions. It is said also that the philosopher
+Empedocles sought fame and death by casting himself into the fiery
+crater. There has thus in the case of this mountain been no such long
+period of repose as occurred in Vesuvius. Though our records of the
+outbreaks are exceedingly imperfect, they serve to show that the vent
+has maintained its activity much more continuously than is ordinarily
+the case with volcanoes. Ætna is characteristically a lava-yielding
+cone; though the amount of dust put forth is large, the ratio of the
+fluid rock which flows away from the crater is very much greater than
+at Vesuvius. Nearly half the cone, indeed, may be composed of this
+material. Our space does not permit anything like a consecutive story
+of the Ætnean eruptions since the dawn of history, or even a full
+account of its majestic cone; we can only note certain features of a
+particularly instructive nature which have been remarked by the many
+able men who have studied this structure and the effects of its
+outbreak.
+
+The most important feature exhibited by Ætna is the vast size of its
+cone. At its apex its height, though variable from the frequent
+destruction and rebuilding of the crater walls, may be reckoned as
+about eleven thousand feet. The base on which the volcanic material
+lies is probably less than a thousand feet above the sea, so that the
+maximum thickness of the heap of volcanic ejections is probably about
+two miles. The average depth of this coating is probably about five
+thousand feet, and, as the cone has an average diameter of about
+thirty miles, we may conclude that the cone now contains about a
+thousand cubic miles of volcanic materials. Great as is this mass,
+it is only a small part of the ejected material which has gone forth
+from the vent. All the matter which in its vaporous state went forth
+with the eruption, the other gases and vapours thus discharged, have
+disappeared. So, too, a large part of the ash and much of the lava has
+been swept away by the streams which drain the region, and which in
+times of eruption are greatly swollen by the accompanying torrential
+rains. The writer has estimated that if all the emanations from the
+volcano--solid, fluid, and gaseous--could be heaped on the cone, they
+would form a mass of between two and three thousand cubic miles in
+contents. Yet notwithstanding this enormous outputting of earthy
+matter, the earth on which the Ætnean cone has been constructed has
+not only failed to sink down, but has been in process of continuous,
+slow uprising, which has lifted the surface more than a thousand feet
+above the level which it had at the time when volcanic action began in
+this field. Here, even more clearly than in the case of Vesuvius, we
+see that the materials driven forth from the crater are derived not
+from just beneath its foundation, but from a distance, from realms
+which in the case of this insular volcano are beneath the sea floors.
+It is certain that here the migration of rock matter, impelled by the
+expansion of its contained water toward the vent, has so far exceeded
+that which has been discharged through the crater that an uprising of
+the surface such as we have observed has been brought about.
+
+[Illustration: _Mount Ætna, seen from near Catania. The imperfect
+cones on the sky line to the left are those of small secondary
+eruptions._]
+
+There are certain peculiarities of Mount Ætna which are due in part to
+its great size and in part to the climatal conditions of the region in
+which it lies. The upper part of the mountain in winter is deeply
+snow-clad; the frozen water often, indeed, forms great drifts in the
+gorges near the summit. Here it has occasionally happened that a layer
+of ashes has deeply buried the mass, so that it has been preserved for
+years, becoming gradually more inclosed by the subsequent eruptions.
+At one point where this compact snow--which has, indeed, taken on the
+form of ice--has been revealed to view, it has been quarried and
+conveyed to the towns upon the seacoast. It is likely that there are
+many such masses of ice inclosed between the ash layers in the upper
+part of the mountain, where, owing to the height, the climate is very
+cold. This curious fact shows how perfect a non-conductor the ash beds
+of a volcano are to protect the frozen water from the heat of the
+rocks about the crater.
+
+The furious rains which beset the mountain in times of great eruptions
+excavate deep channels on its sides. The lava outbreaks which attend
+almost every eruption, and which descend from the base of the cinder
+cone at the height of from five to eight thousand feet above the sea,
+naturally find their way into these channels, where they course in the
+manner of rivers until the lower and less valleyed section of the cone
+is reached.
+
+Such a lava flow naturally begins to freeze on the surface, the lava
+at first becoming viscid, much in the manner of cream on the surface
+of milk. Urged along by the more fluid lava underneath, this viscid
+coating takes a ropy or corrugated form. As the freezing goes deeper,
+a firm stone roof may be formed across the gorge, which, when the
+current of lava ceases to flow from the crater, permits the lower part
+of the stream to drain away, leaving a long cavern or scries of caves
+extending far up the cone. The nature of this action is exactly
+comparable to that which we may observe when on a frosty morning after
+rain we may find the empty channels which were occupied by rills of
+water roofed over with ice; the ice roofs are temporary, while those
+of lava may endure for ages. Some of these lava-stream caves have been
+disclosed, in the manner of ordinary caverns, by the falling of their
+roofs; but the greater part are naturally hidden beneath the
+ever-increasing materials of the cone.
+
+The lava-stream caves of Ætna are not only interesting because of
+their peculiarities of form, which we shall not undertake to describe,
+but also for the reason that they help us to account for a very
+peculiar feature in the history of the great cone. On the slopes of
+the volcano, below the upper cindery portion, there are several
+hundred lesser cones, varying from a few score to seven hundred feet
+in height. Each of these has its appropriate crater, and has evidently
+been the seat of one or more eruptions. As the greater part of these
+cones are ancient, many of them being almost effaced by the rain or
+buried beneath the ejections which have surrounded their bases since
+the time they were formed, we are led to believe that many thousands
+of them have been formed during the history of the volcano. The
+history of these subsidiary cones appears to be connected with the
+lava caves noted above. These caverns, owing to the irregularities of
+their form, contain water. They are, in fact, natural cisterns, where
+the abundant rainfall of the mountain finds here and there storage.
+When, during the throes of an eruption, dikes such as we know often to
+penetrate the mountain, are riven outward from the crater through the
+mass of the cone, and filled with lava, the heated rock must often
+come in contact with these masses of buried water. The result of this
+would inevitably be the local generation of steam at a high
+temperature, which would force its way out in a brief but vigorous
+eruption, such as has been observed to take place when these
+peripheral volcanoes are formed. Sometimes it has happened that after
+the explosion the lava has found its way in a stream from the fissure
+thus opened. That this explanation is sufficient is in a measure shown
+by observations on certain effects of lava flows from Vesuvius. The
+writer was informed by a very judicious observer, a resident of
+Naples, who had interested himself in the phenomena of that volcano,
+that the lava streams when they penetrated a cistern, such as they
+often encounter in passing over villages or farmsteads, vaporized the
+water, and gave rise, through the action of the steam, to small
+temporary cones, which, though generally washed away by the further
+flow of the liquid rock, are essentially like those which we find on
+Ætna. Such subsidiary, or, as they are sometimes called, parasitic
+cones, are known about other volcanoes, but nowhere are they so
+characteristic as on the flanks of that wonderful volcano.
+
+A very conspicuous feature in the Ætnean cone consists of a great
+valley known as the Val del Bove, or Bull Hollow, which extends from
+the base of the modern and ever-changeable cinder cone down the flanks
+of the older structure to near its base. This valley has steep sides,
+in places a thousand or more feet high, and has evidently been formed
+by the down-settling of portions of the cone which were left without
+support by the withdrawal from beneath them of materials cast forth in
+a time of explosion. In an eruption this remarkable valley was the
+seat of a vast water flood, the fluid being cast forth from the crater
+at the beginning of the explosion. In the mouths of this and other
+volcanoes, after a long period of repose, great quantities of water,
+gathering from rains or condensed from the steam which slowly escapes
+from these openings, often pours like a flood down the sides of the
+mountains. In the great eruption of Galongoon, in Java, such a mass of
+water, cast forth by a terrific explosion, mingled with ashes, so that
+the mass formed a thick mud, was shot forth with such energy that it
+ravaged an area nearly eighty miles in diameter, destroying the
+forests and their wild inhabitants, as well as the people who dwelt
+within the range of the amazing disaster. So powerfully was this water
+driven from the crater that the districts immediately at the base of
+the cone were in a manner overshot by the vast stream, and escaped
+with relatively little injury.
+
+When it comes forth from the base of the cinder cone, or from one of
+the small peripheral craters, the lava stream usually appears to be
+white hot, and to flow with almost the ease of water. It does not
+really have that measure of fluidity; its condition is rather that of
+thin paste; but the great weight of the material--near two and a half
+times that of water--causes the movement down the slope to be speedy.
+The central portion of the lava stream long retains its high
+temperature; but the surface, cooling, is first converted into a tough
+sheet, which, though it may bend, can hardly be said to flow. Further
+hardening converts these outlying portions of the current into hard,
+glassy stone, which is broken into fragments in a way resembling the
+ice on the surface of a river. It thus comes about that the advancing
+front of the lava stream becomes covered, and its motion hindered by
+the frozen rock, until the rate of ongoing may not exceed a few feet
+an hour, and the appearance is that of a heap of stone slowly rolling
+down a slope. Now and then a crevice is formed, through which a thin
+stream of liquid lava pours forth, but the material, having already
+parted with much of its heat, rapidly cools, and in turn becomes
+covered with the coating of frozen fragments. In this state of the
+stream the lava flow stands on all sides high above the slope which it
+is traversing; it is, in fact, walled in by its own solidified parts,
+though it is urged forward by the contribution which continues to flow
+in the under arches. In this state of the movement trifling accidents,
+or even human interference, may direct the current this way or that.
+
+Some of the most interesting chapters in the history of Ætna relate to
+the efforts of the people to turn these slow-moving streams so that
+their torrents might flow into wilderness places rather than over the
+fields and towns. In the great flow of 1669, which menaced the city of
+Catania, a large place on the seashore to the southeast of the cone, a
+public-spirited citizen, Señor Papallardo, protecting himself and his
+servants with clothing made of hides, and with large shields, set
+forth armed with great hooks with the purpose of diverting the course
+of the lava mass. He succeeded in pulling away the stones on the
+flank of the stream, so that a flow of the molten rock was turned in
+another direction. The expedient would probably have been successful
+if he had been allowed to continue his labours; but the inhabitants of
+a neighbouring village, which was threatened by the off-shooting
+current which Papallardo had created, took up arms and drove him and
+his retainers away. The flow continued until it reached Catania. The
+people made haste to build the city walls on the side of danger higher
+than it was before, but the tide mounted over its summit.
+
+Although the lavas which come forth from the volcano evidently have a
+high temperature, their capacity for melting other rocks is relatively
+small. They scour these rocks, because of their weight, even more
+energetically than do powerful torrents of water, but they are
+relatively ineffective in melting stone. On Ætna and elsewhere we may
+often observe lavas which have flowed through forests. When the tide
+of molten rock has passed by, the trees may be found charred but not
+entirely burned away; even stems a few inches in diameter retain
+strength enough to uphold considerable fringes and clots of the lava
+which has clung to them. These facts bear out the conclusion that the
+fluidity of the heated stone depends in considerable measure on the
+water which is contained, either in its fluid or vaporous state,
+between the particles of the material.
+
+If we consider the Italian volcanoes as a whole, we find that they lie
+in a long, discontinuous line extending from the northern part of the
+valley of the Po, within sight of the Alps, to Ætna, and in
+subterranean cones perhaps to the northern coast of Africa. At the
+northern end of the line we have a beautiful group of extinct
+volcanoes, known as the Eugean Mountains. Thence southward to southern
+Tuscany craters are wanting, but there is evidence of fissures in the
+earth which give forth thermal waters. From southern Tuscany southward
+through Rome to Naples there are many extinct craters, none of which
+have been active in the historic period. From Naples southward the
+cones of this system, about a dozen in number, are on islands or close
+to the margin of the sea. It is a noteworthy fact that the greater
+part of these shore or insular vents have been active since the dawn
+of history; several of them frequently and furiously so, while none of
+those occupying an inland position have been the seat of explosions.
+This is a striking instance going to show the relation of these
+processes to conditions which are brought about on the sea bottom.
+
+Ætna is, as we have noticed, a much more powerful volcano than
+Vesuvius. Its outbreaks are more vigorous, its emanations vastly
+greater in volume, and the mass of its constructions many times as
+great as those accumulated in any other European cone. There are,
+however, a number of volcanoes in the world which in certain features
+surpass Ætna as much as that crater does Vesuvius. Of these we shall
+consider but two--Skaptar Jokul, of Iceland, remarkable for the volume
+of its lava flow, and Krakatoa, an island volcano between Java and
+Sumatra, which was the seat of the greatest explosion of which we have
+any record.
+
+The whole of Iceland may be regarded as a volcanic mass composed
+mainly of lavas and ashes which have been thrown up by a group of
+volcanoes lying near the northern end of the long igneous axis which
+extends through the centre of the Atlantic. The island has been the
+seat of numerous eruptions; in fact, since its settlement by the
+Northmen in 1070 its sturdy inhabitants have been almost as much
+distressed by the calamities which have come from the internal heat as
+they have been by the enduring external cold. They have, indeed, been
+between frost and fire. The greatest recorded eruption of Iceland
+occurred in 1783, when the volcano of Skaptar, near the southern
+border of the island, poured forth, first, a vast discharge of dust
+and ashes, and afterward in the languid state of eruption inundated a
+series of valleys with the greatest lava flow of which we have any
+written record. The dust poured forth into the upper air, being finely
+divided and in enormous quantity, floated in the air for months,
+giving a dusky hue to the skies of Europe, which led the common people
+and many of the learned to fear that the wrath of God was upon them,
+and that the day of judgment was at hand. Even the poet Cowper, a man
+of high culture and education, shared in this unreasonable view.
+
+The lava flow in this eruption filled one of the considerable valleys
+of the island, drying up the river, and inundating the plains on
+either side. Estimates which have been made as to the volume of this
+flow appear to indicate that it may have amounted to more than the
+bulk of the Mont Blanc.
+
+This great eruption, by the direct effect of the calamity, and by the
+famine due to the ravaging of the fields and the frightening of the
+fish from the shores which it induced, destroyed nearly one fifth of
+the Icelandic people. It is, in fact, to be remembered as one of the
+three or four most calamitous eruptions of which we have any account,
+and, from the point of view of lava flow, the greatest in history.
+
+Just a hundred years after the great Skaptar eruption, which darkened
+the skies of Europe, the island of Krakatoa, an isle formed by a small
+volcano in the straits of Java, was the seat of a vapour explosion
+which from its intensity is not only unparalleled, but almost
+unapproached in all accounts of such disturbances. Krakatoa had long
+been recognised as a volcanic isle; it is doubtful, however, if it had
+ever been seen in eruption during the three centuries or more since
+European ships began to sail by it until the month of May of the year
+above mentioned. Then an outbreak of what may be called ordinary
+violence took place, which after a few days so far ceased that
+observers landed and took account of the changes which the convulsion
+had brought about. For about three months there were no further signs
+of activity, but on the 29th of August a succession of vast explosions
+took place, which blew away a great part of the island, forming in its
+place a submarine crater two or three miles in diameter, creating
+world-wide disturbances of sea and air. The sounds of the outbreak
+were heard at a distance of sixteen hundred miles away. The waves of
+the air attendant on the explosion ran round the earth at least once,
+as was distinctly indicated by the self-recording barometers; it is
+possible, indeed, that, crossing each other in their east and west
+courses, these atmospheric tides twice girdled the sphere. In effect,
+the air over the crater was heaved up to the height of some tens of
+thousands of feet, and thence rolled off in great circular waves, such
+as may be observed in a pan of milk when a sharp blow pushes the
+bottom upward.
+
+The violent stroke delivered to the waters of the sea created a vast
+wave, which in the region where it originated rolled upon the shores
+with a surf wall fifty or more feet high. In a few minutes about
+thirty thousand people were overwhelmed. The wave rolled on beyond its
+destructive limits much in the manner of the tide; its influence was
+felt in a sharp rise and fall of the waters as far as the Pacific
+coast of North America, and was indicated by the tide gauges in the
+Atlantic as far north as the coast of Europe.
+
+Owing to the violence of the eruption, Krakatoa poured forth no lava,
+but the dust and ashes which ascended into the air--or, in
+other words, the finely divided lava which escaped into the
+atmosphere--probably amounted in bulk to more than twenty cubic miles.
+The coarser part of this material, including much pumice, fell upon
+the seas in the vicinity, where, owing to its lightness, it was free
+to drift in the marine currents far and wide throughout the oceanic
+realm. The finer particles, thrown high into the air, perhaps to the
+height of nearly a hundred thousand feet--certainly to the elevation
+of more than half this amount--drifted far and wide in the
+atmosphere, so that for years the air of all regions was clouded by
+it, the sunrise and sunset having a peculiar red glow, which the dust
+particles produce by the light which they reflect. In this period, at
+all times when the day was clear, the sun appeared to be surrounded by
+a dusky halo. In time the greater part of this dust was drawn down by
+gravity, some portion of it probably falling on every square foot of
+the earth. Since the disappearance of the characteristic phenomena
+which it produced in the atmosphere, European observers have noted the
+existence of faint clouds lying in the upper part of the air at the
+height of a hundred miles or more above the surface. These clouds,
+which were at first distinctly visible in the earliest stage of dawn
+and in the latest period of the sunset glow, seemed to be in rapid
+motion to the eastward, and to be mounting higher above the earth. It
+has been not unreasonably supposed that these shining clouds represent
+portions of the finest dust from Krakatoa, which has been thrown so
+far above the earth's attraction that it is separating itself from the
+sphere. If this view be correct, it seems likely that we may look to
+great volcanic explosions as a source whence the dustlike particles
+which people the celestial spaces may have come. They may, in a word,
+be due to volcanic explosions occurring on this and other celestial
+spheres.
+
+The question suggested above as to the possibility of volcanic
+ejections throwing matter from the earth beyond the control of its
+gravitative energy is one of great scientific interest. Computations
+(not altogether trustworthy) show that a body leaving the earth's
+surface under the conditions of a cannon ball fired vertically upward
+would have to possess a velocity at the start of at least seven miles
+a second in order to go free into space. It would at first sight seem
+that we should be able to reckon whether volcanoes can propel earth
+matter upward with this speed. In fact, however, sufficient data are
+not obtainable; we only know in a general way that the column of
+vapour rises to the height of thirty or forty thousand feet, and this
+in eruptions of no great magnitude. In an accident such as that at
+Krakatoa, even if an observer were near enough to see clearly what was
+going on, the chance of his surviving the disturbance would be small.
+Moreover, the ascending vapours, owing to their expansion of the steam
+in the column, begin to fly out sideways on its periphery, so that the
+upper part of the central section in the discharge is not visible from
+the earth.
+
+It is in the central section of the uprushing mass, if anywhere, that
+the dust might attain the height necessary to put it beyond the
+earth's attraction, bringing it fairly into the realm of the solar
+system, or to the position where its own motion and the attraction of
+the other spheres would give it an independent orbital movement about
+the sun, or perhaps about the earth. We can only say that observations
+on the height of volcanic ejections are extremely desirable; they can
+probably only be made from a balloon. An ascension thus made beyond
+the cloud disk which the eruption produces might bring the observer
+where he could discern enough to determine the matter. Although the
+movements of the rocky particles could not be observed, the colour
+which they would give to the heavens might tell the story which we
+wish to know. There is evidence that large masses of stone hurled up
+by volcanic eruption have fallen seven miles from the base of the
+cone. Assuming that the masses went straight upward at the beginning
+of their ascent, and that they were afterward borne outwardly by the
+expansion of the column, computations which have a general but no
+absolute value appear to indicate that the masses attained a height of
+from thirty to fifty miles, and had an initial velocity which, if
+doubled, might have carried them into space.
+
+Last of all, we shall note the conditions which attend the eruptions
+of submarine volcanoes. Such explosions have been observed in but a
+few instances, and only in those cases where there is reason to
+believe that the crater at the time of its explosion had attained to
+within a few hundred feet of the sea level. In these cases the
+ejections, never as yet observed in the state of lava, but in the
+condition of dust and pumice, have occasionally formed a low island,
+which has shortly been washed away by the waves. Knowing as we do that
+volcanoes abound on the sea floor, the question why we do not oftener
+see their explosions disturbing the surface of the waters is very
+interesting, but not as yet clearly explicable. It is possible,
+however, that a volcanic discharge taking place at the depth of
+several thousand feet below the surface of the water would not be able
+to blow the fluid aside so as to open a pipe to the surface, but would
+expend its energy in a hidden manner near the ocean floor. The vapours
+would have to expand gradually, as they do in passing up through the
+rock pipe of a volcano, and in their slow upward passage might be
+absorbed by the water. The solid materials thrown forth would in this
+case necessarily fall close about the vent, and create a very steep
+cone, such, indeed, as we find indicated by the soundings off certain
+volcanic islands which appear only recently to have overtopped the
+level of the waters.
+
+As will be seen, though inadequately from the diagrams of Vesuvius,
+volcanic cones have a regularity and symmetry of form far exceeding
+that afforded by the outlines of any other of the earth's features.
+Where, as is generally the case, the shape of the cone is determined
+by the distribution of the falling cinders or divided lava which
+constitutes the mass of most cones, the slope is in general that known
+as a catenary curve--i.e., the line formed by a chain hanging between
+two points at some distance from the vertical. It is interesting to
+note that this graceful outline is a reflection or consequence of the
+curve described by the uprushing vapour. The expansion in the
+ascending column causes it to enlarge at a somewhat steadfast rate,
+while the speed of the ascent is ever diminishing. Precisely the same
+action can be seen in the like rush of steam and other gases and
+vapours from the cannon's mouth; only in the case of the gun, even of
+the greatest size, we can not trace the movement for more than a few
+hundred feet. In this column of ejection the outward movement from the
+centre carries the bits of lava outwardly from the centre of the
+shaft, so that when they lose their ascending velocity they are drawn
+downward upon the flanks of the cone, the amount falling upon each
+part of that surface being in a general way proportional to the
+thickness of the vaporous mass from which they descend. The result is,
+that the thickest part of the ash heap is formed on the upper part of
+the crater, from which point the deposit fades away in depth in every
+direction. In a certain measure the concentration toward the centre of
+the cone is brought about by the draught of air which moves in toward
+the ascending column.
+
+Although, in general, ejections of volcanic matter take place through
+cones, that being the inevitable form produced by the escaping steam,
+very extensive outpourings of lava, ejections which in mass probably
+far exceed those thrown forth through ordinary craters, are
+occasionally poured out through fissures in the earth's crust. Thus in
+Oregon, Idaho, and Washington, in eastern Europe, in southern India,
+and at some other points, vast flows, which apparently took place from
+fissures, have inundated great realms with lava ejections. The
+conditions which appear to bring about these fissure eruptions of lava
+are not yet well understood. A provisional and very probable account
+of the action can be had in the hypothesis which will now be set
+forth.
+
+Where any region has been for a long time the seat of volcanic action,
+it is probable that a large amount of rock in a more or less fluid
+condition exists beneath its surface. Although the outrushing steam
+ejects much of this molten material, there are reasons to suppose that
+a yet greater part lies dormant in the underground spaces. Thus in the
+case of Ætna we have seen that, though some thousands of miles of
+rock matter have come forth, the base of the cone has been uplifted,
+probably by the moving to that region of more or less fluid rock. If
+now a region thus underlaid by what we may call incipient lavas is
+subjected to the peculiar compressive actions which lead to
+mountain-building, we should naturally expect that such soft material
+would be poured forth, possibly in vast quantities through fault
+fissures, which are so readily formed in all kinds of rock when
+subject to irregular and powerful strains, such as are necessarily
+brought about when rocks are moved in mountain-making. The great
+eruptions which formed the volcanic table-lands on the west coast of
+North America appear to have owed the extrusion of their materials to
+mountain-building actions. This seems to have been the case also in
+some of those smaller areas where fissure flows occur in Europe. It is
+likely that this action will explain the greater part of these massive
+eruptions.
+
+It need not be supposed that the rock beneath these countries, which
+when forced out became lava, was necessarily in the state of perfect
+fluidity before it was forced through the fissures. Situated at great
+depth in the earth, it was under a pressure so great that its
+particles may have been so brought together that the material was
+essentially solid, though free to move under the great strains which
+affected it, and acquiring temperature along with the fluidity which
+heat induces as it was forced along by the mountain-building pressure.
+As an illustration of how materials may become highly heated when
+forced to move particle on particle, it may be well to cite the case
+in which the iron stringpiece on top of a wooden dam near Holyoke,
+Mass., was affected when the barrier went away in a flood. The iron
+stringer, being very well put together, was, it is said, drawn out by
+the strain until it became sensibly reddened by the motion of its
+particles, and finally fell hissing into the waters below. A like
+heating is observable when metal is drawn out in making wire. Thus a
+mass of imperfectly fluid rock might in a forced journey of a few
+miles acquire a decided increase of temperature.
+
+Although the most striking volcanic action--all such phenomena,
+indeed, as commonly receives the name--is exhibited finally on the
+earth's surface, a great deal of work which belongs in the same group
+of geological actions is altogether confined to the deep-lying rock,
+and leads to the formation of dikes which penetrate the strata, but do
+not rise to the open air. We have already noted the fact that dikes
+abound in the deeper parts of volcanic cones, though the fissures into
+which they find their way are seldom riven up to the surface. In the
+same way beneath the ground in non-volcanic countries we may discover
+at a great depth in the older, much-changed rock a vast number of
+these crevices, varying from a few inches to a hundred feet or more in
+width, which have been filled with lavas, the rock once molten having
+afterward cooled. In most cases these dikes are disclosed to us
+through the down-wearing of the earth that has removed the beds into
+which the dikes did not penetrate, thus disclosing the realm in which
+the disturbances took place.
+
+Where, as is occasionally the case in deep mines, or on some bare
+rocky cliff of great height, we can trace a dike in its upward course
+through a long distance, we find that we can never distinctly discover
+the lower point of its extension. No one has ever seen in a clear way
+the point of origin of such an injection. We can, however, often
+follow it upward to the place where there was no longer a rift into
+which it could enter. In its upward path the molten matter appears
+generally to have followed some previously existing fracture, a joint
+plane or a fault, which generally runs through the rocks on those
+planes. We can observe evidence that the material was in the state of
+igneous fluidity by the fact that it has baked the country rocks on
+either side of the fissure, the amount of baking being in proportion
+to the width of the dike, and thus to the amount of heat which it
+could give forth. A dike six inches in diameter will sometimes barely
+sear its walls, while one a hundred feet in width will often alter the
+strata for a great distance on either side. In some instances, as in
+the coal beds near Richmond, Va., dikes occasionally cut through beds
+of bituminous coal. In these cases we find that the coal has been
+converted into coke for many feet either side of a considerable
+injection. The fact that the dike material was molten is still further
+shown by the occurrence in it of fragments which it has taken up from
+the walls, and which may have been partly melted, and in most cases
+have clearly been much heated.
+
+Where dikes extend up through stratified beds which are separated from
+each other by distinct layers, along which the rock is not firmly
+bound together, it now and then happens, as noted by Mr. G.K. Gilbert,
+of the United States Geological Survey, that the lava has forced its
+way horizontally between these layers, gradually uplifting the
+overlying mass, which it did not break through, into a dome-shaped
+elevation. These side flows from dikes are termed laccolites, a word
+which signifies the pool-like nature of the stony mass which they form
+between the strata.
+
+In many regions, where the earth has worn down so as to reveal the
+zone of dikes which was formed at a great depth, the surface of the
+country is fairly laced with these intrusions. Thus on Cape Ann, a
+rocky isle on the east coast of Massachusetts, having an area of about
+twenty square miles, the writer, with the assistance of his colleague,
+Prof. R.S. Tarr, found about four hundred distinct dikes exhibited on
+the shore line where the rocks had been swept bare by the waves. If
+the census of these intrusions could have been extended over the whole
+island, it would probably have appeared that the total number exceeded
+five thousand. In other regions square miles can be found where the
+dikes intercepted by the surface occupy an aggregate area greater than
+that of the rocks into which they have been intruded.
+
+Now and then, but rarely, the student of dikes finds one where the
+bordering walls, in place of having the clean-cut appearance which
+they usually exhibit, has its sides greatly worn away and much melted,
+as if by the long-continued passage of the igneous fluid through the
+crevice. Such dikes are usually very wide, and are probably the paths
+through which lavas found their way to the surface of the earth,
+pouring forth in a volcanic eruption. In some cases we can trace their
+relation to ancient volcanic cones which have worn down in all their
+part which were made up of incoherent materials, so that there remains
+only the central pipe, which has been preserved from decay by the
+coherent character of the lava which filled it.
+
+The hypothesis that dikes are driven upward into strata by the
+pressure of the beds which overlie materials hot and soft enough to be
+put in motion when a fissure enters them, and that their movement
+upward through the crevice is accounted for by this pressure, makes
+certain features of these intrusions comprehensible. Seeing that very
+long, slender dikes are found penetrating the rock, which could not
+have had a high temperature, it becomes difficult to understand how
+the lava could have maintained its fluidity; but on the supposition
+that it was impelled forward by a strong pressure, and that the energy
+thus transmitted through it was converted into heat, we discover a
+means whereby it could have been retained in the liquid condition,
+even when forced for long distances through very narrow channels.
+Moreover, this explanation accounts for the fact which has long
+remained unexplained that dikes, except those formed about volcanic
+craters, rarely, if ever, rise to the surface.
+
+The materials contained in dikes differ exceedingly in their chemical
+and mineral character. These variations are due to the differences in
+Nature of the deposits whence they come, and also in a measure to
+exchanges which take place between their own substance and that of the
+rocks between which they are deposited. This process often has
+importance of an economic kind, for it not infrequently leads to the
+formation of metalliferous veins or other aggregations of ores, either
+in the dike itself or in the country rock. The way in which this is
+brought about may be easily understood by a familiar example. If flesh
+be placed in water which has the same temperature, no exchange of
+materials will take place; but if the water be heated, a circulation
+will be set up, which in time will bring a large part of the soluble
+matter into the surrounding water. This movement is primarily
+dependent on differences of temperature, and consequently differences
+in the quantity of soluble substances which the water seeks to take
+up. When a dike is injected into cooler rocks, such a slow circulation
+is induced. The water contained in the interstices of the stone
+becomes charged with mineral materials, if such exist in positions
+where it can obtain possession of them, and as cooling goes on, these
+dissolved materials are deposited in the manner of veins. These veins
+are generally laid down on the planes of contact between the two kinds
+of stone, but they may be formed in any other cavities which exist in
+the neighbourhood. The formation of such veins is often aided by the
+considerable shrinkage of the lava in the dike, which, when it cools,
+tends to lose about fifteen per cent of its volume, and is thus likely
+to leave a crevice next the boundary walls. Ores thus formed afford
+some of the commonest and often the richest mineral deposits. At
+Leadville, in Colorado, the great silver-bearing lodes probably were
+produced in this manner, wherein lavas, either those of dikes or those
+which flowed in the open air, have come in contact with limestones.
+The mineral materials originally in the once molten rock or in the
+limy beds was, we believe, laid down on ancient sea floors in the
+remains of organic forms, which for their particular uses took the
+materials from the old sea water. The vein-making action has served to
+assemble these scattered bits of metal into the aggregation which
+constitutes a workable deposit. In time, as the rocks wear down, the
+materials of the veins are again taken into solution and returned to
+the sea, thence perhaps to tread again the cycle of change.
+
+In certain dikes, and sometimes also, perhaps, in lavas known as
+basalts, which have flowed on the surface, the rock when cooling, from
+the shrinkage which then occurs, has broken in a very regular way,
+forming hexagonal columns which are more or less divided on their
+length by joints. When worn away by the agencies of decay, especially
+where the material forms steep cliffs, a highly artificial effect is
+produced, which is often compared, where cut at right angles to the
+columns, to pavements, or, where the division is parallel to the
+columns, to the pipes of an organ.
+
+What we know of dikes inclines us to the opinion that as a whole they
+represent movements of softened rock where the motion-compelling agent
+is not mainly the expansion of the contained water which gives rise to
+volcanic ejection, but rather in large part due to the weight of
+superincumbent strata setting in motion materials which were somewhat
+softened, and which tended to creep, as do the clays in deep coal
+mines. It is evident, however; it is, moreover, quite natural, that
+dike work is somewhat mingled with that produced by the volcanic
+forces; but while the line between the two actions is not sharp, the
+discrimination is important, and occurs with a distinctness rather
+unusual on the boundary line between two adjacent fields of phenomena.
+
+                  *       *       *       *       *
+
+We have now to consider the general effects of the earth's interior
+heat so far as that body of temperature tends to drive materials from
+the depths of the earth to the surface. This group of influences is
+one of the most important which operates on our sphere; as we shall
+shortly see, without such action the earth would in time become an
+unfit theatre for the development of organic life. To perceive the
+effect of these movements, we must first note that in the great
+rock-constructing realm of the seas organic life is constantly
+extracting from the water substances, such as lime, potash, soda, and
+a host of other substances necessary for the maintenance of
+high-grade organisms, depositing these materials in the growing
+strata. Into these beds, which are buried as fast as they form, goes
+not only these earthy materials, but a great store of the sea water as
+well. The result would be in course of time a complete withdrawal into
+the depths of the earth of those substances which play a necessary
+part in organic development. The earth would become more or less
+completely waterless on its surface, and the rocks exposed to view
+would be composed mainly of silica, the material which to a great
+extent resists solution, and therefore avoids the dissolving which
+overtakes most other kinds of rocks. Here comes in the machinery of
+the hot springs, the dikes, and the volcanoes. These agents, operating
+under the influence of the internal heat of the earth, are constantly
+engaged in bearing the earthy matter, particularly its precious more
+solvent parts, back to the surface. The hot springs and volcanoes work
+swiftly and directly, and return the water, the carbon dioxide, and a
+host of other vaporizable and soluble and fusible substances to the
+realm of solar activity, to the living surface zone of the earth. The
+dikes operate less immediately, but in the end to the same effect.
+They lift their materials miles above the level where they were
+originally laid, probably from a zone which is rarely if ever exposed
+to view, placing them near the surface, where the erosive agents can
+readily find access to them.
+
+Of the three agents which serve to export earth materials from its
+depths, volcanoes are doubtless the most important. They send forth
+the greater part of the water which is expelled from the rocks.
+Various computations which the writer has made indicate that an
+ordinary volcano, such as Ætna, in times of most intense explosion,
+may send forth in the form of steam one fourth of a cubic mile or
+more of water during each day of its discharge, and in a single great
+eruption may pour forth several times this quantity. In its history
+Ætna has probably returned to the atmosphere some hundred cubic miles
+of water which but for the process would have remained permanently
+locked up in its rock prison.
+
+The ejection of rock material, though probably on the average less in
+quantity than the water which escapes, is also of noteworthy
+importance. The volcanoes of Java and the adjacent isles have, during
+the last hundred and twenty years, delivered to the seas more earth
+material than has been carried into those basins by the great rivers.
+If we could take account of all the volcanic ejections which have
+occurred in this time, we should doubtless find that the sum of the
+materials thus cast forth into the oceans was several times as great
+as that which was delivered from the lands by all the superficial
+agents which wear them away. Moreover, while the material from the
+land, except the small part which is in a state of complete solution,
+all falls close to the shore, the volcanic waste, because of its fine
+division or because of the blebs of air which its masses contain, may
+float for many years before it finds its way to the bottom, it may be
+at the antipodes of the point at which it came from the earth. While
+thus journeying through the sea the rock matter from the volcanoes is
+apt to become dissolved in water; it is, indeed, doubtful if any
+considerable part of that which enters the ocean goes by gravitation
+to its floor. The greater portion probably enters the state of
+solution and makes its way thence through the bodies of plants and
+animals again into the ponderable state.
+
+If an observer could view the earth from the surface of the moon, he
+would probably each day behold one of these storms which the volcanoes
+send forth. In the fortnight of darkness, even with the naked eye, it
+would probably be possible to discern at any time several eruptions,
+some of which would indicate that the earth's surface was ravaged by
+great catastrophes. The nearer view of these actions shows us that
+although locally and in small measure they are harmful to the life of
+the earth, they are in a large way beneficent.
+
+
+
+
+                           CHAPTER VIII.
+
+                             THE SOIL.
+
+
+The frequent mention which it has been necessary to make of soil
+phenomena in the preceding chapters shows how intimately this feature
+in the structure of the earth is blended with all the elements of its
+physical history. It is now necessary for us to take up the phenomena
+of soils in a consecutive manner.
+
+The study of any considerable river basin enables us to trace the more
+important steps which lead to the destructure and renovation of the
+earth's detrital coating. In such an interpretation we note that
+everywhere the rocks which were built on the sea bottom, and more or
+less made over in the great laboratory of the earth's interior, are at
+the surface, when exposed to the conditions of the atmosphere, in
+process of being taken to pieces and returned to the sea. This action
+goes on everywhere; every drop of rain helps it. It is aided by frost,
+or even by the changes of expansion and contraction which occur in the
+rocks from variations of heat. The result is that, except where the
+slopes are steep, the surface is quickly covered with a layer of
+fragments, all of which are in the process of decay, and ready to
+afford some food to plants. Even where the rock appears bare, it is
+generally covered with lichens, which, adhering to it, obtain a share
+of nutriment from the decayed material which they help to hold on the
+slope. When they have retained a thin sheet of the _débris_, mosses
+and small flowering plants help the work of retaining the detritus.
+Soon the strong-rooted bushes and trees win a foothold, and by sending
+their rootlets, which are at first small but rapidly enlarge, into the
+crevices, they hasten the disruption of the stones.
+
+If the construction of soil goes on upon a steep cliff, the quantity
+retained on the slope may be small, but at the base we find a talus,
+composed of the fragments not held by the vegetation, which gradually
+increases as the cliff wears down, until the original precipice may be
+quite obliterated beneath a soil slope. At first this process is
+rapid; it becomes gradually slower and slower as the talus mounts up
+the cliff and as the cliff loses its steepness, until finally a gentle
+slope takes the place of the steep.
+
+From the highest points in any river valley to the sea level the
+broken-up rock, which we term soil, is in process of continuous
+motion. Everywhere the rain water, flowing over the surface or soaking
+through the porous mass, is conveying portions of the material which
+is taken into solution in a speedy manner to the sea. Everywhere the
+expansion of the soil in freezing, or the movements imposed on it by
+the growth of roots, by the overturning of trees, or by the
+innumerable borings and burrowings which animals make in the mass, is
+through the action of gravitation slowly working down the slope. Every
+little disturbance of the grains or fragments of the soil which lifts
+them up causes them when they fall to descend a little way farther
+toward the sea level. Working toward the streams, the materials of the
+soil are in time delivered to those flowing waters, and by them urged
+speedily, though in most cases interruptedly, toward the ocean.
+
+There is another element in the movement of the soils which, though
+less appreciable, is still of great importance. The agents of decay
+which produce and remove the detritus, the chemical changes of the bed
+rock, and the mechanical action which roots apply to them, along with
+the solutional processes, are constantly lowering the surface of the
+mass. In this way we can often prove that a soil continuously
+existing has worked downward through many thousand feet of strata. In
+this process of downgoing the country on which the layer rests may
+have greatly changed its form, but the deposit, under favourable
+conditions, may continue to retain some trace of the materials which
+it derived from beds which have long since disappeared, their position
+having been far up in the spaces now occupied by the air. Where the
+slopes are steep and streams abound, we rarely find detritus which
+belonged in rock more than a hundred feet above the present surface of
+the soil. Where, however, as on those isolated table-lands or buttes
+which abound in certain portions of the Mississippi Valley, as well as
+in many other countries, we find a patch of soil lying on a nearly
+level surface, which for geologic ages has not felt the effect of
+streams, we may discover, commingled in the _débris_, the harder
+wreckage derived from the decay of a thousand feet or more of vanished
+strata.
+
+When we consider the effect of organic life on the processes which go
+on in the soil, we first note the large fact that the development of
+all land vegetation depends upon the existence of this detritus--in a
+word, on the slow movement of the decaying rocky matter from the point
+where it is disrupted to its field of rest in the depths of the sea.
+The plants take their food from the portion of this rocky waste which
+is brought into solution by the waters which penetrate the mass. On
+the plants the animals feed, and so this vast assemblage of organisms
+is maintained. Not only does the land life maintain itself on the
+soil, and give much to the sea, but it serves in various ways to
+protect this detrital coating from too rapid destruction, and to
+improve its quality. To see the nature of this work we should visit a
+region where primeval forests still lie upon the slopes of a hilly
+region. In the body of such a wood we find next the surface a coating
+of decayed vegetable matter, made up of the falling leaves, bark,
+branches, and trunks which are constantly descending to the earth.
+Ordinarily, this layer is a foot or more in thickness; at the top it
+is almost altogether composed of vegetable matter; at the bottom it
+verges into the true soil. An important effect of this decayed
+vegetation is to restrain the movement of the surface water. Even in
+the heaviest rains, provided the mass be not frozen, the water is
+taken into it and delivered in the manner of springs to the larger
+streams. We can better note the measure of this effect by observing
+the difference in the ground covered by this primeval forest and that
+which we find near by which has been converted into tilled fields.
+With the same degree of rapidity in the flow, the distinct stream
+channels on the tilled ground are likely to be from twenty to a
+hundred times in length what they are on the forest bed. The result is
+that while the brook which drains the forested area maintains a
+tolerably constant flow of clean water, the other from the tilled
+ground courses only in times of heavy rain, and then is heavily
+charged with mud. In the virgin conditions of the soil the downwear is
+very slow; in its artificial state this wearing goes on so rapidly
+that the sloping fields are likely to be worn to below the soil level
+in a few score years.
+
+Not only does the natural coating of vegetation, such as our forests
+impose upon the country, protect the soil from washing away, but the
+roots of the larger plants are continually at work in various ways to
+increase the fertility and depth of the stratum. In the form of
+slender fibrils these underground branches enter the joints and bed
+planes of the rock, and there growing they disrupt the materials,
+giving them a larger surface on which decay may operate. These bits,
+at first of considerable size, are in turn broken up by the same
+action. Where the underlying rocks afford nutritious materials, the
+branches of our tap-rooted trees sometimes find their way ten feet or
+more below the base of the true soil. Not only do they thus break up
+the stones, but the nutrition which they obtain in the depths is
+brought up and deposited in the parts above the ground, as well as in
+the roots which lie in the true soil, so that when the tree dies it
+becomes available for other plants. Thus in the forest condition of a
+country the amount of rock material contributed to the deposit in
+general so far exceeds that which is taken away to the rivers by the
+underground water as to insure the deepening of the soil bed to the
+point where only the strongest roots--those belonging to our
+tap-rooted trees--can penetrate through it to the bed rocks.
+
+Almost all forests are from time to time visited by winds which uproot
+the trees. When they are thus rent from the earth, the underground
+branches often form a disk containing a thick tangle of stones and
+earth, and having a diameter of ten or fifteen feet. The writer has
+frequently observed a hundred cubic feet of soil matter, some of it
+taken from the depth of a yard or more, thus uplifted into the air. In
+the path of a hurricane or tornado we may sometimes find thousands of
+acres which have been subjected to this rude overturning--a natural
+ploughing. As the roots rot away, the _débris_ which they held falls
+outside of the pit, thus forming a little hillock along the side of
+the cavity. After a time the thrusting action of other roots and the
+slow motion of the soil down the slope restore the surface from its
+hillocky character to its original smoothness; but in many cases the
+naturalist who has learned to discern with his feet may note these
+irregularities long after it has been recovered with the forest.
+
+Great as is the effect of plants on the soil, that influence is almost
+equalled by the action of the animals which have the habit of entering
+the earth, finding there a temporary abiding place. The number of
+these ground forms is surprisingly great. It includes, indeed, a host
+of creatures which are efficient agents in enriching the earth. The
+species of earthworms, some of which occupy forested districts as well
+as the fields, have the habit of passing the soil material through
+their bodies, extracting from the mass such nutriment as it may
+contain. In this manner the particles of mineral matter become
+pulverized, and in a measure affected by chemical changes in the
+bodies of the creatures, and are thus better fitted to afford plant
+food. Sometimes the amount of the earth which the creatures take in in
+moving through their burrows and void upon the surface is sufficient
+to form annually a layer on the surface of the ground having a depth
+of one twentieth of an inch or more. It thus may well happen that the
+soil to the depth of two or three feet is completely overturned in the
+course of a few hundred years. As the particles which the creatures
+devour are rather small, the tendency is to accumulate the finer
+portions of the soil near the surface of the earth, where by solution
+they may contribute to the needs of the lowly plants. It is probably
+due to the action of these creatures that small relics of ancient men,
+such as stone tools, are commonly found buried at a considerable depth
+beneath the earth, and rarely appear upon the surface except where it
+has been subjected to deep ploughing or to the action of running
+streams.
+
+Along with the earthworms, the ants labour to overturn the soil;
+frequently they are the more effective of the two agents. The common
+species, though they make no permanent hillocks, have been observed by
+the writer to lay upon the surface each year as much as a quarter of
+an inch of sand and other fine materials which they have brought up
+from a considerable depth. In many regions, particularly in those
+occupied by glacial drift, and pebbly alluvium along the rivers, the
+effect of this action, like that of earthworms, is to bring to the
+surface the finer materials, leaving the coarser pebbles in the
+depths. In this way they have changed the superficial character of the
+soil over great areas; we may say, indeed, over a large part of the
+earth, and this in a way which fits it better to serve the needs of
+the wild plants as well as the uses of the farmer.
+
+Many thousand species of insects, particularly the larger beetles,
+have the habit of passing their larval state in the under earth. Here
+they generally excavate burrows, and thus in a way delve the soil. As
+many of them die before reaching maturity, their store of organic
+matter is contributed to the mass, and serves to nourish the plants.
+If the student will carefully examine a section of the earth either in
+its natural or in its tilled state, he will be surprised to find how
+numerous the grubs are. They may often be found to the number of a
+score or more of each cubic foot of material. Many of the species
+which develop underground come from eggs which have carefully been
+encased in organic matter before their deposition in the earth. Thus
+some of the carrion beetles are in the habit of laying their eggs in
+the bodies of dead birds or field mice, which they then bury to the
+depth of some inches in the earth. In this way nearly all the small
+birds and mammals of our woods disappear from view in a few hours
+after they are dead. Other species make balls from the dung of cattle
+in which they lay their eggs, afterward rolling the little spheres, it
+may be for hundreds of feet, to the chambers in the soil which they
+have previously prepared. In this way a great deal of animal matter is
+introduced into the earth, and contributes to its fertility.
+
+Many of our small mammals have the habit of making their dwelling
+places in the soil. Some of them, such as the moles, normally abide in
+the subterranean realm for all their lives. Others use the excavations
+as places of retreat. In any case, these excavations serve to move the
+particles of the soil about, and the materials which the animals drag
+into the earth, as well as the excrement of the creatures, act to
+enrich it. This habit of taking food underground is not limited to the
+mammals; it is common with the ants, and even the earthworms, as noted
+by Charles Darwin in his wonderful essay on these creatures, are
+accustomed to drag into their burrows bits of grass and the slender
+leaves of pines. It is not known what purpose they attain by these
+actions, but it is sufficiently common somewhat to affect the
+conditions of the soil.
+
+The result of these complicated works done by animals and plants on
+the soil is that the material to a considerable depth are constantly
+being supplied with organic matter, which, along with the mineral
+material, constitutes that part of the earth which can support
+vegetation. Experiment will readily show that neither crushed rock nor
+pure vegetable mould will of itself serve to maintain any but the
+lowliest vegetation. It requires that the two materials be mixed in
+order that the earth may yield food for ordinary plants, particularly
+for those which are of use to man, as crops. On this account all the
+processes above noted whereby the waste of plant and animal life is
+carried below the surface are of the utmost importance in the creation
+and preservation of the soil. It has been found, indeed, in almost all
+cases, necessary for the farmer to maintain the fertility of his
+fields to plough-in quantities of such organic waste. By so doing he
+imitates the work which is effected in virgin soil by natural action.
+As the process is costly in time and material, it is often neglected
+or imperfectly done, with the result that the fields rapidly diminish
+in fertility.
+
+The way in which the buried organic matter acts upon the soil is not
+yet thoroughly understood. In part it accomplishes the results by the
+materials which on its decay it contributes to the soil in a state in
+which they may readily be dissolved and taken up by the roots into
+their sap; in part, however, it is believed that they better the
+conditions by affording dwelling places for a host of lowly species,
+such as the forms which are known as bacteria. The organisms probably
+aid in the decomposition of the mineral matter, and in the conversion
+of nitrogen, which abounds in the air or the soil, into nitrates of
+potash and soda--substances which have a very great value as
+fertilizers. Some effect is produced by the decay of the foreign
+matter brought into the soil, which as it passes away leaves channels
+through which the soil water can more readily pass.
+
+By far the most general and important effect arising from the decay
+of organic matter in the earth is to be found in the carbon dioxide
+which is formed as the oxygen of the air combines with the carbon
+which all organic material contains. As before noted, water thus
+charged has its capacity for taking other substances into solution
+vastly increased, and on this solvent action depends in large part the
+decay of the bed rocks and the solution of materials which are to be
+appropriated by the plants.
+
+Having now sketched the general conditions which lead to the formation
+of soils, we must take account of certain important variations in
+their conditions due to differences in the ways in which they are
+formed and preserved. These matters are not only of interest to the
+geologist, but are of the utmost importance to the life of mankind, as
+well as all the lower creatures which dwell upon the lands. First, we
+should note that soils are divisible into three great groups, which,
+though not sharply parted from each other, are sufficiently peculiar
+for the purposes of classification. Where the earth material has been
+derived from the rocks which nearly or immediately underlie it, we
+have a group of soils which may be entitled those of immediate
+derivation--that is, derived from rocks near by, or from beds which
+once overlaid the level and have since been decayed away. Next, we
+have alluvial soils, those composed of materials which have been
+transported by streams, commonly from a great distance, and laid down
+on their flood plains. Third, the soils the mineral matters of which
+have been brought into their position by the action of glaciers; these
+in a way resemble those formed by rivers, but the materials are
+generally imperfectly sorted, coarse and fine being mingled together.
+Last of all, we have the soils due to the accumulation of blown dust
+or blown sand, which, unlike the others, occupy but a small part of
+the land surface. It would be possible, indeed, to make yet another
+division, including those areas which when emerging from the sea were
+covered with fine, uncemented detritus ready at once to serve the
+purposes of a soil. Only here and there, and but seldom, do we find
+soils of this nature.
+
+It is characteristic of soils belonging to the group to which we have
+given the title of immediate derivation that they have accumulated
+slowly, that they move very gradually down the slopes on which they
+lie, and that in all cases they represent, with a part of their mass
+at least, levels of rock which have disappeared from the region which
+they occupied. The additions made to their mass are from below, and
+that mass is constantly shrinking, generally at a pretty rapid rate,
+by the mineral matter which is dissolved and goes away with the spring
+water. They also are characteristically thin on steep slopes,
+thickening toward the base of the incline, where the diminished grade
+permits the soil to move slowly, and therefore to accumulate.
+
+In alluvial soils we find accumulations which are characterized by
+growth on their upper surfaces, and by the distant transportation of
+the materials of which they are composed. In these deposits the
+outleaching removes vast amounts of the materials, but so long as the
+floods from time to time visit their surfaces the growth of the
+deposits is continued. This growth rarely takes place from the waste
+of the bed rocks on which the alluvium lies. It is characteristic of
+alluvial soils that they are generally made up of _débris_ derived
+from fields where the materials have undergone the change which we
+have noted in the last paragraph; therefore these latter deposits have
+throughout the character which renders the mineral materials easily
+dissolved. Moreover, the mass as it is constructed is commonly mingled
+with a great deal of organic waste, which serves to promote its
+fertility. On these accounts alluvial grounds, though they vary
+considerably in fertility, commonly afford the most fruitful fields of
+any region. They have, moreover, the signal advantage that they often
+may be refreshed by allowing the flood waters to visit them, an
+action which but for the interference of man commonly takes place once
+each year. Thus in the valley of the Nile there are fields which have
+been giving rich grain harvests probably for more than four thousand
+years, without any other effective fertilizing than that derived from
+the mud of the great river.
+
+The group of glaciated soils differs in many ways from either of those
+mentioned. In it we find the mineral matter to have been broken up,
+transported, and accumulated without the influence of those conditions
+which ordinarily serve to mix rock _débris_ with organic matter during
+the process by which it is broken into bits. When vegetation came to
+preoccupy the fields made desolate by glacial action, it found in most
+places more than sufficient material to form soils, but the greater
+part of the matter was in the condition of pebbles of very hard rock
+and sand grains, fragments of silex. Fortunately, the broken-up state
+of this material, by exposing a great surface of the rocky matter to
+decay, has enabled the plants to convert a portion of the mass into
+earth fit for the uses of their roots. But as the time which has
+elapsed since the disappearance of the glaciers is much less than that
+occupied in the formation of ordinary soil, this decay has in most
+cases not yet gone very far, so that in a cubic foot of glaciated
+waste the amount of material available for plants is often only a
+fraction of that held in the soils of immediate derivation.
+
+In the greater portion of the fields occupied by glacial waste the
+processes which lead to the introduction of organic matter into the
+earth have not gone far enough to set in effective work the great
+laboratory which has to operate in order to give fertile soil. The
+pebbles hinder the penetration of the roots as well as the movement of
+insects and other animals. There has not been time enough for the
+overturning of trees to bring about a certain admixture of vegetable
+matter with the soil--in a word, the process of soil-making, though
+the first condition, that of broken-up rock, has been accomplished,
+is as yet very incomplete. It needs, indeed, care in the introduction
+of organic matter for its completion.
+
+It is characteristic of glacial soils that they are indefinitely deep.
+This often is a disadvantageous feature, for the reason that the soil
+water may pass so far down into the earth that the roots are often
+deprived of the moisture which they need, and which in ordinary soils
+is retained near the surface by the hard underlayer. On the other
+hand, where the glacial waste is made up of pebbles formed from rocks
+of varied chemical composition, which contain a considerable share of
+lime, potash, soda, and other substances which are required by plants,
+the very large surface which they expose to decay provides the soil
+with a continuous enrichment. In a cubic foot of pebbly glacial earth
+we often find that the mass offers several hundred times as much
+surface to the action of decay as is afforded by the underlying solid
+bed rock from which a soil of immediate derivation has to win its
+mineral supply. Where the pebbly glacial waste is provided with a
+mixture of vegetable matter, the process of decay commonly goes
+forward with considerable rapidity. If the supply of such matter is
+large, such as may be produced by ploughing in barnyard manure or
+green crops, the nutritive value of the earth may be brought to a very
+high point.
+
+It is a familiar experience in regions where glacial soils exist that
+the earth beneath the swamps when drained is found to be
+extraordinarily well suited for farming purposes. On inspecting the
+pebbles from such places, we observe that they are remarkably decayed.
+Where the masses contain large quantities of feldspar, as is the case
+in the greater part of our granitic and other crystalline rocks, this
+material in its decomposition is converted into kaolin or feldspar
+clay, and gives the stones a peculiar white appearance, which marks
+the decomposition, and indicates the process by which a great variety
+of valuable soil ingredients are brought into a state where they may
+be available for plants.
+
+In certain parts of the glacial areas, particularly in the region near
+the margin of the ice sheet, where the glacier remained in one
+position for a considerable time, we find extensive deposits of
+silicious sand, formed of the materials which settled from the
+under-ice stream, near where they escaped from the glacial cavern.
+These kames and sand plains, because of the silicious nature of their
+materials and the very porous nature of the soil which they afford,
+are commonly sterile, or at most render a profit to the tiller by dint
+of exceeding care. Thus in Massachusetts, although the first settlers
+seized upon these grounds, and planted their villages upon them
+because the forests there were scanty and the ground free from
+encumbering boulders, were soon driven to betake themselves to those
+areas where the drift was less silicious, and where the pebbles
+afforded a share of clay. Very extensive fields of this sandy nature
+in southeastern New England have never been brought under tillage.
+Thus on the island of Martha's Vineyard there is a connected area
+containing about thirty thousand acres which lies in a very favourable
+position for tillage, but has been found substantially worthless for
+such use. The farmers have found it more advantageous to clear away
+the boulders from the coarser drift in order to win soil which would
+give them fair returns.
+
+Those areas which are occupied by soil materials which have been
+brought into their position by the action of the wind may, as regards
+their character, be divided into two very distinct groups--the dunes
+and loess deposits. In the former group, where, as we have noted (see
+page 123), the coarse sea sands or those from the shores of lakes are
+driven forward as a marching hillock, the grains of the material are
+almost always silicious. The fragments in the motion are not taken up
+into the air, but are blown along the surface. Such dune accumulations
+afford an earth which is even more sterile than that of the glacial
+sand plains, where there is generally a certain admixture of pebbles
+from rocks which by their decomposition may afford some elements of
+fertility. Fortunately for the interests of man, these wind-borne
+sands occupy but a small area; in North America, in the aggregate,
+there probably are not more than one thousand square miles of such
+deposits.
+
+Where the rock material drifted by the winds is so fine that it may
+rise into the air in the form of dust, the accumulations made of it
+generally afford a fertile soil, and this for the reason that they are
+composed of various kinds of rock, and not, as in the case of dunes,
+of nearly pure silica. In some very rare cases, where the seashore is
+bordered by coral reefs, as it is in parts of southern Florida, and
+the strand is made up of limestone bits derived from the hard parts
+which the polyps secrete, small dunes are made of limy material.
+Owing, however, in part to the relatively heavy nature of this
+substance, as well as to the rapid manner in which its grains become
+cemented together, such limestone dunes never attain great size nor
+travel any distance from their point of origin.
+
+As before noted, dust accumulations form the soil in extended areas
+which lie to the leeward of great deserts. Thus a considerable part of
+western China and much of the United States to the west of the
+Mississippi is covered by these wind-blown earths. Wherever the
+rainfall is considerable these loess deposits have proved to have a
+high agricultural value.
+
+Where a region has an earth which has recently passed from beneath the
+sea or a great lake, the surface is commonly covered by incoherent
+detritus which has escaped consolidation into hard rock by the fact
+that it has not been buried and thus brought into the laboratory of
+the earth's crust. When such a region becomes dry land, the materials
+are immediately ready to enter into the state of soil. They commonly
+contain a good deal of waste derived from the organic life which
+dwelt upon the sea bottom and was embedded in the strata as they were
+formed. Where these accumulations are made in a lake, the land
+vegetation at once possesses the field, even a single year being
+sufficient for it to effect its establishment. Where the lands emerge
+from the sea, it requires a few years for the salt water to drain away
+so that the earth can be fit for the uses of plants. In a general way
+these sea-bottom soils resemble those formed in the alluvial plains.
+They are, however, commonly more sandy, and their substances less
+penetrated by that decay which goes on very freely in the atmosphere
+because of the abundant supply of oxygen, and but slowly on the sea
+floor. Moreover, the marine deposits are generally made up in large
+part of silicious sand, a material which is produced in large
+quantities by the disruption of the rocks along the sea coast. The
+largest single field of these ocean-bottom soils of North America is
+found in the lowland region of the southern United States, a wide belt
+of country extending along the coast from the Rio Grande to New York.
+Although the streams have channelled shallow valleys in the beds of
+this region, the larger part of its surface still has the peculiar
+features of form and composition which were impressed upon it when it
+lay below the surface of the sea.
+
+Local variations in the character of the soil covering are exceedingly
+numerous, and these differences of condition profoundly affect the
+estate of man. We shall therefore consider some of the more important
+of these conditions, with special reference to their origin.
+
+The most important and distinctly marked variation in the fertility of
+soils is that which is produced by differences in the rainfall. No
+parts of the earth are entirely lacking in rain, but over considerable
+areas the precipitation does not exceed half a foot a year. In such
+realms the soil is sterile, and the natural coating of vegetation
+limited to those plants which can subsist on dew or which can take on
+an occasional growth at such times as moisture may come upon them.
+With a slight increase in precipitation, the soil rapidly increases in
+productivity, so that we may say that where as much as about ten
+inches of water enters the earth during the summer half of the year,
+it becomes in a considerable measure fit for agriculture. Observations
+indicate that the conditions of fertility are not satisfied where the
+rainfall is just sufficient to fill the pores of the soil; there must
+be enough water entering the earth to bring about a certain amount of
+outflow in the form of springs. The reason of this need becomes
+apparent when we study the evident features of those soils which,
+though from season to season charged with water, do not yield springs,
+but send the moisture away through the atmosphere. Wherever these
+conditions occur we observe that the soil in dry seasons becomes
+coated with a deposit of mineral matter, which, because of its taste,
+has received the name of alkali. The origin of this coating is as
+follows: The pores of the soil, charged from year to year with
+sufficient water to fill them, become stored with a fluid which
+contains a very large amount of dissolved mineral matter--too much,
+indeed, to permit the roots of plants, save a few species which have
+become accustomed to the conditions, to do their appointed work. In
+fact, this water is much like that of the sea, which the roots of only
+a few of our higher plants can tolerate. When the dry season comes on,
+the heat of the sun evaporates the water at the surface, leaving
+behind a coating composed of the substances which the water contains.
+The soil below acts in the manner of a lamp-wick to draw up fluid as
+rapidly as the heat burns it away. When the soil water is as far as
+possible exhausted, the alkali coating may represent a considerable
+part of the soluble matter of the soil, and in the next rainy season
+it may return in whole or in part to the under-earth, again to be
+drawn in the manner before described to the upper level. It is
+therefore only when a considerable share of the ground water goes
+forth to the streams in each year that the alkaline materials are in
+quantity kept down to the point where the roots of our crop-giving
+plants can make due use of the soil. Where, in an arid region, the
+ground can be watered from the enduring streams or from artificial
+reservoirs, the main advantage arising from the process is commonly
+found in the control which it gives the farmer in the amount of the
+soil water. He can add to the rainfall sufficient to take away the
+excess of mineral matter. When such soils are first brought under
+tillage it is necessary to use a large amount of water from the
+canals, in order to wash away the old store of alkali. After that a
+comparatively small contribution will often keep the soil in excellent
+condition for agriculture. It has been found, however, in the
+irrigated lands beside the Nile that where too much saving is
+practised in the irrigation, the alkaline coating will appear where it
+has been unknown before, and with it an unfitness of the earth to bear
+crops.
+
+Although the crust of mineral matters formed in the manner above
+described is characteristic of arid countries, and in general peculiar
+to them, a similar deposit may under peculiar conditions be formed in
+regions of great rainfall. Thus on the eastern coast of New England,
+where the tidal marshes have here and there been diked from the sea
+and brought under tillage, the dissolved mineral matters of the soil,
+which are excessive in quantity, are drawn to the surface, forming a
+coating essentially like that which is so common in arid regions. The
+writer has observed this crust on such diked lands, having a thickness
+of an eighth of an inch. In fact, this alkali coating represents
+merely the extreme operation of a process which is going on in all
+soils, and which contributes much to their fertility. When rain falls
+and passes downward into the earth, it conveys the soluble matter to a
+depth below the surface, often to beyond the point where our ordinary
+crop plants, such as the small grains, can have access to it, and
+this for the reason that their roots do not penetrate deeply. When dry
+weather comes and evaporation takes place from the surface, the fluid
+is drawn up to the upper soil layer, and there, in process of
+evaporation, deposits the dissolved materials which it contains. Thus
+the mineral matter which is fit for plant food is constantly set in
+motion, and in its movement passes the rootlets of the plants. It is
+probably on this account--at least in part--that very wet weather is
+almost as unfavourable to the farmer as exceedingly dry, the normal
+alternation in the conditions being, as is well known, best suited to
+his needs.
+
+So long as the earth is subjected to conditions in which the rainfall
+may bring about a variable amount of water in the superficial detrital
+layer, we find normal fruitful soils, though in their more arid
+conditions they may be fit for but few species of plants. When, by
+increasing aridity, we pass to conditions where there is no tolerably
+permanent store of water in the _débris_, the material ceases to have
+the qualities of a soil, and becomes mere rock waste. At the other
+extreme of the scale we pass to conditions where the water is
+steadfastly maintained in the interstices of the detritus, and there
+again the characteristic of the soil and its fitness for the uses of
+land vegetation likewise disappear. In a word, true soil conditions
+demand the presence of moisture, but that in insufficient quantities,
+to keep the pores of the earth continually filled; where they are thus
+filled, we have the condition of swamps. Between these extremes the
+level at which the water stands in the soil in average seasons is
+continually varying. In rainy weather it may rise quite to the
+surface; in a dry season it may sink far down. As this water rises and
+falls, it not only moves, as before noted, the soluble mineral
+materials, but it draws the air into and expels it from the earth with
+each movement. This atmospheric circulation of the soil, as has been
+proved by experiment, is of great importance in maintaining its
+fertility; the successive charges of air supply the needs of the
+microscopic underground creatures which play a large part in enriching
+the soil, and the direct effect of the oxygen in promoting decay is
+likewise considerable. A part of the work which is accomplished by
+overturning the earth in tillage consists in this introduction of the
+air into the pores of the soil, where it serves to advance the actions
+which bring mineral matters into solution.
+
+[Illustration: _Mountain gorge, Himalayas, India. Note the difference
+in the slope of the eroded rocks and the effect of erosion upon them;
+also the talus slopes at the base of the cliffs which the torrent is
+cutting away. On the left of the foreground there is a little bench
+showing a recent higher line of the water._]
+
+In the original conditions of any country which is the seat of
+considerable rainfall, and where the river system is not so far
+developed as to provide channels for the ready exit of the waters, we
+commonly find very extensive swamps; these conditions of bad drainage
+almost invariably exist where a region has recently been elevated
+above the level of the sea, and still retains the form of an irregular
+rolling plain common to sea floors, and also in regions where the work
+done by glaciers has confused the drainage which the antecedent
+streams may have developed. In an old, well-elaborated river system
+swamps are commonly absent, or, if they occur, are due to local
+accidents of an unimportant nature.
+
+For our purpose swamps may be divided into three groups--climbing
+bogs, lake bogs, and marine marshes. The first two of these groups
+depend on the movements of the rain water over the land; the third on
+the action of the tides. Beginning our account with the first and most
+exceptional of these groups, we note the following features in their
+interesting history:
+
+Wherever in a humid region, on a gentle slope--say with an inclination
+not exceeding ten feet to the mile--the soil is possessed by any
+species of plants whose stems grow closely together, so that from
+their decayed parts a spongelike mass is produced, we have the
+conditions which favour the development of climbing bogs. Beginning
+usually in the shores of a pool, these plants, necessarily of a
+water-loving species, retain so much moisture in the spongy mass
+which they form that they gradually extend up the slope. Thus
+extending the margin of their field, and at the same time thickening
+the deposit which they form, these plants may build a climbing bog
+over the surface until steeps are attained where the inclination is so
+great that the necessary amount of water can not be held in the spongy
+mass, or where, even if so held, the whole coating will in time slip
+down in the manner of an avalanche.
+
+The greater part of the climbing bogs of the world are limited to the
+moist and cool regions of high latitudes, where species of moss
+belonging to the genus _Sphagnum_ plentifully flourish. These plants
+can only grow where they are continuously supplied with a bath of
+water about their roots. They develop in lake bogs as far south as
+Mexico, but in the climbing form they are hardly traceable south of
+New England, and are nowhere extensively developed within the limits
+of the United States. In more northern parts of this continent, and in
+northwestern Europe, particularly in the moist climate of Ireland,
+climbing bogs occupy great areas, and hold up their lakes of
+interstitially contained water over the slopes of hills, where the
+surface rises at the rate of thirty feet or more to the mile. So long
+as the deposit of decayed vegetable matter which has accumulated in
+this manner is thin, therefore everywhere penetrated by the fibrous
+roots of the moss, it may continue to cling to its sloping bed; but
+when it attains a considerable thickness, and the roots in the lower
+part decay, the pulpy mass, water-laden in some time of heavy rain,
+break away in a vast torrent of thick, black mud, which may inundate
+the lower lands, causing widespread destruction.
+
+In more southern countries, other water-loving plants lead to the
+formation of climbing bogs. Of these, the commonest and most effective
+are the species of reeds, of which our Indian cane is a familiar
+example. Brakes of this vegetation, plentifully mingled with other
+species of aquatic growth, form those remarkable climbing bogs known
+as the Dismal and other swamps, which numerously occur along the coast
+line of the United States from southern Maryland to eastern Texas.
+Climbing bogs are particularly interesting, not only from the fact
+that they are eminently peculiar effects of plant growth, but because
+they give us a vivid picture of those ancient morasses in which grew
+the plants that formed the beds of vegetable matter now appearing in
+the state of coal. Each such bed of buried swamp material was, with
+rare exceptions, where the accumulation took place in lakes, gathered
+in climbing bogs such as we have described.
+
+Lake bogs occur in all parts of the world, but in their best
+development are limited to relatively high latitudes, and this for the
+reason that the plants which form vegetable matter grow most
+luxuriantly in cool climates and in regions where the level of the
+basin is subject to less variation than occurs in the alternating wet
+and dry seasons which exist in nearly all tropical regions. The
+fittest conditions are found in glaciated regions, where, as before
+noted, small lakes are usually very abundant. On the shores of one of
+these pools, of size not so great that the waves may attain a
+considerable height, or in the sheltered bay of a larger lake, various
+aquatic plants, especially the species of pond lilies, take root upon
+the bottom, and spread their expanded leaves on the surface of the
+water. These flexible-leaved and elastic-stemmed plants can endure
+waves which attain no more than a foot or two of height, and by the
+friction which they afford make the swash on the shore very slight. In
+the quiet water, rushes take root, and still further protect the
+strand, so that the very delicate vegetation of the mosses, such as
+the _Sphagnum_, can fix itself on the shore.
+
+As soon as the _Sphagnum_ mat has begun its growth, the strength given
+by its interlaced fibres enables it to extend off from the shore and
+float upon the water. In this way it may rapidly enlarge, if not
+broken up by the waves, so that its front advances into the lake at
+the rate of several inches each year. While growing outwardly it
+thickens, so that the bottom of the mass gradually works down toward
+the floor of the basin. At the same time the lower part of the sheet,
+decaying, contributes a shower of soft peat mud to the floor of the
+lake. In this way, growing at its edge, deepening, and contributing to
+an upgrowth from the bottom, a few centuries may serve entirely to
+fill a deep basin with peaty accumulation. In general, however, the
+surface of the bog closes over the lake before the accumulation has
+completely filled the shoreward portions of the area. In these
+conditions we have what is familiarly known as a quaking bog, which
+can be swayed up and down by a person who quickly stoops and rises
+while standing on the surface. In this state the tough and thick sheet
+of growing plants is sufficient to uphold a considerable weight, but
+so elastic that the underlying water can be thrown into waves. Long
+before the bog has completely filled the lake with the peaty
+accumulations the growth of trees is apt to take place on its surface,
+which often reduces the area to the appearance of a very level wet
+wood.
+
+[Illustration: Fig. 17.--Diagram showing beginning of peat bog: A,
+lake; B, lilies and rushes; C, lake bog; D, climbing bog.]
+
+Climbing and lake bogs in the United States occupy a total area of
+more than fifty thousand square miles. In all North America the total
+area is probably more than twice as great. Similar deposits are
+exceedingly common in the Eurasian continent and in southern
+Patagonia. It is probable that the total amount of these fields in
+different parts of the world exceeds half a million square miles.
+These two groups of fresh-water swamps have an interest, for the
+reason that when reduced to cultivation by drainage and by subsequent
+removal of the excess of peaty matter, by burning or by natural decay,
+afford very rich soil. The fairest fields of northern Europe,
+particularly in Great Britain and Ireland, have been thus won to
+tillage. In the first centuries of our era a large part of
+England--perhaps as much as one tenth of the ground now tilled in that
+country--was occupied by these lands, which retained water in such
+measure as to make them unfit for tillage, the greater portion of this
+area being in the condition of thin climbing bog. For many centuries
+much of the energy of the people was devoted to the reclamation of
+these valuable lands. This task of winning the swamp lands to
+agriculture has been more completely accomplished in England than
+elsewhere, but it has gone far on the continent of Europe,
+particularly in Germany. In the United States, owing to the fact that
+lands have been cheap, little of this work of swamp-draining has as
+yet been accomplished. It is likely that the next great field of
+improvement to be cultivated by the enterprising people will be found
+in these excessively humid lands, from which the food-giving resources
+for the support of many million people can be won.
+
+[Illustration: Fig. 18.--Diagram showing development of swamp: A,
+remains of lake; B, surface growth; c, peat.]
+
+The group of marine marshes differs in many important regards from
+those which are formed in fresh water. Where the tide visits any
+coast line, and in sheltered positions along that shore, a number of
+plants, mostly belonging to the group of grasses, species which have
+become accustomed to having their roots bathed by salt water, begin
+the formation of a spongy mat, which resembles that composed of
+_Sphagnum_, only it is much more solid. This mat of the marine marshes
+soon attains a thickness of a foot or more, the upper or growing
+surface lying in a position where it is covered for two or three hours
+at each visit of the tide. Growing rapidly outward from the shore, and
+having a strength which enables it to resist in a tolerably effective
+manner waves not more than two or three feet high, this accumulation
+makes head against the sea. To a certain extent the waves undermine
+the front of the sheet and break up masses of it, which they
+distribute over the shallow bottom below the level at which these
+plants can grow. In this deeper water, also, other marine animals and
+plants are continually developing, and their remains are added to the
+accumulations which are ever shallowing the water, thus permitting a
+further extension of the level, higher-lying marsh. This process
+continues until the growth has gone as far as the scouring action of
+the tidal currents will permit. In the end the bay, originally of
+wide-open water, is only such at high tide. For the greater part of
+the time it appears as broad savannas, whose brilliant green gives
+them the aspect of rare fertility.
+
+Owing to the conditions of their growth, the deposits formed in marine
+marshes contain no distinct peat, the nearest approach to that
+substance being the tangle of wirelike roots which covers the upper
+foot or so of the accumulation. The greater part of the mass is
+composed of fine silt, brought in by the streams of land water which
+discharge into the basin, and by the remains of animals which dwelt
+upon the bottom or between the stalks of the plants that occupy the
+surface of the marshes. These interspaces afford admirable shelter to
+a host of small marine forms. The result is, that the tidal marshes,
+as well as the lower-lying mud flats, which have been occupied by the
+mat of vegetation, afford admirable earth for tillage. Unfortunately,
+however, there are two disadvantages connected with the redemption of
+such lands. In the first place, it is necessary to exclude the sea
+from the area, which can only be accomplished by considerable
+engineering work; in the second place, the exclusion of the tide
+inevitably results in the silting up of the passage by which the water
+found its way to the sea. As these openings are often used for
+harbours, the effect arising from their destruction is often rather
+serious. Nevertheless, in some parts of the world very extensive and
+most fertile tracts of land have thus been won from the sea; a large
+part of Holland and shore-land districts in northern Europe are made
+up of fields which were originally covered by the tide. Near the mouth
+of the Rhine, indeed, the people have found these sea-bottom soils so
+profitable that they have gone beyond the zone of the marshes, and
+have drained considerable seas which of old were permanently covered,
+even at the lowest level of the waters.
+
+On the coast of North America marine marshes have an extensive
+development, and vary much in character. In the Bay of Fundy, where
+the tides have an altitude of fifty feet or more, the energy of their
+currents is such that the marsh mat rarely forms. Its place, however,
+is taken by vast and ever-changing mud flats, the materials of which
+are swept to and fro by the moving waters. The people of this region
+have learned an art of a peculiar nature, by which they win broad
+fields of excellent land from the sea. Selecting an area of the flats,
+the surface of which has been brought to within a few feet of high
+tide, they inclose it with a stout barrier or dike, which has openings
+for the free admission of the tidal waters. Entering this basin, the
+tide, moving with considerable velocity, bears in quantities of
+sediment. In the basin, the motion being arrested, this sediment
+falls to the bottom, and serves to raise its level. In a few months
+the sheet of sediment is brought near the plane of the tidal movement,
+then the gates are closed at times when the tide has attained half of
+its height, so that the ground within the dike is not visited by the
+sea water, and can be cultivated.
+
+[Illustration: Fig. 19.--Map of Ipswich marshes, Massachusetts, formed
+behind a barrier beach.]
+
+Along the coast of New England the ordinary marine marshes attain an
+extensive development in the form of broad-grassed savannas. With this
+aspect, though with a considerable change in the plants which they
+bear, the fringe of savannas continues southward along the coast to
+northern Florida. In the region about the mouth of the Savannah River,
+so named from the vast extent of the tidal marshes, these fields
+attain their greatest development. In central and southern Florida,
+however, where the seacoast is admirably suited for their development,
+these coastal marshes of the grassy type disappear, their place being
+taken by the peculiar morasses formed by the growth of the mangrove
+tree.
+
+In the mangrove marshes the tree which gives the areas their name
+covers all the field which is visited by the tide. This tree grows
+with its crown supported on stiltlike roots, at a level above high
+tide. From its horizontal branches there grow off roots, which reach
+downward into the water, and thence to the bottom. The seeds of the
+mangrove are admirably devised so as to enable the plant to obtain a
+foothold on the mud flats, even where they are covered at low tide
+with a depth of two or three feet of water. They are several inches in
+length, and arranged with booklets at their lower ends; floating near
+the bottom, they thus catch upon it, and in a few weeks' growth push
+the shoot to the level of the water, thus affording a foundation for a
+new plantation. In this manner, extending the old forests out into the
+shallow water of the bays, and forming new colonies wherever the water
+is not too deep, these plants rapidly occupy all the region which
+elsewhere would appear in the form of savannas.
+
+[Illustration: Fig. 20.--Diagram showing mode of growth of mangroves.]
+
+The tidal marshes of North America, which may be in time converted to
+the uses of man, probably occupy an area exceeding twenty thousand
+square miles. If the work of reclaiming such lands from the sea ever
+attains the advance in this country that it has done in Holland, the
+area added to the dry land by engineering devices may amount to as
+much as fifty thousand square miles--a territory rather greater than
+the surface of Kentucky, and with a food-yielding power at least five
+times as great as is afforded by that fertile State. In fact, these
+conquests from the sea are hereafter to be among the great works which
+will attract the energies of mankind. In the arid region of the
+Cordilleras, as well as in many other countries, the soil, though
+destitute of those qualities which make it fit for the uses of man,
+because of the absence of water in sufficient amount, is, as regards
+its structure and depth, as well as its mineral contents, admirably
+suited to the needs of agriculture. The development of soils in desert
+regions is in almost all cases to be accounted for by the former
+existence in the realms they occupy of a much greater rainfall than
+now exists. Thus in the Rocky Mountain country, when the deep soils
+of the ample valleys were formed, the lakes, as we have before noted,
+were no longer dead seas, as is at present so generally the case, but
+poured forth great streams to the sea. Here, as elsewhere, we find
+evidence that certain portions of the earth which recently had an
+abundant rainfall have now become starved for the lack of that supply.
+All the soils of arid regions where the trial has been made have
+proved very fertile when subjected to irrigation, which can often be
+accomplished by storing the waters of the brief rainy season or by
+diverting those of rivers which enter the deserts from well-watered
+mountain fields. In fact, the soil of these arid realms yields
+peculiarly ample returns to the husbandman, because of certain
+conditions due to the exceeding dryness of the air. This leads to an
+absence of cloudy weather, so that from the time the seed is planted
+the growth is stimulated by uninterrupted and intense sunshine. The
+same dryness of the air leads, as we have seen, to a rapid evaporation
+from the surface, by which, in a manner before noted, the dissolved
+mineral matter is brought near the top of the soil, where it can best
+serve the greater part of our crop plants. On these accounts an acre
+of irrigated soil can be made to yield a far greater return than can
+be obtained from land of like chemical composition in humid regions.
+
+In many parts of the world, particularly in the northern and western
+portions of the Mississippi Valley, there are widespread areas, which,
+though moderately well watered, were in their virgin state almost
+without forests. In the prairie region the early settlers found the
+country unwooded, except along the margins of the streams. On the
+borders of the true prairies, however, they found considerable areas
+of a prevailingly forested land, with here and there a tract of
+prairie. There were several of these open fields south of the Ohio,
+though the country there is in general forested; one of these prairie
+areas, in the Green River district of Kentucky, was several thousand
+square miles in extent. At first it was supposed that the absence of
+trees in the open country of the Mississippi Valley was due to some
+peculiarity of the soil, but experience shows that plantations
+luxuriantly develop, and that the timber will spread rapidly in the
+natural way. In fact, if the seeds of the trees which have been
+planted since the settlement of the country were allowed to develop as
+they seek to do, it would only be a few centuries before the region
+would be forest-clad as far west as the rainfall would permit the
+plants to develop. Probably the woods would attain to near the
+hundredth meridian.
+
+In the opinion of the writer, the treeless character of the Western
+plains is mainly to be accounted for by the habit which our Indians
+had of burning the herbage of a lowly sort each year, so that the
+large game might obtain better pasturage. It is a well-known fact to
+all those who have had to deal with cattle on fields which are in the
+natural state that fire betters the pasturage. Beginning this method
+of burning in the arid regions to the west of the original forests,
+the natural action of the fire has been gradually to destroy these
+woods. Although the older and larger trees, on account of their thick
+bark and the height of their foliage above the ground, escaped
+destruction, all the smaller and younger members of the species were
+constantly swept away. Thus when the old trees died they left no
+succession, and the country assumed its prairie character. That the
+prairies were formed in this manner seems to be proved by the
+testimony which we have concerning the open area before mentioned as
+having existed in western Kentucky. It is said that around the
+timberless fields there was a wide fringe of old fire-scarred trees,
+with no undergrowth beneath their branches, and that as they died no
+kind of large vegetation took their place. When the Indians who set
+these fires were driven away, as was the case in the last decade of
+the last century, the country at once began to resume its timbered
+condition. From the margin and from every interior point where the
+trees survived, their seeds spread so that before the open land was
+all subjugated to the plough it was necessary in many places to clear
+away a thick growth of the young forest-building trees.
+
+The soils which develop on the lavas and ashes about an active volcano
+afford interesting subjects for study, for the reason that they show
+how far the development of the layer which supports vegetation may
+depend upon the character of the rocks from which it is derived. Where
+the materials ejected from a volcano lie in a rainy district, the
+process of decay which converts the rock into soil is commonly very
+rapid, a few years of exposure to the weather being sufficient to
+bring about the formation of a fertile soil. This is due to the fact
+that most lavas, as well as the so-called volcanic ashes, which are of
+the same material as the lavas, only blown to pieces, are composed of
+varied minerals, the most of which are readily attacked by the agents
+of decay. Now and then, however, we find the materials ejected from a
+particular volcano, or even the lavas and ashes of a single eruption,
+in such a chemical state that soils form upon them with exceeding
+slowness.
+
+                  *       *       *       *       *
+
+The foregoing incomplete considerations make it plain that the
+soil-covering of the earth is the result of very delicate adjustments,
+which determine the rate at which the broken-down rocks find their
+path from their original bed places to the sea. The admirable way in
+which this movement is controlled is indicated by the fact that almost
+everywhere we find a soil-covering deep enough for the use of a varied
+vegetation, but rarely averaging more than a dozen feet in depth. Only
+here and there are the rocks bare or the earth swathed in a profound
+mass of detritus. This indicates how steadfast and measured is the
+march of the rock waste from the hills to the sea. Unhappily, man,
+when by his needs he is forced to till the soil, is compelled to break
+up this ancient and perfect order. He has to strip the living mantle
+from the earth, replacing it with growth of those species which serve
+his needs. Those plants which are most serviceable--which are, indeed,
+indispensable in the higher civilization, the grains--require for
+their cultivation that the earth be stripped bare and deeply stirred
+during the rainy season, and thus subjected to the most destructive
+effect of the rainfall. The result is, that in almost all grain fields
+the rate of soil destruction vastly surpasses that at which the
+accumulation is being made. We may say, indeed, that, except in
+alluvial plains, where the soil grows by flood-made additions to its
+upper surface, no field tilled in grain can without exceeding care
+remain usable for a century. Even though the agriculturist returns to
+the earth all the chemical substances which he takes away in his
+crops, the loss of the soil by the washing away of its substance to
+the stream will inevitably reduce the region to sterility.
+
+It is not fanciful to say that the greatest misfortune which in a
+large way man has had to meet in his agriculture arises from this
+peculiar stress which grain crops put upon the soil. If these grains
+grew upon perennial plants, in the manner of our larger fruits, the
+problem of man's relation to the soil would be much simpler than it is
+at present. He might then manage to till the earth without bringing
+upon it the inevitable destruction which he now inflicts. As it is, he
+should recognise that his needs imperil this ancient and precious
+element in the earth's structure, and he should endeavour in every
+possible way to minimize the damage which he brings about. This result
+he may accomplish in certain simple ways.
+
+First, as regards the fertility of the soil, as distinguished from the
+thickness of the coating, it may be said that modern discoveries
+enable us to see the ways whereby we may for an indefinite period
+avoid the debasement of our great heritage, the food-giving earth. We
+now know in various parts of the world extensive and practically
+inexhaustible deposits, whence may be obtained the phosphates,
+potash, soda, etc., which we take from the soil in our crops. We also
+have learned ways in which the materials contained in our sewage may
+be kept from the sea and restored to the fields. In fact, the recent
+developments of agriculture have made it not only easy, but in most
+cases profitable, to avoid this waste of materials which has reduced
+so many regions to poverty. We may fairly look forward to the time,
+not long distant, when the old progressive degradation in the
+fertility of the soil coating will no longer occur. It is otherwise
+with the mass of the soil, that body of commingled decayed rock and
+vegetable matter which must possess a certain thickness in order to
+serve its needs. As yet no considerable arrest has been made in the
+processes which lead to the destruction of this earthy mass. In all
+countries where tillage is general the rivers are flowing charged with
+all they can bear away of soil material. Thus in the valley of the Po,
+a region where, if the soil were forest-clad, the down-wearing of the
+surface would probably be at no greater rate than one foot in five
+thousand years, the river bears away the soil detritus so rapidly that
+at the present time the downgoing is at the rate of one foot in eight
+hundred years, and each decade sees the soil disappear from hillsides
+which were once fertile, but are now reduced to bare rocks. All about
+the Mediterranean the traveller notes extensive regions which were
+once covered with luxuriant forests, and were afterward the seats of
+prosperous agriculture, where the soil has utterly disappeared,
+leaving only the bare rocks, which could not recover its natural
+covering in thousands of years of the enforced fallow.
+
+Within the limits of the United States the degradation of the soil,
+owing to the peculiar conditions of the country, is in many districts
+going forward with startling rapidity. It has been the habit of our
+people--a habit favoured by the wide extent of fertile and easily
+acquired frontier ground--recklessly to till their farms until the
+fields were exhausted, and then to abandon them for new ground. By
+shallow ploughing on steep hillsides, by neglect in the beginning of
+those gulches which form in such places, it is easy in the hill
+country of the eastern United States to have the soil washed away
+within twenty years after the protecting forests have been destroyed.
+The writer has estimated that in the States south of the Ohio and
+James Rivers more than eight thousand square miles of originally
+fertile ground have by neglect been brought into a condition where it
+will no longer bear crops of any kind, and over fifteen hundred miles
+of the area have been so worn down to the subsoil or the bed rock that
+it may never be profitable to win it again to agricultural uses.
+
+Hitherto, in our American agriculture, our people have been to a great
+extent pioneers; they have been compelled to win what they could in
+the cheapest possible way and with the rudest implements, and without
+much regard to the future of those who were in subsequent generations
+to occupy the fields which they were conquering from the wilderness
+and the savages. The danger is now that this reckless tillage, in a
+way justified of old, may be continued and become habitual with our
+people. It is, indeed, already a fixed habit in many parts of the
+country, particularly in the South, where a small farmer expects to
+wear out two or three plantations in the course of his natural life.
+Many of them manage to ruin from one to two hundred acres of land in
+the course of half a century of uninterrupted labour. This system
+deserves the reprobation of all good citizens; it would be well,
+indeed, if it were possible to do so, to stamp it out by the law. The
+same principle which makes it illegal for a man to burn his own
+dwelling house may fairly be applied in restraining him from
+destroying the land which he tills.
+
+There are a few simple principles which, if properly applied, may
+serve to correct this misuse of our American soil. The careful tiller
+should note that all soils whatever which lie on declivities having a
+slope of more than one foot in thirty inevitably and rapidly waste
+when subject to plough tillage. This instrument tends to smear and
+consolidate the layer of earth over which its heel runs, so that at a
+depth of a few inches below the surface a layer tolerably impervious
+to water is formed. The result is that the porous portion of the
+deposit becomes excessively charged with water in times of heavy rain,
+and moves down the hillside in a rapid manner. All such steep slopes
+should be left in their wooded state, or, if brought into use, should
+be retained as pasture lands.
+
+Where, as is often the case with the farms in hilly countries, all the
+fields are steeply inclined, it is an excellent precaution to leave
+the upper part of the slope with a forest covering. In this condition
+not only is the excessive flow of surface water diminished, but the
+moisture which creeps down the slope from the wooded area tends to
+keep the lower-lying fields in a better state for tillage, and
+promotes the decay of the underlying rocks, and thus adds to the body
+and richness of the earth.
+
+On those soils which must be tilled, even where they tend to wash
+away, the aim should be to keep the detritus open to such a depth that
+it may take in as much as possible of the rainfall, yielding the water
+to the streams through the springs. This end can generally be
+accomplished by deep ploughing; it can, in almost all cases, be
+attained by under-drainage. The effect of allowing the water to
+penetrate is not only to diminish the superficial wearing, but to
+maintain the process of subsoil and bed-rock decay by which the
+detrital covering is naturally renewed. Where, as in many parts of the
+country, the washing away of the soil can not otherwise be arrested,
+the progress of the destruction can be delayed by forming with the
+skilful use of the plough ditches of slight declivity leading along
+the hillsides to the natural waterways. One of the most satisfactory
+marks of the improvement which is now taking place in the agriculture
+of the cotton-yielding States of this country is to be found in the
+rapid increase in the use of the ditch system here mentioned. This
+system, combined with ploughing in the manner where the earth is with
+each overturning thrown uphill, will greatly reduce the destructive
+effect of rainfall on steep-lying fields. But the only effective
+protection, however, is accomplished by carefully terracing the
+slopes, so that the tilled ground lies in level benches. This system
+is extensively followed in the thickly settled portions of Europe, but
+it may be a century before it will be much used in this country.
+
+The duty of the soil-tiller by the earth with which he deals may be
+briefly summed up: He should look upon himself as an agent necessarily
+interfering with the operations which naturally form and preserve the
+soil. He should see that his work brings two risks; he may impoverish
+the accumulation of detrital material by taking out the plant food
+more rapidly than it is prepared for use. This injurious result may be
+at any time reparable by a proper use of manures. Not so, however,
+with the other form of destruction, which results in the actual
+removal of the soil materials. Where neglect has brought about this
+disaster, it can only be repaired by leaving the area to recover
+beneath the slowly formed forest coating. This process in almost all
+cases requires many thousands of years for its accomplishment. The man
+who has wrought such destruction has harmed the inheritance of life.
+
+
+
+
+                            CHAPTER IX.
+
+                     THE ROCKS AND THEIR ORDER.
+
+
+In the preceding chapters of this book the attention of the student
+has been directed mainly to the operations of those natural forces
+which act upon the surface of the earth. Incidentally the consequences
+arising from the applications of energy to the outer part of the
+planet have been attended to, but the main aim has been to set forth
+the work which solar energy, operating in the form of heat,
+accomplishes upon the lands. We have now to consider one of the great
+results of these actions, which is exhibited in the successive strata
+that make up the earth's crust.
+
+The most noteworthy effect arising from the action of the solar forces
+on the earth and their co-operation with those which originate in our
+sphere is found in the destruction of beds or other deposits of rock,
+and the removal of the materials to the floors of water basins, where
+they are again aggregated in strata, and gradually brought once more
+into a stable condition within the earth. This work is accomplished by
+water in its various states, the action being directly affected by
+gravitation. In the form of steam, water which has been built into
+rocks and volcanically expelled by tensions, due to the heat which it
+has acquired at great depths below the surface, blows forth great
+quantities of lava, which is contributed to the formation of strata,
+either directly in the solid form or indirectly, after having been
+dissolved in the sea. Acting as waves, water impelled by solar energy
+transmitted to it by the winds beats against the shores, wearing away
+great quantities of rock, which is dragged off to the neighbouring sea
+bottoms, there to resume the bedded form. Moving ice in glaciers,
+water again applying solar energy given to it by its elevation above
+the sea, most effectively grinds away the elevated parts of the crust,
+the _débris_ being delivered to the ocean. In the rain the same work
+is done, and even in the wind the power of the sun serves to abrade
+the high-lying rocks, making new strata of their fragments.
+
+As gravity enters as an element in all the movements of divided rock,
+the tendency of the waste worn from the land is to gather on to the
+bottoms of basins which contain water. Rarely, and only in a small
+way, this process results in the accumulation of lake deposits; the
+greater part of the work is done upon the sea floor. When the beds are
+formed in lake basins, they may be accumulated in either of two very
+diverse conditions. They may be formed in what are called dead seas,
+in which case the detrital materials are commonly small in amount, for
+the reason that the inflowing streams are inconsiderable; in such
+basins there is normally a large share of saline materials, which are
+laid down by the evaporation of the water. In ordinary lakes the
+deposits which are formed are mostly due to the sediment that the
+rivers import. These materials are usually fine-grained, and the sand
+or pebbles which they contain are plentifully mingled with clay. Hence
+lake deposits are usually of an argillaceous nature. As organic life,
+such as secretes limestone, is rarely developed to any extent in lake
+basins, limy beds are very rarely formed beneath those areas of water.
+Where they occur, they are generally due to the fact that rivers
+charged with limy matter import such quantities of the substance that
+it is precipitated on the bottom.
+
+As lake deposits are normally formed in basins above the level of the
+sea, and as the drainage channels of the basins are always cutting
+down, the effect is to leave such strata at a considerable height
+above the sea level, where the erosive agents may readily attack them.
+In consequence of this condition, lacustrine beds are rarely found of
+great antiquity; they generally disappear soon after they are formed.
+Where preserved, their endurance is generally to be attributed to the
+fact that the region they occupy has been lowered beneath the sea and
+covered by marine strata.
+
+The great laboratory in which the sedimentary deposits are
+accumulated, the realm in which at least ninety-nine of the hundred
+parts of these materials are laid down, is the oceanic part of the
+earth. On the floors of the seas and oceans we have not only the
+region where the greater part of the sedimentation is effected, but
+that in which the work assumes the greatest variety. The sea bottoms,
+as regards the deposits formed upon them, are naturally divided into
+two regions--the one in which the _débris_ from the land forms an
+important part of the sediment, and the other, where the remoteness
+of the shores deprives the sediment of land waste, or at least of
+enough of that material in any such share as can affect the character
+of the deposits.
+
+What we may term the littoral or shore zone of the sea occupies a belt
+of prevailingly shallow water, varying in width from a few score to a
+few hundred miles. Where the bottom descends steeply from the coast,
+where there are no strong off-shore setting currents, and where the
+region is not near the mouth of a large river which bears a great tide
+of sediment to the sea, the land waste may not affect the bottom for
+more than a mile or two from the shore. Where these conditions are
+reversed, the _débris_ from the air-covered region may be found three
+or four hundred miles from the coast line. It should also be noted
+that the incessant up-and-down goings of the land result in a constant
+change in the position of the coast line, and consequently in the
+extension of the land sediment, in the course of a few geological
+periods over a far wider field of sea bottom than that to which they
+would attain if the shores remained steadfast.
+
+It is characteristic of the sediments deposited within the influence
+of the continental detritus that they vary very much in their action,
+and that this variation takes place not only horizontally along the
+shores in the same stratum, but vertically, in the succession of the
+beds. It also may be traced down the slope from the coast line to deep
+water. Thus where all the _débris_ comes from the action of the waves,
+the deposits formed from the shore outwardly will consist of coarse
+materials, such as pebbles near the coast, of sand in the deeper and
+remoter section, and of finer silt in the part of the deposit which is
+farthest out. With each change in the level of the coast line the
+position of these belts will necessarily be altered. Where a great
+river enters the sea, the changes in the volume of sediment which it
+from time to time sends forth, together with the alternations in the
+position of its point of discharge, led to great local complexities in
+the strata. Moreover, the turbid water sent forth by the stream may,
+as in the case of the tide from the Amazon, be drifted for hundreds of
+miles along the coast line or into the open sea.
+
+The most important variations which occur in the deposits of the
+littoral zone are brought about by the formations of rocks more or
+less composed of limestone. Everywhere the sea is, as compared with
+lake waters, remarkably rich in organic life. Next the shore, partly
+because the water is there shallow, but also because of its relative
+warmth and the extent to which it is in motion, organic life, both
+that of animals and plants, commonly develops in a very luxuriant way.
+Only where the bottom is composed of drifting sands, which do not
+afford a foothold for those species which need to rest upon the shore,
+do we fail to find that surface thickly tenanted with varied forms.
+These are arranged according to the depth of the bottom. The species
+of marine plants which are attached to fixed objects are limited to
+the depth within which the sunlight effectively penetrates the water;
+in general, it may be said that they do not extend below a depth of
+one hundred feet. The animal forms are distributed, according to their
+kinds, over the floor, but few species having the capacity to endure
+any great range in the pressure of the sea water. Only a few forms,
+indeed, extend from low tide to the depth of a thousand feet.
+
+The greatest development of organic life, the realm in which the
+largest number of species occur, and where their growth is most rapid,
+lies within about a hundred feet of the low-tide level. Here sunlight,
+warmth, and motion in the water combine to favour organic development.
+It is in this region that coral reefs and other great accumulations of
+limestone, formed from the skeletons of polyps and mollusks, most
+abundantly occur. These deposits of a limy nature depend upon a very
+delicate adjustment of the conditions which favour the growth of
+certain creatures; very slight geographic changes, by inducing
+movements of sand or mud, are apt to interrupt their formation,
+bringing about a great and immediate alteration in the character of
+the deposits. Thus it is that where geologists find considerable
+fields of rock, where limestones are intercalated with sandstones and
+deposits of clay, they are justified in assuming that the strata were
+laid down near some ancient shore. In general, these coast deposits
+become more and more limy as we go toward the tropical realms, and
+this for the reason that the species which secrete large amounts of
+lime are in those regions most abundant and attain the most rapid
+growth. The stony polyps, the most vigorous of the limestone makers,
+grow in large quantities only in the tropical realm, or near to it,
+where ocean streams of great warmth may provide the creatures with the
+conditions of temperature and food which they need.
+
+As we pass from the shore to the deeper sea, the share of land
+detritus rapidly diminishes until, as before remarked, at the distance
+of five hundred miles from the coast line, very little of that waste,
+except that from volcanoes, attains the bottom of the sea. By far the
+larger part of the contributions which go to the formation of these
+deep-sea strata come from organic remains, which are continually
+falling upon the sea floor. In part, this waste is derived from
+creatures which dwell upon the bottom; in considerable measure,
+however, it is from the dead bodies of those forms which live near the
+surface of the sea, and which when dying sink slowly through the
+intermediate realm to the bottom.
+
+Owing to the absence of sunlight, the prevailingly cold water of the
+deeper seas, and the lack of vegetation in those realms, the growth of
+organic forms on the deep-sea floor is relatively slow. Thus it
+happens that each shell or other contribution to the sediment lies for
+some time on the bottom before it is buried. While in this condition
+it is apt to be devoured by some of the many species which dwell on
+the bottom and subsist from the remains of animals and plants which
+they find there. In all cases the fossilization of any form depends
+upon the accumulation of sediment before the processes of destruction
+have overtaken them, and among these processes we must give the first
+place to the creatures which subsist on shells, bones, or other
+substances of like nature which find their way to the ocean floor. In
+the absolute darkness, the still water, and the exceeding cold of the
+deeper seas, animals find difficult conditions for development.
+Moreover, in this deep realm there is no native vegetation, and, in
+general, but little material of this nature descends to the bottom
+from the surface of the sea. The result is, the animals have to
+subsist on the remains of other animals which at some step in the
+succession have obtained their provender from the plants which belong
+on the surface or in the shallow waters of the sea. This limitation
+of the food supply causes the depths of the sea to be a realm of
+continual hunger, a region where every particle of organic matter is
+apt to be seized upon by some needy creature.
+
+In consequence of the fact that little organic matter on the deeper
+sea floors escapes being devoured, the most of the material of this
+nature which goes into strata enters that state in a finely divided
+condition. In the group of worms alone--forms which in a great
+diversity of species inhabit the sea floor--we find creatures which
+are specially adapted to digesting the _débris_ which gathers on the
+sea bottom. Wandering over this surface, much in the manner of our
+ordinary earthworms, these creatures devour the mud, voiding the
+matter from their bodies in a yet more perfectly divided form. Hence
+it comes about that the limestone beds, so commonly formed beneath the
+open seas, are generally composed of materials which show but few and
+very imperfect fossils. Studying any series of limestone beds, we
+commonly find that each layer, in greater or less degree, is made up
+of rather massive materials, which evidently came to their place in
+the form of a limy mud. Very often this lime has crystallized, and
+thus has lost all trace of its original organic structure.
+
+One of the conspicuous features which may be observed in any
+succession of limestone beds is the partings or divisions into layers
+which occur with varied frequency. Sometimes at vertical intervals of
+not more than one or two inches, again with spacings of a score of
+feet, we find divisional planes, which indicate a sudden change in the
+process of rock formation. The lime disappears, and in place of it we
+have a thin layer of very fine detritus, which takes on the form of a
+clay. Examining these partings with care, we observe that on the upper
+surface on the limestone the remains of the animal which dwelt on the
+ancient sea floor are remarkably well preserved, they having evidently
+escaped the effect of the process which reduced their ancestors,
+whose remains constitute the layer, to mud. Furthermore, we note that
+the shaly layer is not only lacking in lime, but commonly contains no
+trace of animals such as might have dwelt on the bottom. The fossils
+it bears are usually of species which swam in the overlying water and
+came to the bottom after death. Following up through the layer of
+shale, we note that the ordinary bottom life gradually reappears, and
+shortly becomes so plentiful that the deposit resumes the character
+which it had before the interruption began. Often, however, we note
+that the assemblage of species which dwelt on the given area of sea
+floor has undergone a considerable change. Forms in existence in the
+lower layer may be lacking in the upper, their place being taken by
+new varieties.
+
+So far the origin of these divisional planes in marine deposits has
+received little attention from geologists; they have, indeed, assumed
+that each of these alterations indicates some sudden disturbance of
+the life of the sea floors. They have, however, generally assumed that
+the change was due to alterations in the depth of the sea or in the
+run of ocean currents. It seems to the writer, however, that while
+these divisions may in certain cases be due to the above-mentioned
+and, indeed, to a great variety of causes, they are in general best to
+be explained by the action of earthquakes. Water being an exceedingly
+elastic substance, an earthquake passes through it with much greater
+speed than it traverses the rocks which support the ocean floor. The
+result is that, when the fluid and solid oscillate in the repeated
+swingings which a shock causes, they do not move together, but rub
+over each other, the independent movements having the swing of from a
+few inches to a foot or two in shocks of considerable energy.
+
+When the sea bottom and the overlying water, vibrating under the
+impulse of an earthquake shock, move past each other, the inevitable
+result is the formation of muddy water; the very fine silt of the
+bottom is shaken up into the fluid, which afterward descends as a
+sheet to its original position. It is a well-known fact that such
+muddying of water, in which species accustomed to other conditions
+dwell, inevitably leads to their death by covering their breathing
+organs and otherwise disturbing the delicately balanced conditions
+which enable them to exist. We find, in fact, that most of the tenants
+of the water, particularly the forms which dwell upon the bottom, are
+provided with an array of contrivances which enable them to clear away
+from their bodies such small quantities of silt as may inconvenience
+them. Thus, in the case of our common clam, the breathing organs are
+covered with vibratory cilia, which, acting like brooms, sweep off any
+foreign matter which may come upon their surfaces. Moreover, the
+creature has a long, double, spoutlike organ, which it can elevate
+some distance above the bottom, through which it draws and discharges
+the water from which it obtains food and air. Other forms, such as the
+crinoids, or sea lilies, elevate the breathing parts on top of tall
+stems of marvellous construction, which brings those vital organs at
+the level, it may be, of three or four feet above the zone of mud. In
+consequence of the peculiar method of growth, the crinoids often
+escape the damage done by the disturbance of the bottom, and thus form
+limestone beds of remarkable thickness; sometimes, indeed, we find
+these layers composed mainly of crinoidal remains, which exhibit only
+slight traces of partings such as we have described, being essentially
+united for the depth of ten or twenty feet. Where the layers have been
+mainly accumulated by shellfish, their average thickness is less than
+half a foot.
+
+When we examine the partitions between the layers of limestone, we
+commonly find that, however thin, they generally extend for an
+indefinite distance in every direction. The writer has traced some of
+these for miles; never, indeed, has he been able to find where they
+disappeared. This fact makes it clear that the destruction which took
+place at the stage where these partings were formed was widespread; so
+far as it was due to earthquake shocks, we may fairly believe that in
+many cases it occurred over areas which were to be measured by tens of
+thousands of square miles. Indeed, from what we know of earthquake
+shocks, it seems likely that the devastation may at times have
+affected millions of square miles.
+
+Another class of accidents connected with earthquakes may also
+suddenly disturb the mud on the sea bottom. When, as elsewhere noted,
+a shock originates beneath the sea, the effect is suddenly to elevate
+the water over the seat of the jarring and the regions thereabouts to
+the height of some feet. This elevation quickly takes the shape of a
+ringlike wave, which rolls off in every direction from its point of
+origin. Where the sea is deep, the effect of this wave on the bottom
+may be but slight; but as the undulation attains shallower water, and
+in proportion to the shoaling, the front of the surge is retarded in
+its advance by the friction of the bottom, while the rear part, being
+in deeper water, crowds upon the advancing line. The action is
+precisely that which has been described as occurring in wind-made
+waves as they approach the beach; but in this last-named group of
+undulations, because of the great width of the swell, the effect of
+the shallowing is evident in much deeper water. It is likely that at
+the depth of a thousand feet the passing of one of these vast surges
+born of earthquakes may so stir the mud of the sea floor as to bring
+about a widespread destruction of life, and thus give rise to many of
+the partitions between strata.
+
+If we examine with the microscope the fine-grained silts which make up
+the shaly layers between limestones, we find the materials to be
+mostly of inorganic origin. It is hard to trace the origin of the
+mineral matter which it contains; some of the fragments are likely to
+prove of Volcanic origin; others, bits of dust from meteorites; yet
+others, dust blown from the land, which may, as we know, be conveyed
+for any distance across the seas. Mingled with this sediment of an
+inorganic origin we almost invariably find a share of organic waste,
+derived not from creatures which dwelt upon the bottom, but from those
+which inhabited the higher-lying waters. If, now, we take a portion of
+the limestone layer which lies above or below the shale parting, and
+carefully dissolve out with acids the limy matter which it contains,
+we obtain a residuum which in general character, except so far as the
+particles may have been affected by the acid, is exactly like the
+material which forms the claylike partition. We are thus readily led
+to the conclusion that on the floors of the deeper seas there is
+constantly descending, in the form of a very slow shower, a mass of
+mineral detritus. Where organic life belonging to the species which
+secrete hard shells or skeletons is absent, this accumulation,
+proceeding with exceeding slowness, gradually accumulates layers,
+which take on a shaly character. Where limestone-making animals
+abound, they so increase the rate of deposition that the proportion of
+the mineral material in the growing strata is very much reduced; it
+may, indeed, become as small as one per cent of the mass. In this case
+we may say that the deposit of limestone grew a hundred times as fast
+as the intervening beds of shale.
+
+The foregoing considerations make it tolerably clear that the sea
+floor is in receipt of two diverse classes of sediment--those of a
+mineral and those of an organic origin. The mineral, or inorganic,
+materials predominate along the shores. They gradually diminish in
+quantity toward the open sea, where the supply is mainly dependent on
+the substances thrown forth from volcanoes, on pumice in its massive
+or its comminuted form--i.e., volcanic dust, states of lava in which
+the material, because of the vesicles which it contains, can float for
+ages before it comes to rest on the sea bottom. Variations in the
+volcanic waste contributed to the sea floor may somewhat affect the
+quantity of the inorganic sediments, but, as a whole, the downfalling
+of these fragments is probably at a singularly uniform rate. It is
+otherwise with the contributions of sediment arising from organic
+forms. This varies in a surprising measure. On the coral reefs, such
+as form in the mid oceans, the proportion of matter which has not come
+into the accumulation through the bodies of animals and plants may be
+as small as one tenth of one per cent, or less. In the deeper seas, it
+is doubtful whether the rate of animal growth is such as to permit the
+formation of any beds which have less than one half of their mass made
+up of materials which fell through the water.
+
+In certain areas of the open seas the upper part of the water is dwelt
+in by a host of creatures, mostly foraminifera, which extract
+limestone from the water, and, on dying, send their shells to the
+bottom. Thus in the North Atlantic, even where the sea floor is of
+great depth beneath the surface, there is constantly accumulating a
+mass of limy matter, which is forming very massive limestone strata,
+somewhat resembling chalk deposits, such as abundantly occur in Great
+Britain, in the neighbouring parts of Europe, in Texas, and elsewhere.
+Accumulations such as this, where the supply is derived from the
+surface of the water, are not affected by the accidents which divide
+beds made on the bottom in the manner before described. They may,
+therefore, have the singularly continuous character which we note in
+the English chalk, where, for the thickness of hundreds of feet, we
+may have no evident partitions, except certain divisions, which have
+evidently originated long after the beds were formed.
+
+We have already noted the fact that, while the floors of the deeper
+seas appear to lack mountainous elevations, those arising from the
+folding of strata, they are plentifully scattered over with volcanic
+cones. We may therefore suppose that, in general, the deposits formed
+on the sea floor are to a great extent affected by the materials which
+these vents cast forth. Lava streams and showers represent only a
+part of the contributions from volcanoes, which finally find their way
+to the bottom. In larger part, the materials thrown forth are probably
+first dissolved in the water and then taken up by the organic species;
+only after the death of these creatures does the waste go to the
+bottom. As hosts of these creatures have no solid skeleton to
+contribute to the sea floor, such mineral matter as they may obtain is
+after their death at once restored to the sea.
+
+Not only does the contribution of organic sediment diminish in
+quantity with the depth which is attained, but the deeper parts of the
+ocean bed appear to be in a condition where no accumulations of this
+nature are made, and this for the reason that the water dissolves the
+organic matter more rapidly than it is laid down. Thus in place of
+limestone, which would otherwise form, we have only a claylike
+residuum, such as is obtained when we dissolve lime rocks in acids.
+This process of solution, by which the limy matter deposited on the
+bottom is taken back into the water, goes on everywhere, but at a rate
+which increases with the depth. This increase is due in part to the
+augmentation of pressure, and in part to the larger share of carbonic
+dioxide which the water at great depths holds. The result is, that
+explorations with the dredge seem to indicate that on certain parts of
+the deeper sea floors the rocks are undergoing a process of
+dissolution comparable to that which takes place in limestone caverns.
+So considerable is the solvent work that a large part of the inorganic
+waste appears to be taken up by the waters, so as to leave the bottom
+essentially without sedimentary accumulations. The sea, in a word,
+appears to be eating into rocks which it laid down before the
+depression attained its present great depth.
+
+We should here note something of the conditions which determine the
+supply of food which the marine animals obtain. First of all, we may
+recur to the point that the ocean waters appear to contain something
+of all the earth materials which do not readily decompose when they
+are taken into the state of solution. These mineral substances,
+including the metals, are obtained in part from the lands, through the
+action of the rain water and the waves, but perhaps in larger share
+from the volcanic matter which, in the form of floating lava, pumice,
+or dust, is plentifully delivered to the sea. Except doubtfully, and
+at most in a very small way, this chemical store of the sea water can
+not be directly taken into the structures of animals; it can only be
+immediately appropriated by the marine plants. These forms can only
+develop in that superficial realm of the seas which is penetrated by
+the sunlight, or say within the depth of five hundred feet, mostly
+within one hundred feet of the surface, about one thirtieth of the
+average, and about one fiftieth of the maximum ocean depth. On this
+marine plant life, and in a small measure on the vegetable matter
+derived from the land, the marine animals primarily depend for their
+provender. Through the conditions which bring about the formation of
+_Sargassum_ seas, those areas of the ocean where seaweeds grow afloat,
+as well as by the water-logging and weighting down of other vegetable
+matter, some part of the plant remains is carried to the sea floor,
+even to great depths; but the main dependence of the deep-sea forms of
+animals is upon other animal forms, which themselves may have obtained
+their store from yet others. In fact, in any deep-sea form we might
+find it necessary to trace back the food by thousands of steps before
+we found the creature which had access to the vegetable matter. It is
+easy to see how such conditions profoundly limit the development of
+organic being in the abysm of the ocean.
+
+The sedentary animals, or those which are fixed to the sea bottom--a
+group which includes the larger part of the marine species--have to
+depend for their sustenance on the movement of the water which passes
+their station. If the seas were perfectly still, none of these
+creatures except the most minute could be fed; therefore the currents
+of the ocean go far by their speed to determine the rate at which life
+may flourish. At great depths, as we have seen, these movements are
+practically limited to that which is caused by the slow movement which
+the tide brings about. The amount of this motion is proportional to
+the depth of the sea; in the deeper parts, it carries the water to and
+fro twice each day for the distance of about two hundred and fifty
+feet. In the shallower water this motion increases in proportion to
+the shoaling, and in the regions near the shores the currents of the
+sea which, except the massive drift from the poles, do not usually
+touch the bottom, begin to have their influence. Where the water is
+less than a hundred feet in depth, each wave contributes to the
+movement, which attains its maximum near the shore, where every surge
+sweeps the water rapidly to and fro. It is in this surge belt, where
+the waves are broken, that marine animals are best provided with food,
+and it is here that their growth is most rapid. If the student will
+obtain a pint of water from the surf, he will find that it is clouded
+by fragments of organic matter, the quantity in a pound of the fluid
+often amounting to the fiftieth part of its weight. He will thus
+perceive that along the shore line, though the provision of victuals
+is most abundant, the store is made from the animals and plants which
+are ground up in the mill. In a word, while the coast is a place of
+rapid growth, it is also a region of rapid destruction; only in the
+case of the coral animals, which associate their bodies with a number
+of myriads in large and elaborately organized communities, do we find
+animals which can make such head against the action of the waves that
+they can build great deposits in their realm.
+
+It should be noted that a part of the advantage which is afforded to
+organic life by the shore belt is due to the fact that the waters are
+there subjected to a constant process of aëration by the whipping into
+foam and spray which occurs where the waves overturn.
+
+It will be interesting to the student to note the great number of
+mechanical contrivances which have been devised to give security to
+animals and plants which face these difficult conditions arising from
+successive violent blows of falling water. Among these may be briefly
+noted those of the limpets--mollusks which dwell in a conical shell,
+which faces the water with a domelike outside, and which at the moment
+of the stroke is drawn down upon the rock by the strong muscle which
+fastens the creature to its foundation. The barnacles, which with
+their wedge-shaped prows cut the water at the moment of the stroke,
+but open in the pauses between the waves, so that the creature may
+with its branching arms grasp at the food which floats about it; the
+nullipores, forms of seaweed which are framed of limestone and cling
+firmly to the rock--afford yet other instances of protective
+adaptations contrived to insure the safety of creatures which dwell in
+the field of abundant food supply.
+
+                  *       *       *       *       *
+
+The facts above presented will show the reader that the marine
+sediments are formed under conditions which permit a great variety in
+the nature of the materials of which they are composed. As soon as the
+deposits are built into rocks and covered by later accumulations,
+their materials enter the laboratory of the under earth, where they
+are subjected to progressive changes. Even before they have attained a
+great depth, through the laying down of later deposits upon them,
+changes begin which serve to alter their structure. The fragments of a
+soluble kind begin to be dissolved, and are redeposited, so that the
+mass commonly becomes much more solid, passing from the state of
+detritus to that of more or less solid rock. When yet more deeply
+buried, and thereby brought into a realm of greater warmth, or perhaps
+when penetrated by dikes and thereby heated, these changes go yet
+further. More of the material is commonly rearranged by solution and
+redeposition, so that limestone may be converted into crystalline
+marble, granular sandstones into firm masses, known as quartzites, and
+clays into the harder form of slate. Where the changes go to the
+extreme point, rocks originally distinctly bedded probably may be so
+taken to pieces and made over that all traces of their stratification
+may be destroyed, all fossils obliterated, and the stone transformed
+into mica schist, or granite or other crystalline rock. It may be
+injected into the overlying strata in the form of dikes, or it may be
+blown forth into the air through volcanoes. Involved in
+mountain-folding, after being more or less changed in the manner
+described, the beds may become tangled together like the rumpled
+leaves of a book, or even with the complexity of snarled thread. All
+these changes of condition makes it difficult for the geologist to
+unravel the succession of strata so that he may know the true order of
+the rocks, and read from them the story of the successive geological
+periods. This task, though incomplete, has by the labours of many
+thousand men been so far advanced that we are now able to divide the
+record into chapters, the divisions of the geologic ages, and to give
+some account of the succession of events, organic and geographic,
+which have occurred since life began to write its records.
+
+
+                           EARTHQUAKES.
+
+In ordinary experience we seem to behold the greater part of the earth
+which meets our eyes as fixed in its position. A better understanding
+shows us that nothing in this world is immovable. In the realm of the
+inorganic world the atoms and molecules even in solid bodies have to
+be conceived as endowed with ceaseless though ordered motions. Even
+when matter is built into the solid rock, it is doubtful whether any
+grain of it ever comes really to rest. Under the strains which arise
+from the contraction of the earth's interior and the chemical changes
+which the rocks undergo, each bit is subject to ever-changing
+thrusts, which somewhat affect its position. If we in any way could
+bring a grain of sand from any stratum under a microscope, so that we
+could perceive its changes of place, we should probably find that it
+was endlessly swaying this way and that, with reference to an ideally
+fixed point, such as the centre of the earth. But even that centre,
+whether of gravity or of figure, is probably never at rest.
+
+Earth movements may be divided into two groups--those which arise from
+the bodily shifting of matter, which conveys the particles this way or
+that, or, as we say, change their place, and those which merely
+produce vibration, in which the particles, after their vibratory
+movement, return to their original place. For purposes of illustration
+the first, or translatory motion, may be compared to that which takes
+place when a bell is carried along upon a locomotive or a ship; and
+the second, or vibratory movement, to what takes place when the bell
+is by a blow made to ring. It is with these ringing movements, as we
+may term them, that we find ourselves concerned when we undertake the
+study of earthquakes.
+
+It is desirable that the reader should preface his study of
+earthquakes by noting the great and, at the same time, variable
+elasticity of rocks. In the extreme form this elasticity is very well
+shown when a toy marble, which is made of a close-textured rock, such
+as that from which it derives its name, is thrown upon a pavement
+composed of like dense material. Experiment will show that the little
+sphere can often be made to bounce to the height of twenty feet
+without breaking. If, then, with the same energy the marble is thrown
+upon a brick floor, the rebound will be very much diminished. It is
+well to consider what happens to produce the rebound. When the sphere
+strikes the floor it changes its shape, becoming shorter in the axis
+at right angles to the point which was struck, and at the same instant
+expanded along the equator of that axis. The flattening remains for
+only a small fraction of a second; the sphere vibrates so that it
+stretches along the line on which it previously shortened, and, as
+this movement takes place with great swiftness, it may be said to
+propel itself away from the floor. At the same time a similar movement
+goes on in the rock of the floor, and, where the rate of vibration is
+the same, the two kicks are coincident, and so the sphere is impelled
+violently away from the point of contact. Where the marble comes in
+contact with brick, in part because of the lesser elasticity of that
+material, due to its rather porous structure, and partly because it
+does not vibrate at the same rate as the marble, the expelling blow is
+much less strong.
+
+All rocks whatever, even those which appear as incoherent sands, are
+more or less set into vibratory motion whenever they are struck by a
+blow. In the crust of the earth various accidents occur which may
+produce that sudden motion which we term a blow. When we have examined
+into the origin of these impulses, and the way in which they are
+transmitted through the rocks, we obtain a basis for understanding
+earthquake shocks. The commonest cause of the jarrings in the earth is
+found in the formation of fractures, known as faults. If the reader
+has ever been upon a frozen lake at a time when the weather was
+growing colder, and the ice, therefore, was shrinking, he may have
+noted the rending sound and the slight vibration which comes with the
+formation of a crack traversing the sheet of ice. At such a time he
+feels a movement which is an earthquake, and which represents the
+simpler form of those tremors arising from the sudden rupture of fault
+planes. If he has a mind to make the experiment, he may hang a bullet
+by a thread from a small frame which rests upon the ice, and note that
+as the vibration occurs the little pendulum sways to and fro, thus
+indicating the oscillations of the ice. The same instrument will move
+in an identical manner when affected by a quaking in the rocks.
+
+Where the rocks are set in vibration by a rent which is formed in
+them, the phenomena are more complicated, and often on a vastly larger
+scale than in the simple conditions afforded by a sheet of ice. The
+rocks on either side of the rupture generally slide over each other,
+and the opposing masses are rent in their friction upon one another;
+the result is, not only the first jar formed by the initial fracture,
+but a great many successive movements from the other breakages which
+occur. Again, in the deeper parts of the crust, the fault fissures are
+often at the moment of their formation filled by a violent inrush of
+liquid rock. This, as it swiftly moves along, tears away masses from
+the walls, and when it strikes the end of the opening delivers a blow
+which may be of great violence. The nature of this stroke may be
+judged by the familiar instance where the relatively slow-flowing
+stream from a hydrant pipe is suddenly choked by closing the stopcock.
+Unless the plumber provides a cushion of air to diminish the energy of
+the blow, it is often strong enough to shake the house. Again, when
+steam or other gases are by a sudden diminution of pressure enabled to
+expand, they may deliver a blow which is exactly like that caused by
+the explosion of gunpowder, which, even when it rushes against the
+soft cushion of the air, may cause a jarring that may be felt as well
+as heard to a great distance. Such movements very frequently occur in
+the eruptions of volcanoes; they cause a quivering of the earth, which
+may be felt for a great distance from the immediate seat of the
+disturbance.
+
+When by any of the sudden movements which have been above described a
+jar is applied to the rocks, the wave flies through the more or less
+elastic mass until the energy involved in it is exhausted. This may
+not be brought about until the motion has travelled for the distance
+of hundreds of miles. In the great earthquake of 1755, known as the
+Lisbon shock, the records make it seem probable that the movement was
+felt over one eighth part of the earth's surface. Such great
+disturbances probably bring about a motion of the rocks near the point
+of origin, which may be expressed in oscillations having an amplitude
+of one to two feet; but in the greater number of earthquakes the
+maximum swing probably does not exceed the tenth of that amount. Very
+sensible shaking, even such as may produce considerable damage to
+buildings, are caused by shocks in which the earth vibrates with less
+than an inch of swing.
+
+When a shock originates, the wave in the rocks due to the compression
+which the blow inflicts runs at a speed varying with the elasticity of
+the substance, but at the rate of about fifteen hundred feet a second.
+The movements of this wave are at right angles to the seat of the
+originating disturbance, so that the shock may come to the surface in
+a line forming any angle between the vertical and the nearly
+horizontal. Where, as in a volcanic eruption, the shock originates
+with an explosion, these waves go off in circles. Where, however, as
+is generally the case, the shock originates in a fault plane, which
+may have a length and depth of many miles, the movement has an
+elliptical form.
+
+If the earthquake wave ran through a uniform and highly elastic
+substance, such as glass, it would move everywhere with equal speed,
+and, in the case of the greater disturbances, the motion might be felt
+over the whole surface of the earth. But as the motion takes place
+through rocks of varying elasticity, the rate at which it journeys is
+very irregular. Moving through materials of one density, and with a
+rate of vibration determined by those conditions, the impulse is with
+difficulty communicated to strata which naturally vibrate at another
+speed. In many cases, as where a shock passing through dense
+crystalline strata encounters a mass of soft sandstone, the wave, in
+place of going on, is reflected back toward its point of origin. These
+earthquake echoes sometimes give rise to very destructive movements.
+It often happens that before the original tremors of a shock have
+passed away from a point on the surface the reflex movements rush in,
+making a very irregular motion, which may be compared to that of the
+waves in a cross-sea.
+
+The foregoing account of earthquake action will serve to prepare the
+reader for an understanding of those very curious and important
+effects which these accidents produce in and on the earth. Below the
+surface the sensible action of earthquake shocks is limited. It has
+often been observed that people in mines hardly note a swaying which
+may be very conspicuous to those on the surface, the reason for this
+being that underground, where the rocks are firmly bound together, all
+those swingings which are due to the unsupported position of such
+objects as buildings, columnar rocks, trees, and the waters of the
+earth, are absent. The effect of the movements which earthquakes
+impress on the under earth is mainly due to the fact that in almost
+every part of the crust tensions or strains of other kinds are
+continually forming. These may for ages prove without effect until the
+earth is jarred, when motions will suddenly take place which in a
+moment may alter the conditions of the rocks throughout a wide field.
+In a word, a great earthquake caused by the formation of an extensive
+fault is likely to produce any number of slight dislocations, each of
+which is in turn shock-making, sending its little wave to complicate
+the great oscillation. Nor does the perturbing effect of these jarring
+movements cease with the fractures which they set up and the new
+strains which are in turn developed by the motions which they induce.
+The alterations of the rocks which are involved in chemical changes
+are favoured by such motions. It is a familiar experience that a
+vessel of water, if kept in the state of repose, may have its
+temperature lowered three or four degrees below the freezing point
+without becoming frozen. If the side of the vessel is then tapped with
+the finger, so as to send a slight quake through the mass, it will
+instantly congeal. Molecular rearrangements are thus favoured by
+shocks, and the consequences of those which run through the earth are,
+from a chemical point of view, probably important.
+
+The reader may help himself to understand something of the complicated
+problem of earth tensions, and the corresponding movements of the
+rocks, by considering certain homely illustrations. He may observe how
+the soil cracks as it shrinks in times of drought, the openings
+closing when it rains. In a similar way the frozen earth breaks open,
+sometimes with a shock which is often counted as an earthquake. Again,
+the ashes in a sifter or the gravel on a sieve show how each shaking
+may relieve certain tensions established by gravity, while they create
+others which are in turn to be released by the next shock. An ordinary
+dwelling house sways and strains with the alternations of temperature
+and moisture to which it is subjected in the round of climatal
+alterations. Now and then we note the movements in a cracking sound,
+but by far the greater part of them escape observation.
+
+With this sketch of the mechanism of earthquake shocks we now turn to
+consider their effects upon the surface of the earth. From a
+geological point of view, the most important effect of earthquake
+shocks is found in the movement of rock masses down steep slopes,
+which is induced by the shaking. Everywhere on the land the agents of
+decay and erosion tend to bring heavy masses into position where
+gravitation naturally leads to their downfall, but where they may
+remain long suspended, provided they are not disturbed. Thus, wherever
+there are high and steep cliffs, great falls of rock are likely to
+occur when the earthquake movements traverse the under earth. In more
+than one instance observers, so placed that they commanded a view of
+distant mountains, have noticed the downfall of precipices in the path
+of the shock before the trembling affected the ground on which they
+stood. In the famous earthquake of 1783, which devastated southern
+Italy, the Prince of Scylla persuaded his people to take refuge in
+their boats, hoping that they might thereby escape the destruction
+which threatened them on the land. No sooner were the unhappy folk on
+the water than the fall of neighbouring cliffs near the sea produced a
+great wave, which overwhelmed the vessels.
+
+Where the soil lies upon steep slopes, in positions in which it has
+accumulated during ages of tranquillity, a great shock is likely to
+send it down into the valleys in vast landslides. Thus, in the
+earthquake of 1692, the Blue Mountains of Jamaica were so violently
+shaken that the soil and the forests which stood on it were
+precipitated into the river beds, so that many tree-clad summits
+became fields of bare rock. The effect of this action is immensely to
+increase the amount of detritus which the streams convey to the sea.
+After the great Jamaica shock, above noted, the rivers for a while
+ceased to flow, their waters being stored in the masses of loose
+material. Then for weeks they poured forth torrents of mud and the
+_débris_ of vegetation--materials which had to be swept away as the
+streams formed new channels.
+
+In all regions where earthquake movements are frequent, and the shock
+of considerable violence, the trained observer notes that the surfaces
+of bare rock are singularly extensive, the fact being that many of
+these areas, where the slope lies at angles of from ten to thirty
+degrees, which in an unshaken region would be thickly soil-covered,
+are deprived of the coating by the downward movement of the waste
+which the disturbances bring about. A familiar example of this action
+may be had by watching the workmen engaged in sifting sand, by casting
+the material on a sloping grating. The work could not be done but for
+an occasional blow applied to the sifter. An arrangement for such a
+jarring motion is commonly found in various ore-dressing machines,
+where the object is to move fragments of matter over a sloping
+surface.
+
+Even where the earth is so level that an earthquake shock does not
+cause a sliding motion of the materials, such as above described,
+other consequences of the shaking may readily be noted. As the motion
+runs through the mass, provided the movement be one of considerable
+violence, crevices several feet in width, and sometimes having the
+length of miles, are often formed. In most cases these fissures,
+opened by one pulsation of the shock, are likely to be closed by the
+return movement, which occurs the instant thereafter. The consequences
+of this action are often singular, and in cases constitute the most
+frightful elements of a shock which the sufferer beholds. In the great
+earthquake of 1811, which ravaged the section of the Mississippi
+Valley between the mouth of the Ohio and Vicksburg, these crevices
+were so numerously formed that the pioneers protected themselves from
+the danger of being caught in their jaws by felling trees so that they
+lay at right angles to the direction in which the rents extended,
+building on these timbers platforms to support their temporary
+dwelling places. The records of earthquakes supply many instances in
+which people have been caught in these earth fissures, and in a single
+case it is recorded that a man who disappeared into the cavity was in
+a moment cast forth in the rush of waters which in this, as in many
+other cases, spouts forth as the walls of the opening come together.
+
+Sometimes these rents are attended by a dislocation, which brings the
+earth on one side much higher than on the other. The step thus
+produced may be many miles in length, and may have a height of twenty
+feet or more. It needs no argument to show that we have here the top
+of a fault such as produced the shock, or it may be one of a secondary
+nature, such as any earthquake is likely to bring about in the strata
+which it traverses. In certain cases two faults conjoin their action,
+so that a portion of the surface disappears beneath the earth,
+entombing whatever may have stood on the vanished site. Thus in the
+great shock known as that of Lisbon, which occurred in 1755, the stone
+quay along the harbour, where many thousand people had sought refuge
+from the falling buildings of the city, suddenly sank down with the
+multitude, and the waters closed over it; no trace of the people or of
+the structure was to be found after the shock was over. There is a
+story to the effect that during the same earthquake an Arab village in
+northern Africa sank down, the earth on either side closing over it,
+so that no trace of the habitations remained. In both these instances
+the catastrophes are best explained by the diagram.
+
+[Illustration: Fig. 21.--Diagram showing how a portion of the earth's
+surface may be sunk by faulting. Fig. A shows the original position;
+B, the position after faulting; b b' and c c' the planes of the
+faults; the arrows the direction of the movement.]
+
+In the earthquake of 1811 the alluvial plains on either side of the
+Mississippi at many points sank down so that arable land was converted
+into lakes; the area of these depressions probably amounted to some
+hundred square miles. The writer, on examining these sunken lands,
+found that the subsidences had occurred where the old moats or
+abandoned channels of the great river had been filled in with a
+mixture of decaying timber and river silt. When violently shaken, this
+loose-textured _débris_ naturally settled down, so that it formed a
+basin occupied by a crescent-shaped lake. The same process of settling
+plentifully goes on wherever the rocks are still in an uncemented
+state. The result is often the production of changes which lead to the
+expulsion of gases. Thus, in the Charleston earthquake of 1883, the
+surface over an area of many hundred square miles was pitted with
+small craters, formed by the uprush of water impelled by its contained
+gases. These little water volcanoes--for such we may call
+them--sometimes occur to the number of a dozen or more on each acre of
+ground in the violently shaken district. They indicate one result of
+the physical and chemical alterations which earthquake shocks bring
+about. As earthquakes increase in violence their effect upon the soil
+becomes continually greater, until in the most violent shocks all the
+loose materials on the surface of the earth may be so shaken about as
+to destroy even the boundaries of fields. After the famous earthquake
+of Riobamba, which occurred on the west coast of South America in
+1797, the people of the district in which the town of that name was
+situated were forced to redivide their land, the original boundaries
+having disappeared. Fortunately, shocks of this description are
+exceedingly rare. They occur in only a few parts of the world.
+
+Certain effects of earthquakes where the shock emerges beneath the sea
+have been stated in the account of volcanic eruptions (see page 299).
+We may therefore note here only certain of the more general facts.
+While passing through the deep seas, this wave may have a height of
+not more than two or three feet and a width of some score miles. As it
+rolls in upon the shore the front of the undulation is retarded by the
+friction of the bottom in such a measure that its speed is diminished,
+while the following part of the waves, being less checked, crowds up
+toward this forward part. The result is, that the surge mounts ever
+higher and higher as it draws near the shore, upon which it may roll
+as a vast wave having the height of fifty feet or more and a width
+quite unparalleled by any wave produced from wind action. Waves of
+this description are most common in the Pacific Ocean. Although but
+occasional, the damage which they may inflict is very great. As the
+movement approaches the shore, vessels, however well anchored, are
+dragged away to seaward by the great back lash of the wave, a
+phenomenon which may be perceived even in the case of the ordinary
+surf. Thus forced to seaward, the crews of the ships may find their
+vessels drawn out for the distance of some miles, until they come near
+the face of the advancing billow. This, as it approaches the shore,
+straightens up to the wall-fronted form, and then topples upon the
+land. Those vessels which are not at once crushed down by the blow are
+generally hurled far inland by the rush of waters. In the great
+Jamaica earthquake of 1692 a British man-of-war was borne over the
+tops of certain warehouses and deposited at a distance from the shore.
+
+Owing to the fact that water is a highly elastic material, the shocks
+transmitted to it from the bottom are sent onward with their energy
+but little diminished. While the impulse is very violent, these
+oscillations may prove damaging to shipping. The log-books of mariners
+abound in stories of how vessels were dismasted or otherwise badly
+shaken by a sudden blow received in the midst of a quiet sea. The
+impression commonly conveyed to the sailors is that the craft has
+struck upon a rock. The explanation is that an earthquake jar, in
+traversing the water, has delivered its blow to the ship. As the speed
+of this jarring movement is very much greater than that of any
+ordinary wave, the blow which it may strike may be most destructive.
+There seems, indeed, little reason to doubt that a portion of the
+vessels which are ever disappearing in the wilderness of the ocean are
+lost by the crushing effect of these quakings which pass through the
+waters of the deep.
+
+We have already spoken of the earthquake shock as an oscillation. It
+is a quality of all bodies which oscillate under the influence of a
+blow, such as originates in earthquake shocks, to swing to and fro,
+after the manner of the metal in a bell or a tuning fork, in a
+succession of movements, each less than the preceding, until the
+impulse is worn out, or rather, we should in strict sense say,
+changed to other forms of energy. The result is, that even in the
+slightest earthquake shock the earth moves not once to and fro, but
+very many times. In a considerable shock the successive diminishing
+swingings amount to dozens before they become so slight as to elude
+perception. Although the first swaying is the strongest, and generally
+the most destructive, the quick to-and-fro motions are apt to continue
+and to complete the devastation which the first brings about. The
+vibrations due to any one shock take place with great rapidity. They
+may, indeed, be compared to those movements which we perceive in the
+margin of a large bell when it has received a heavy blow from the
+clapper. The reader has perhaps seen that for a moment the rim of the
+bell vibrates with such rapidity that it has a misty look--that is,
+the motions elude the sight. It is easy to see that a shaking of this
+kind is particularly calculated to disrupt any bodies which stand free
+in the air and are supported only at their base.
+
+In what we may call the natural architecture of the earth, the
+pinnacles and obelisks, such as are formed in many high countries, the
+effect of these shakings is destructive, and, as we have seen, even
+the firmer-placed objects, such as the strong-walled cliffs and steep
+slopes of earth, break down under the assaults. It is therefore no
+matter of surprise that the buildings which man erects, where they are
+composed of masonry, suffer greatly from these tremblings. In almost
+all cases human edifices are constructed without regard to other
+problems of strength than those which may be measured by their weight
+and the resistance to fracture from gravitation alone. They are not
+built with expectation of a quaking, but of a firm-set earth.
+
+The damage which earthquakes do to buildings is in most cases due to
+the fact that they sway their walls out of plumb, so that they are no
+longer in position to support the weight which they have to bear. The
+amount of this swaying is naturally very much greater than that which
+the earth itself experiences in the movement. A building of any height
+with its walls unsupported by neighbouring structures may find its
+roof rocked to and fro through an arc which has a length of feet,
+while its base moves only through a length of inches. The reader may
+see an example of this nature if he will poise a thin book or a bit of
+plank a foot long on top of a small table; then jarring the table so
+that it swings through a distance of say a quarter of an inch, he will
+see that the columnar object swings at its top through a much greater
+distance, and is pretty sure to be overturned.
+
+Where a building carries a load in its upper parts, such as may be
+afforded by its heavy roof or the stores which it contains, the effect
+of an earthquake shock such as carries the earth to and fro becomes
+much more destructive than it might otherwise be. This weight lags
+behind when the earth slips forward in the first movement of the
+oscillation, with the effect that the walls of the building are pretty
+sure to be thrust so far beyond the perpendicular that they give way
+and are carried down by the weight which they bore. It has often been
+remarked in earthquake shocks that tall columns, even where composed
+of many blocks, survive a shock which overturns lower buildings where
+thin walls support several floors, on each of which is accumulated a
+considerable amount of weight. In the case of the column, the strains
+are even, and the whole structure may rock to and fro without toppling
+over. As the energy of the undulations diminish, it gradually regains
+the quiet state without damage. In the ordinary edifice the irregular
+disposition of the weight does not permit the uniform movement which
+may insure safety. Thus, if the city of Washington should ever be
+violently shaken, the great obelisk, notwithstanding that it is five
+hundred feet high, may survive a disturbance which would wreck the
+lower and more massive edifices which lie about it.
+
+Where, as is fortunately rarely the case, the great shock comes to
+the earth in a vertical direction, the effect upon all movable objects
+is in the highest measure disastrous. In such a case buildings are
+crushed as if by the stroke of a giant's hand. The roofs and floors
+are at one stroke thrown to the foundations, and all the parts of the
+walls which are not supported by strong masonry continuous from top to
+bottom are broken to pieces. In such cases it has been remarked that
+the bodies of men are often thrown considerable distances. It is
+asserted, indeed, that in the Riobamba shock they were cast upward to
+the height of more than ninety feet. It is related that the solo
+survivor of a congregation which had hastened at the outset of the
+disturbance into a church was thrown by the greatest and most
+destructive shock upward and through a window the base of which was at
+the height of more than twenty feet from the ground.
+
+It is readily understood that an earthquake shock may enter a building
+in any direction between the vertical and the horizontal. As the
+movement exhausts itself in passing from the place of its origin, the
+horizontal shocks are usually of least energy. Those which are
+accurately vertical are only experienced where the edifices are placed
+immediately over the point where the motion originates. It follows,
+therefore, that the destructive work of earthquakes is mainly
+performed in that part of the field where the motion is, as regards
+its direction, between the vertical and the horizontal--a position in
+which the edifice is likely to receive at once the destructive effect
+arising from the sharp upward thrust of the vertical movement and the
+oscillating action of that which is in a horizontal direction. Against
+strains of this description, where the movements have an amplitude of
+more than a few inches, no ordinary masonry edifice can be made
+perfectly safe; the only tolerable security is attained where the
+building is of well-framed timber, which by its elasticity permits a
+good deal of motion without destructive consequences. Even such
+buildings, however, those of the strongest type, may be ruined by the
+greater earthquakes. Thus, in the Mississippi Valley earthquake of
+1811, the log huts of the frontiersmen, which are about as strong as
+any buildings can be made, were shaken to pieces by the sharp and
+reiterated shocks.
+
+It is by no means surprising to find that the style of architecture
+adopted in earthquake countries differs from that which is developed
+in regions where the earth is firm-set. The people generally learn
+that where their buildings must meet the trials of earthquakes they
+have to be low and strong, framed in the manner of fortifications, to
+withstand the assault of this enemy. We observe that Gothic
+architecture, where a great weight of masonry is carried upon slender
+columns and walls divided by tall windows, though it became the
+dominant style in the relatively stable lands of northern Europe,
+never gained a firm foothold in those regions about the Mediterranean
+which are frequently visited by severe convulsions of the earth. There
+the Grecian or the Romanesque styles, which are of a much more massive
+type, retain their places and are the fashions to the present day.
+Even this manner of building, though affording a certain security
+against slight tremblings, is not safe in the greater shocks. Again
+and again large areas in southern Italy have been almost swept of
+their buildings by the destructive movements which occur in that
+realm. The only people who have systematically adapted their
+architectural methods to earthquake strains are the Japanese, who in
+certain districts where such risks are to be encountered construct
+their dwellings of wood, and place them upon rollers, so that they may
+readily move to and fro as the shock passes beneath them. In a measure
+the people of San Francisco have also provided against this danger by
+avoiding dangerous weights in the upper parts of their buildings, as
+well as the excessive height to which these structures are lifted in
+some of our American towns.
+
+Earthquakes of sensible energy appear to be limited to particular
+parts of the earth's crust. The regions, indeed, where within the
+period of human history shocks of devastating energy have occurred do
+not include more than one fifteenth part of the earth's surface. There
+is a common notion that these movements are most apt to happen in
+volcanic regions. It is, indeed, true that sensible shocks commonly
+attend the explosions from great craters, but the records clearly show
+that these movements are very rarely of destructive energy. Thus in
+the regions about the base of Vesuvius and of Ætna, the two volcanoes
+of which most is known, the shocks have never been productive of
+extensive disaster. In fact, the reiterated slight jarrings which
+attend volcanic action appear to prevent the formation of those great
+and slowly accumulated strains which in their discharge produce the
+most violent tremblings of the earth. The greatest and most continuous
+earthquake disturbances of history--that before noted in the early
+days of this century, in the Mississippi Valley, where shocks of
+considerable violence continued for two years--came about in a field
+very far removed from active volcanoes. So, too, the disturbances
+beneath the Atlantic floor which originated the shocks that led to the
+destruction of Lisbon, and many other similar though less violent
+movements, are developed in a field apparently remote from living
+volcanoes. Eastern New England, which has been the seat of several
+considerable earthquakes, is about as far away from active vents as
+any place on the habitable globe. We may therefore conclude that,
+while volcanoes necessarily produce shocks resulting from the
+discharge of their gases and the intrusion of lava into the dikes
+which are formed about them, the greater part of the important shocks
+are in no wise connected with volcanic explosions.
+
+With the exception of the earthquake in the Mississippi Valley, all
+the great shocks of which we have a record have occurred in or near
+regions where the rocks have been extensively disturbed by
+mountain-building forces, and where the indications lead us to
+believe that dislocations of strata, such as are competent to rive the
+beds asunder, may still be in progress. This, taken in connection with
+the fact that many of these shocks are attended by the formation of
+fault planes, which appear on the surface, lead us to the conclusion
+that earthquakes of the stronger kind are generally formed by the
+riving of fissures, which may or may not be developed upward to the
+surface. This view is supported by many careful observations on the
+effect which certain great earthquakes have exercised on the buildings
+which they have ravaged. The distinguished observer, Mr. Charles
+Mallet, who visited the seat of the earthquake which, in 1854,
+occurred in the province of Calabria in Italy, with great labour and
+skill determined the direction in which the shock moved through some
+hundreds of edifices on which it left the marks of its passage.
+Platting these lines of motion, he found that they were all referred
+to a vertical plane lying at the depth of some miles beneath the
+surface, and extending for a great distance in a north and south
+direction. This method of inquiry has been applied to other fields,
+with the result that in the case of all the instances which have been
+subjected to this inquiry the seat of the shock has been traced to
+such a plane, which can best be accounted for by the supposition of a
+fault.
+
+The method pursued by Mr. Mallet in his studies of the origin of
+earthquakes, and by those who have continued his inquiry, may be
+briefly indicated as follows: Examining disrupted buildings, it is
+easy to determine those which have been wrecked by a shock that
+emerged from the earth in a vertical direction. In these cases, though
+tall walls may remain standing, the roofs and floors are thrown into
+the cellars. With a dozen such instances the plane of what is called
+the seismic vertical is established (_seismos_ is the Greek for
+earthquake). Then on either side of this plane, which indicates the
+line but not the depth of the disturbance, other observations may be
+made which give the clew to the depth. Thus a building may be found
+where the northwest corner at its upper part has been thrown off. Such
+a rupture was clearly caused by an upward but oblique movement, which
+in the first half of the oscillation heaved the structure upwardly
+into the northwest, and then in the second half, or rebound, drew the
+mass of the building away from the unsupported corner, allowing that
+part of the masonry to fly off and fall to the ground. Constructing a
+line at right angles to the plane of the fracture, it will be found to
+intersect the plane, the position of which has been in part determined
+by finding the line where it intersects the earth, or the seismic
+vertical before noted. Multiplying such observations on either side of
+the last-mentioned line, the attitude of the underground parts of the
+plane, as well as the depth to which it attained, can be approximately
+determined.
+
+It is worth while to consider the extent to which earthquake shocks
+may affect the general quality of the people who dwell in countries
+where these disturbances occur with such frequency and violence as to
+influence their lives. There can be no question that wherever
+earthquakes occur in such a measure as to produce widespread terror,
+where, recurring from time to time, they develop in men a sense of
+abiding insecurity, they become potent agents of degradation. All the
+best which men do in creating a civilization rests upon a sense of
+confidence that their efforts may be accumulated from year to year,
+and that even after death the work of each man may remain as a
+heritage to his kind. It is likely, indeed, that in certain realms, as
+in southern Italy, a part of the failure of the people to advance in
+culture is due to their long experience of such calamities, and the
+natural expectation that they will from time to time recur. In a
+similar way the Spanish settlements in Central and South America,
+which lie mostly in lands that are subject to disastrous shocks, may
+have been retarded by the despair, as well as the loss of property
+and life, which these accidents have so frequently inflicted upon
+them. It will not do, however, to attribute too much to such
+terrestrial influences. By far the most important element in
+determining the destiny of a people is to be found in their native
+quality, that which they owe to their ancestors of distant
+generations. In this connection it is well to consider the history of
+the Icelandic people, where a small folk has for a thousand years been
+exposed to a range and severity of trials, such as earthquakes,
+volcanic explosions, and dearth of harvests may produce, and all these
+in a measure that few if any other countries experience.
+Notwithstanding these misfortunes, the Icelanders have developed and
+maintained a civilization which in all else, except its material
+results, on the average transcends that which has been won by any
+other folk in modern times. If a people have the determining spirit
+which leads to high living, they can successfully face calamities far
+greater than those which earthquakes inflict.
+
+It was long supposed that the regions where earthquakes are not
+noticeable by the unaided senses were exempt from all such
+disturbances. The observations which seismologists have made in recent
+years point to the conclusion that no part of the earth's surface is
+quite exempt from movements which, though not readily perceived, can
+be made visible by the use of appropriate instruments. With an
+apparatus known as the horizontal pendulum it is possible to observe
+vibrations which do not exceed in amplitude the hundredth part of an
+inch. This mechanism consists essentially of a slender bar supported
+near one end by two wires, one from above, the other from below. It
+may readily be conceived that any measurable movement will cause the
+longer end of the rod to sway through a considerable arc. Wherever
+such a pendulum has been carefully observed in any district, it has
+been found that it indicates the occurrence of slight tremors. Even
+certain changes of the barometer, which alter the weight of the
+atmosphere that rests upon the earth to the amount indicated by an
+inch in the height of the mercury column, appears in all cases to
+create such tremors. Many of these slight shocks may be due to the
+effect of more violent quakings, which have run perhaps for thousands
+of miles from their point of origin, and have thus been reduced in the
+amplitude of their movement. Others are probably due to the slight
+motion brought about through the chemical changes of the rocks, which
+are continuously going on. The ease with which even small motions are
+carried to a great distance may be judged by the fact that when the
+ground is frozen the horizontal pendulum will indicate the jarring due
+to a railway train at the distance of a mile or more from the track.
+
+In connection with the earth jarring, it would be well to note the
+occurrence of another, though physically different, kind of movement,
+which we may term earth swayings, or massive movements, which slowly
+dislocate the vertical, and doubtless also the horizontal, position of
+points upon its surface. It has more than once been remarked that in
+mountain countries, where accurate sights have been taken, the heights
+of points between the extremities of a long line appear somewhat to
+vary in the course of a term of years. Thus at a place in the
+Apennines, where two buildings separated by some miles of distance are
+commonly intervisible over the crest of a neighbouring peak, it has
+happened that a change of level of some one of the points has made it
+impossible to see the one edifice from the other. Knowing as we do
+that the line of the seacoast is ever-changing, uprising taking place
+at some points and down-sinking at others, it seems not unlikely that
+these irregular swayings are of very common occurrence. Moreover,
+astronomers are beginning to remark the fact that their observatories
+appear not to remain permanently in the same position--that is, they
+do not have exactly the same latitude and longitude. Certain of these
+changes have recently been explained by the discovery of a new and
+hitherto unnoted movement of the polar axis. It is not improbable,
+however, that the irregular swaying of the earth's crust, due to the
+folding of strata and to the alterations in the volume of rocks which
+are continually going on, may have some share in bringing about these
+dislocations.
+
+Measured by the destruction which was wrought to the interests of man,
+earthquakes deserve to be reckoned among the direst calamities of
+Nature. Since the dawn of history the records show us that the
+destruction of life which is to be attributed to them is to be counted
+by the millions. A catalogue of the loss of life in the accidents of
+this description which have occurred during the Christian era has led
+the writer to suppose that probably over two million persons have
+perished from these shocks in the last nineteen centuries.
+Nevertheless, as compared with other agents of destruction, such as
+preventable disease, war, or famine, the loss which has been inflicted
+by earth movements is really trifling, and almost all of it is due to
+an obstinate carelessness in the construction of buildings without
+reference to the risks which are known to exist in earthquake-ridden
+countries.
+
+Although all our exact knowledge concerning the distribution of
+earthquakes is limited to the imperfect records of two or three
+thousand years, it is commonly possible to measure in a general way
+the liability to such accidents which may exist in any country by a
+careful study of the details of its topography. In almost every large
+area the process of erosion naturally leaves quantities of rock,
+either in the form of detached columns or as detrital accumulations
+deposited on steep slopes. These features are of relatively slow
+formation, and it is often possible to determine that they have been
+in their positions for a time which is to be measured by thousands of
+years. Thus, on inspecting a country such as North America, where the
+historic records cover but a brief time, we may on inquiry determine
+which portions of its area have long been exempt from powerful shocks.
+Where natural obelisks and steep taluses abound--features which would
+have disappeared if the region had been moved by great shocks--we may
+be sure that the field under inspection has for a great period been
+exempt from powerful shaking. Judged by this standard, we may safely
+say that the region occupied by the Appalachian Mountains has been
+exempt from serious trouble. So, too, the section of the Cordilleras
+lying to the east of what is commonly called the Great Basin, between
+the Rocky Mountains and the Sierra Nevada, has also enjoyed a long
+reign of peace. In glaciated countries the record is naturally less
+clear than in those parts of the world which have been subjected to
+long-continued, slow decay of the rocks. Nevertheless, in those fields
+boulders are often found poised in position which they could not have
+maintained if subjected to violent shaking. Judged by this evidence,
+we may say that a large part of the northern section of this
+continent, particularly the area about the Great Lakes, has been
+exempt from considerable shocks since the glacier passed away.
+
+The shores which are subject to the visitations of the great marine
+waves, caused by earthquake shocks occurring beneath the bottom of the
+neighbouring ocean, are so swept by those violent inundations that
+they lose many features which are often found along coasts that have
+been exempted from such visitations. Thus wherever we find extensive
+and delicately moulded dunes, poised stones, or slender pinnacled
+rocks along a coast, we may be sure that since these features were
+formed the district has not been swept by these great waves.
+
+[Illustration: Fig. 22.--Poised rocks indicating a long exemption from
+strong earthquakes in the places where such features occur.]
+
+Around the northern Atlantic we almost everywhere find the glacial
+waste here and there accumulated near the margin of the sea in the
+complicated sculptured outlines which are assumed by kame sands and
+gravels. From a study of these features just above the level of high
+tide, the writer has become convinced that the North Atlantic district
+has long been exempt from the assaults of other waves than those which
+are produced during heavy storms. At the present time the waves
+formed by earthquakes appear to be of destructive violence only on the
+west coast of South America, where they roll in from a region of the
+Pacific lying to the south of the equator and a few hundred miles from
+the shore of the continent, which appears to be the seat of
+exceedingly violent shocks. A similar field occurs in the Atlantic
+between the Lesser Antilles and the Spanish peninsula, but no great
+waves have come thence since the time of the Lisbon earthquake. The
+basin of the Caribbean and the region about Java appear to be also
+fields where these disturbances may be expected, though in each but
+one wave of this nature has been recorded. Therefore we may regard
+these secondary results of a submarine earthquake as seldom phenomena.
+
+
+                  DURATION OF GEOLOGICAL TIME.
+
+Although it is beyond the power of man to conceive any such lapses of
+time as have taken place in the history of this earth, it is
+interesting, and in certain ways profitable, to determine as near as
+possible in the measure of years the duration of the events which are
+recorded in the rocks. Some astronomers, basing their conclusions on
+the heat-containing power of matter, and on the rate at which energy
+in this form flows from the sun, have come to the conclusion that our
+planet could not have been in independent existence for more than
+about twenty million years. The geologist, however, resting his
+conclusions on the records which are the subject of his inquiry, comes
+on many different lines to an opinion which traverses that entertained
+by some distinguished astronomers. The ways in which the student of
+the earth arrives at this opinion will now be set forth.
+
+By noting the amount of sediment carried forth to the sea by the
+rivers, the geologist finds that the lands of the earth--those, at
+least, which are protected by their natural envelopes of
+vegetation--are wearing down at a rate which pretty certainly does
+not exceed one foot in about five thousand years, or two hundred feet
+in a million years. Discovering at many places on the earth's surface
+deposits which originally had a thickness of five thousand feet or
+more, which have been worn down to the depths of thousands of feet in
+a single rather brief section of geological time, the student readily
+finds himself prepared to claim that a period of from five to ten
+million years has often been required for the accomplishment of but a
+very small part of the changes which he knows to have occurred on this
+earth.
+
+As the geologist follows down through the sections of the stratified
+rocks, and from the remains of strata determines the erosion which has
+borne away the greater part of the thick deposits which have been
+exposed to erosion, he comes upon one of those breaks in the
+succession, or encounters what is called an unconformity, as when
+horizontal strata lie against those which are tilted. In many cases he
+may observe that at this time there was a great interval unrepresented
+by deposits at the place where his observations are made, yet a great
+lapse of time is indicated by the fact that a large amount of erosion
+took place in the interval between the two sets of beds.
+
+Putting together the bits of record, and assuming that the rate of
+erosion accomplished by the agents which operate on the land has
+always been about the same, the geologist comes to the conclusion that
+the section of the rocks from the present day to the lowest strata of
+the Laurentian represents in the time required for their formation not
+less than a hundred million years; more likely twice that duration. To
+this argument objection is made by some naturalists that the agents of
+erosion may have been more active in the past than they are at
+present. They suggest that the rainfall may have been much greater or
+the tides higher than they now are. Granting all that can be claimed
+on this score, we note the fact that the rate of erosion evidently
+does not increase in anything like a proportionate way with the
+amount of rainfall. Where a country is protected by its natural
+coating of vegetation, the rain is delivered to the streams without
+making any considerable assault upon the surface of the earth, however
+large the fall may be. Moreover, the tides have little direct cutting
+power; they can only remove detritus which other agents have brought
+into a condition to be borne away. The direct cutting power of the
+tidal movement does not seem to be much greater in the Bay of Fundy,
+where the maximum height of the waves amounts to fifty feet, than on
+the southern coast of Massachusetts, where the range is not more than
+five. So far as the observer can judge, the climatal conditions and
+the other influences which affect the wear of rocks have not greatly
+varied in the past from what they are at the present day. Now and then
+there have been periods of excessive erosion; again, ages in which
+large fields were in the conditions of exceeding drought. It is,
+however, a fair presumption that these periods in a way balance each
+other, and that the average state was much like that which we find at
+present.
+
+If after studying the erosive phenomena exhibited in the structure of
+the earth the student takes up the study of the accumulations of
+strata, and endeavours to determine the time required for the laying
+down of the sediments, he finds similar evidence of the earth's great
+antiquity. Although the process of deposition, which has given us the
+rocks visible in the land masses, has been very much interrupted, the
+section which is made by grouping the observations made in various
+fields shows that something like a maximum thickness of a hundred and
+fifty thousand feet of beds has been accumulated in that part of
+geologic time during which strata were being laid down in the fields
+that are subjected to our study. Although in these rocks there are
+many sets of beds which were rapidly formed, the greater part of them
+have been accumulated with exceeding slowness. Many fine shales, such
+as those which plentifully occur in the Devonian beds of this country,
+must have required a thousand years or more for the deposition of the
+materials that now occupy an inch in depth. In those sections a single
+foot of the rock may well represent a period of ten thousand years. In
+many of the limestones the rate of accumulation could hardly have been
+more speedy. The reckoning has to be rough, but the impression which
+such studies make upon the mind of the unprejudiced observer is to the
+effect that the thirty miles or so of sedimentary deposits could not
+have been formed in less than a hundred million years. In this
+reckoning it should be noted that no account is taken of those great
+intervals of unrecorded time, such as elapsed between the close of the
+Laurentian and the beginning of the Cambrian periods.
+
+There is a third way in which we may seek an interpretation of
+duration from the rocks. In each successive stage of the earth's
+history, in different measure in the various ages, mountains were
+formed which in time, during their exposure to the conditions of the
+land, were worn down to their roots and covered by deposits
+accumulated during the succeeding ages. A score or more of these
+successively constructed series of elevations may readily be observed.
+Of old, it was believed that mountain ranges were suddenly formed, but
+there is, however, ample evidence to prove that these disturbed
+portions of the strata were very gradually dislocated, the rate of the
+mountainous growth having been, in general, no greater in the past
+than it is at the present day, when, as we know full well, the
+movements are going on so slowly that they escape observation. Only
+here and there, as an attendant on earthquake shocks or other related
+movements of the crust, do we find any trace of the upward march which
+produces these elevations. Although not a subject for exact
+measurements, these features of mountain growth indicate a vast lapse
+of time, during which the elevations were formed and worn away.
+
+Yet another and very different method by which we may obtain some
+gauge of the depths of the past is to be found in the steps which have
+led organic life from its lowest and earliest known forms to the
+present state of advancement. Taking the changes of species which have
+occurred since the beginning of the last ice epoch, we find that the
+changes which have been made in the organic life have been very small;
+no naturalist who has obtained a clear idea of the facts will question
+the statement that they are not a thousandth part of the alterations
+which have occurred since the Laurentian time. The writer is of the
+opinion that they do not represent the ten thousandth part of those
+vast changes. These changes are limited in the main to the
+disappearance of a few forms, and to slight modifications in those
+previously in existence which have survived to the present day. So far
+as we can judge, no considerable step in the organic series has taken
+place in this last great period of the earth's history, although it
+has been a period when, as before noted, all the conditions have
+combined to induce rapid modifications in both animals and plants. If,
+then, we can determine the duration of this period, we may obtain a
+gauge of some general value.
+
+Although we can not measure in any accurate way the duration of the
+events which have taken place since the last Glacial period began to
+wane, a study of the facts seems to show that less than a hundred
+thousand years can not well be assumed for this interval. Some of the
+students who have approached the subject are disposed to allow a
+period of at least twice this length as necessary for the perspective
+which the train of events exhibits. Reckoning on the lowest estimate,
+and counting the organic changes which take place during the age as
+amounting to the thousandth part of the organic changes since the
+Laurentian age, we find ourselves in face once again of that
+inconceivable sum which was indicated by the physical record.
+
+Here, again, the critics assert that there may have been periods in
+the history of the earth when the changes of organic life occurred in
+a far swifter manner than in this last section of the earth's history.
+This supposition is inadmissible, for it rests on no kind of proof; it
+is, moreover, contraindicated by the evident fact that the advance in
+the organic series has been more rapid in recent time than at any
+stage of the past. In a word, all the facts with which the geologist
+deals are decidedly against the assumption that terrestrial changes in
+the organic or the inorganic world ever proceed in a spasmodic manner.
+Here and there, and from time to time, local revolutions of a violent
+nature undoubtedly occur, but, so far as we may judge from the aspect
+of the present or the records of the past, these accidents are
+strictly local; the earth has gone forward in its changes much as it
+is now advancing. Its revolutions have been those of order rather than
+those of accident.
+
+The first duty of the naturalist is to take Nature as he finds it. He
+must avoid supposing any methods of action which are not clearly
+indicated in the facts that he observes. The history of his own and of
+all other sciences clearly shows that danger is always incurred where
+suppositions as to peculiar methods of action are introduced into the
+interpretation. It required many centuries of labour before the
+students of the earth came to adopt the principle of explaining the
+problems with which they had to deal by the evidence that the earth
+submitted to them. Wherever they trusted to their imaginations for
+guidance, they fell into error. Those who endeavour to abbreviate our
+conception of geologic time by supposing that in the olden days the
+order of events was other than that we now behold are going counter to
+the best traditions of the science.
+
+Although the aspect of the record of life since the beginning of the
+Cambrian time indicates a period of at least a hundred million years,
+it must not be supposed that this is the limit of the time required
+for the development of the organic series. All the important types of
+animals were already in existence in that ancient period with the
+exception of the vertebrates, the remains of which have apparently now
+been traced down to near the Cambrian level. In other words, at the
+stage where we first find evidence of living beings the series to
+which they belong had already climbed very far above the level of
+lifeless matter. Few naturalists will question the statement that half
+the work of organic advance had been accomplished at the beginning of
+the Cambrian rocks. The writer is of the opinion that the development
+which took place before that age must have required a much longer
+period than has elapsed from that epoch to the present day. We thus
+come to the conclusion that the measurement of duration afforded by
+organic life indicates a yet more lengthened claim of events, and
+demands more time than appears to be required for the formation of the
+stratified rocks.
+
+The index of duration afforded by the organic series is probably more
+trustworthy than that which is found in the sedimentary strata, and
+this for the reason that the records of those strata have been
+subjected to numerous and immeasurable breaks, while the development
+of organic life has of necessity been perfectly continuous. The one
+record can at any point be broken without interrupting the sequences;
+the other does not admit of any breaches in the continuity.
+
+
+                             THE MOON.
+
+Set over against the earth--related to, yet contrasted with it in many
+ways--the moon offers a most profitable object to the student of
+geology. He should often turn to it for those lessons which will be
+briefly noted.
+
+In the beginning of their mutual history the materials of earth and
+moon doubtless formed one vaporous body which had been parted from the
+concentrating mass of the sun in the manner noted in the sketch of
+the history of the solar system. After the earth-moon body had
+gathered into a nebulous sphere, it is most likely that a ring
+resembling that still existing about Saturn was formed about the
+earth, which in time consolidated into the satellite. Thenceforth the
+two bodies were parted, except for the gravitative attraction which
+impelled them to revolve about their common centre of gravity, and
+except for the light and heat they might exchange with one another.
+
+The first stages after the parting of the spheres of earth and moon
+appear to have been essentially the same in each body. Concentrating
+upon their centres, they became in time fluid by heat; further on,
+they entered the rigid state--in a word, they froze--at least in their
+outer parts. At this point in their existence their histories utterly
+diverge; or rather, we may say, the development of the earth continued
+in a vast unfolding, while that of the moon appears to have been
+absolutely arrested in ways which we will now describe.
+
+With the naked eye we see on the moon a considerable variation in the
+light of different parts of its surface; we discern that the darker
+patches appear to be rudely circular, and that they run together on
+their margins. Seeing this little, the ancients fancied that our
+satellite had seas and lands like the earth. The first telescopes did
+not dispel their fancies; even down to the early part of this century
+there were astronomers who believed the moon to be habitable; indeed,
+they thought to find evidence that it was the dwelling place of
+intelligent beings who built cities, and who tried to signal their
+intellectual kindred of this planet. When, however, strong glasses
+were applied to the exploration, these pleasing fancies were rudely
+dispelled.
+
+Seen with a telescope of the better sort, the moon reveals itself to
+be in large part made up of circular depressions, each surrounded by a
+ringlike wall, with nearly level but rough places between. The
+largest of these walled areas is some four hundred miles in diameter;
+thence they grade down to the smallest pits which the glass can
+disclose, which are probably not over as many feet across. The writer,
+from a careful study of these pits, has come to the conclusion that
+the wider are the older and the smaller the last formed. The rude
+elevations about these pits--some of which rise to the height of ten
+thousand feet or more--constitute the principal topographic reliefs of
+the lunar surface. Besides the pits above mentioned, there are
+numerous fractures in the surface of the plains and ringlike ridges;
+on the most of these the walls have separated, forming trenches not
+unlike what we find in the case of some terrestrial breaks such as
+have been noted about volcanoes and elsewhere. It may be that the
+so-called canals of Mars are of the same nature.
+
+[Illustration: Fig. 23.--Lunar mountains near the Gulf of Iris.]
+
+The most curious feature on the moon's surface are the bands of
+lighter colour, which, radiating from certain of the volcanolike
+pits--those of lesser size and probably of latest origin--extend in
+some cases for five hundred miles or more across the surface. These
+light bands have never been adequately explained. It seems most likely
+that they are stains along the sides of cracks, such as are sometimes
+observed about volcanoes.
+
+The eminent peculiarity of the moon is that it is destitute of any
+kind of gaseous or aqueous envelope. That there is no distinct
+atmosphere is clearly shown by the perfectly sharp and sudden way in
+which the light of a star disappears when it goes behind the moon and
+the clear lines of the edge of the satellite in a solar eclipse. The
+same evidence shows that there is no vapour of water; moreover, a
+careful search which the writer has made shows that the surface has
+none of those continuous down grades which mark the work of water
+flowing over the land. Nearly all of the surface consists of shallow
+or deep pits, such as could not have been formed by water action. We
+therefore have not only to conclude that the moon is waterless, but
+that it has been in this condition ever since the part that is turned
+toward us was shaped.
+
+As the moon, except for the slight movement termed its "libration,"
+always turns the same face to us, so that we see in all only about
+four sevenths of its surface, it has naturally been conjectured that
+the unseen side, which is probably some miles lower than that turned
+toward us, might have a different character from that which we behold.
+There are reasons why this is improbable. In the first place, we see
+on the extreme border of the moon, when the libration turns one side
+the farthest around toward the earth, the edge of a number of the
+great walled pits such as are so plenty on the visible area; it is
+fair to assume that these rings are completed in the invisible realm.
+On this basis we can partly map about a third of the hidden side.
+Furthermore, there are certain bands of light which, though appearing
+on the visible side, evidently converge to some points on the other.
+It is reasonable to suppose that, as all other bands radiate from
+walled pits, these also start from such topographic features. In this
+way certain likenesses of the hidden area to that which is visible is
+established, thus making it probable that the whole surface of the
+satellite has the same character.
+
+Clearly as the greater part of the moon is revealed to us--so clearly,
+indeed, that it is possible to map any elevation of its surface that
+attains the height of five hundred feet--the interpretation of its
+features in the light of geology is a matter of very great
+difficulty. The main points seem to be tolerably clear; they are as
+follows: The surface of the moon as we see it is that which was formed
+when that body, passing from the state of fluidity from heat, formed a
+solid crust. The pits which we observe on its surface are the
+depressions which were formed as the mass gradually ceased to boil.
+The later formed of these openings are the smaller, as would be the
+case in such a slowing down of a boiling process.
+
+As the diameter of the moon is only about one fourth of that of the
+earth, its bulk is only about one sixteenth of that of its planet;
+consequently, it must have cooled to the point of solidification ages
+before the larger sphere attained that state. It is probable that the
+same changeless face that we see looked down for millions of years on
+an earth which was still a seething, fiery mass. In a word, all that
+vast history which is traceable in the rocks beneath our feet--which
+is in progress in the seas and lands and is to endure for an
+inconceivable time to come--has been denied our satellite, for the
+reason that it had no air with which to entrap the solar heat and no
+water to apply the solar energy to evolutionary processes. The heat
+which comes upon the moon as large a share for each equal area as it
+comes upon the earth flies at once away from the airless surface, at
+most giving it a temporary warmth, but instituting no geological work
+unless it be a little movement from the expansion and contraction of
+the rocks. During the ages in which the moon has remained thus
+lifeless the earth, owing to its air and water, has applied a vast
+amount of solar energy to geological work in the development and
+redevelopment of its geological features and to the processes of
+organic life. We thus see the fundamental importance of the volatile
+envelopes of our sphere, how absolutely they have determined its
+history.
+
+It would be interesting to consider the causes which led to the
+absence of air and water on the moon, but this matter is one of the
+most debatable of all that relates to that sphere; we shall therefore
+have to content ourselves with the above brief statements as to the
+vast and far-acting effects which have arisen from the non-existence
+of those envelopes on our nearest neighbour of the heavens.
+
+
+                  METHODS IN STUDYING GEOLOGY.
+
+So far as possible the preceding pages, by the method adopted in the
+presentation of facts, will serve to show the student the ways in
+which he may best undertake to trace the order of events exhibited in
+the phenomena of the earth. Following the plan pursued, we shall now
+consider certain special points which need to be noted by those who
+would adopt the methods of the geologist.
+
+At the outset of his studies it may be well for the inquirer to note
+the fact that familiarity with the world about him leads the man in
+all cases to a certain neglect and contempt of all the familiar
+presentations of Nature. We inevitably forget that those points of
+light in the firmament are vast suns, and we overlook the fact that
+the soil beneath our feet is not mere dirt, but a marvellous
+structure, more complicated in its processes than the chemist's
+laboratory, from which the sustenance of our own and all other lives
+is drawn. We feel our own bodies as dear but commonplace possessions,
+though we should understand them as inheritances from the
+inconceivable past, which have come to us through tens of thousands of
+different species and hundreds of millions of individual ancestors. We
+must overlook these things in our common life. If we could take them
+into account, each soul would carry the universe as an intellectual
+burden.
+
+It is, however, well from time to time to contemplate the truth, and
+to force ourselves to see that all this apparently simple and ordinary
+medley of the world about us is a part of a vast procession of events,
+coming forth from the darkness of the past and moving on beyond the
+light of the present day. Even in his professional work the
+naturalist of necessity falls into the commonplace way of regarding
+the facts with which he deals. If he be an astronomer, he catalogues
+the stars with little more sense of the immensities than the man who
+keeps a shop takes account of his wares. Nevertheless, the real profit
+of all learning is in the largeness of the understanding which it
+develops in man. The periods of growth in knowledge are those in which
+the mind, enriched by its store, enlarges its conception while it
+escapes from commonplace ways of thought. With this brief mention of
+what is by far the most important principle of guidance which the
+student can follow, we will turn to the questions of method that the
+student need follow in his ordinary work.
+
+With almost all students a difficulty is encountered which hinders
+them in acquiring any large views as to the world about them. This is
+due to the fact that they can not make and retain in memory clear
+pictures of the things they see. They remember words rather than
+things--in fact, the training in language, which is so large a part of
+an education, tends ever to diminish the element of visual memory. The
+first task of the student who would become a naturalist is to take his
+knowledge from the thing, and to remember it by the mental picture of
+the thing. In all education in Nature, whether the student is guided
+by his own understanding or that of the teacher, a first and very
+continuous aim should be to enforce the habit of recalling very
+distinct images of all objects which it is desired to remember. To
+this end the student should practise himself by looking intently upon
+a landscape or any other object; then, turning away, he should try to
+recall what he has beheld. After a moment the impression by the sight
+should be repeated, and the study of the memory renewed. The writer
+knows by his own experience that even in middle-aged people, where it
+is hard to breed new habits, such deliberate training can greatly
+increase the capacity of the memory for taking in and reproducing
+images which are deemed of importance. Practice of this kind should
+form a part of every naturalist's daily routine. After a certain time,
+it need not be consciously done. The movements of thought and action
+will, indeed, become as automatic as those which the trained fencer
+makes with his foil.
+
+Along with the habit of visualizing memories, and of storing them
+without the use of words, the student should undertake to enlarge his
+powers of conceiving spaces and directions as they exist in the field
+about him. Among savages and animals below the grade of man, this
+understanding of spacial relations is very clear and strong. It
+enables the primitive man to find his way through the trackless
+forest, and the carrier pigeon to recover his mate and dwelling place
+from the distance of hundreds of miles away. In civilized men,
+however, the habit of the home and street and the disuse of the
+ancient freedom has dulled, and in some instances almost destroyed,
+all sense of this shape of the external world. The best training to
+recover this precious capacity will now be set forth.
+
+The student should begin by drawing a map on a true scale, however
+roughly the work may be done, of those features of the earth about him
+with which he is necessarily most familiar. The task may well be begun
+with his own dwelling or his schoolroom. Thence it may be extended so
+as to include the plan of the neighbouring streets or fields. At
+first, only directions and distances should be platted. After a time
+to these indications should be added on the map lines indicating in a
+general way contours or the lines formed by horizontal planes
+intersecting the area subject to delineation. After attaining certain
+rude skill in such work, the student may advantageously make
+excursions to districts which he can see only in a hurried way. As he
+goes, he should endeavour to note on a sketch map the positions of the
+hills and streams and the directions of the roads. A year of holiday
+practice in such work will, if the tasks occupy somewhere about a
+hundred hours of his time, serve greatly to extend or reawaken what
+may be called the topographic sense, and enable him to place in terms
+of space the observations of Nature which he may make.
+
+In his more detailed work the student should select some particular
+field for his inquiry. If he be specially interested in geologic
+phenomena, he will best begin by noting two classes of facts--those
+exhibited in the rocks as they actually appear in the state of repose
+as shown in the outcrops of his neighbourhood, and those shown in the
+active manifestations of geological work, the decay of the rocks and
+the transportation of their waste, or, if the conditions favour, the
+complicated phenomena of the seashores.
+
+As soon as the student begins to observe, he should begin to make a
+record of his studies. To the novice in any science written, and
+particularly sketched, notes are of the utmost importance. These,
+whether in words or in drawings, should be made in face of the facts;
+they should, indeed, be set down at the close of an observation,
+though not until the observer feels that the object he is studying has
+yielded to him all which it can at that time give. It is well to
+remark that where a record is made at the outset of a study the
+student is apt to feel that he is in some way pledged to shape all he
+may see to fit that which he has first written. In his early
+experience as a teacher, the writer was accustomed to have students
+compare their work of observation and delineation with that done by
+trained men on the same ground. It now seems to him best for the
+beginner at first to avoid all such reference of his own work to that
+of others. So great is the need of developing independent motive that
+it is better at the outset to make many blunders than to secure
+accuracy by trust in a leader. The skilful teacher can give fitting
+words of caution which may help a student to find the true way, but
+any reference of his undertakings to masterpieces is sure to breed a
+servile habit. Therefore such comparisons are fitting only after the
+habit of free work has been well formed. The student who can afford
+the help of a master, or, better, the assistance of many, such as some
+of our universities offer, should by all means avail himself of this
+resource. More than any other science, geology, because of the
+complexity of the considerations with which it has to deal, depends
+upon methods of labour which are to a great extent traditional, and
+which can not, indeed, be well transmitted except in the personal way.
+In the distinctly limited sciences, such as mathematics, physics, or
+even those which deal with organic bodies, the methods of work can be
+so far set forth in printed directions that the student may to a great
+extent acquire sound ways of work without the help of a teacher.
+
+Although there is a vast and important literature concerning geology,
+the greater part of it is of a very special nature, and will convey to
+the beginner no substantial information whatever. It is not until he
+has become familiar with the field with which he is enabled to deal in
+the actual way that he can transfer experience thus acquired to other
+grounds. Therefore beyond the pleasing views which he may obtain by
+reading certain general works on the science, the student should at
+the outset of his inquiry limit his work as far as possible to his
+field of practice, using a good text-book, such as Dana's Manual of
+Geology, as a source of suggestions as to the problems which his field
+may afford.
+
+The main aim of the student in this, as in other branches of inquiry,
+is to gain practice in following out the natural series of actions. To
+the primitive man the phenomenal world presents itself as a mere
+phantasmagoria, a vast show in which the things seen are only related
+to each other by the fact that they come at once into view. The end of
+science is to divine the order of this host, and the ways in which it
+is marshalled in its onward movement and the ends to which its march
+appears to be directed. So far as the student observes well, and thus
+gains a clear notion of separated facts, he is in a fair way to
+gather the data of knowledge which may be useful; but the real value
+of these discernments is not gained until the observations go
+together, so as to make something with a perspective. Until the store
+of separate facts is thus arranged, it is merely crude material for
+thought; it is not in the true meaning science, any more than a store
+of stone and mortar is architecture. When the student has developed an
+appetite for the appreciation of order and sources of energy in
+phenomena, he has passed his novitiate, and becomes one of that happy
+body of men who not only see what is perceived by the mass of their
+fellows, but are enabled to look through those chains of action which,
+when comprehended, serve to rationalize and ennoble all that the
+senses of man, aided by the instruments which he has devised, tell us
+concerning the visible world.
+
+
+
+
+
+                                INDEX.
+
+    Ætna, Mount, 381.
+
+    Agriculture,
+      American, 346;
+      in England, winning swamp lands for, 335;
+      recent developments of, 345.
+
+    Alaska, changes on the coast of, 96.
+
+    Ants taking food underground, 319;
+      work of the, on the soil, 318.
+
+    Apsides, revolution of the, 61, 62.
+
+    Arabians, chemical experiments of the, 13.
+
+    Arches, natural, in cavern districts, 258.
+
+    Artesian wells, 258, 259.
+
+    Arts, advance of Italian fine, 19.
+
+    Asteroids, 53;
+      motions of, about their centres and about the sun, 53.
+
+    Astronomers, the solar system and the early, 79.
+
+    Astronomy, 31-80;
+      growth of, since the time of Galileo, 33, 34;
+      the first science, 10.
+
+    Atmosphere, 97-206;
+      along the tropical belt, 102;
+      as a medium of communication between different regions, 99;
+      deprived of water, containing little heat, 105;
+      beginning of the science of the, 117;
+      counter-trade movements of the, 105;
+      envelope of the earth, 98;
+      expansion of, in a hollow wall during the passage of a storm, 114;
+      heat-carrying power of the, 105;
+      heights to which it extends, 99;
+      in water, 99;
+      movements no direct influence on the surface of the earth, 122;
+      movements of the, qualified by the condition which
+            it encounters, 118;
+      of mountains, 98;
+      of the seashore, 98;
+      of the earth, 98;
+      of the sun, 73;
+      snow as an evidence of, 65;
+      supplying needs of underground creatures, 331;
+      uprushes of, 101, 102;
+      upward strain of the, next the earth, 107;
+      weight and motion of the, 120, 121.
+
+    Atmospheric circulation of the soil, 330, 331;
+      envelopes, 97.
+
+    Aurora borealis, 168.
+
+    Avalanches, 210-213;
+      dreaded, in the Alpine regions, 212;
+      great, in the Swiss Oberland, 211, 212;
+      rocky, 175-177.
+
+    Axis,
+      imaginary changes in the earth's, 59;
+      of the earth's rotation, 58;
+      polar, inclined position of, 58;
+      polar, nodding movement of the axes, 54;
+      rotations of the planetary spheres on their axes, 56.
+
+
+    Barometer, causes of changes in the, 117, 118.
+
+    Basalts, 309.
+
+    Beaches, 93, 142, 144;
+      boulder, 142, 143;
+      pebbly, 142;
+      sand, 144.
+
+    Beetles, work of, on the soil, 318, 319.
+
+    Belief of the early astronomers about the solar system, 79.
+
+    _Bergschrund_, the, 214.
+
+    Birds and mammals contributing to the fertility of the soil, 319.
+
+    "Blanketing," 269.
+
+    Bogs,
+      climbing, 331-334;
+      lake, 331-333;
+      peat, 334, 335;
+      quaking, 334.
+
+    Botany, rapid advance in, 14, 15.
+
+    Boulders, 217, 220.
+
+    Breakers, 135, 137, 139.
+
+    Bridges, natural, 257, 258.
+
+
+    Canals of Mars, 67.
+
+    Cañon, newly formed river cutting a, 195.
+
+    Cataracts, 193.
+
+    Caves, 253-258, 261;
+      architecture of, 255-258;
+      hot-water, 261;
+      mammoth cave, 258;
+      stalactites and stalagmites on the roof and floor of, 257.
+
+    Chasms, 140, 141.
+
+    Chemistry, 6, 12, 14;
+      advance of, 12;
+      modern, evolving from the studies of alchemists, 13, 14.
+
+    Chromosphere, 73.
+
+    Civilization of the Icelanders, 384.
+
+    Cliffs, sea-beaten, 132, 141, 142.
+
+    Climate,
+      changes of, due to modifications of the ocean streams, 153;
+      effect of the ocean on the, 147;
+      of the Gulf Stream, 149, 150.
+
+    Clouds, 159;
+      formation of, 162, 163;
+      shape of, 163;
+      water of, usually frozen, 207;
+      cloud-making, laws of, 161, 162.
+
+    Coast,
+      changes on the Scandinavian, 96;
+      line, effect of tide on the, 145;
+      of Greenland, 226;
+      of New Jersey sinking, 95;
+      marine, changes in, 95.
+
+    Cold in Siberia, 243.
+
+    Comets, 47, 50;
+      collisions of, 50;
+      kinship of meteorites and, 48;
+      omens of calamity to the ancients, 50;
+      the great, of 1811, 49, 50.
+
+    Cones. See under VOLCANOES.
+
+    Conflict between religion and science, 20, 22;
+      between the Protestant countries and the followers of science, 20.
+
+    Continental shelves, 125.
+
+    Continents and oceans, 83;
+      changes in position of, 91;
+      cyclones of the, 111;
+      forms of, 90;
+      proofs that they have endured for many years, 92;
+      shape of, 84, 96.
+
+    Coral reefs, 153, 353.
+
+    Corona, realm of the, 73.
+
+    Craters. See under VOLCANOES.
+
+    Crevasse, a barrier to the explorer, 218.
+
+    Crevice water, 250.
+
+    Curds, 214.
+
+    Currents,
+      coral reefs in Florida affecting the velocity of, 153;
+      equatorial, 150;
+      of the Gulf Stream, 147-149;
+      hot and cold, of the sea, 102;
+      ocean, 145;
+      oceanic action of trade winds on, 145;
+      effect on migration of, 157;
+      icebergs indicating, 243;
+      surface, history of, 172;
+      uprushing, near the equator, 106.
+
+    Cyclones, 111;
+      cause of, 111;
+      of North America, 111;
+      secondary storms of, 112.
+
+
+    Deltas, 173, 187.
+
+    Deposits, vein, 260, 261.
+
+    Deserts, interior, 158.
+
+    Dew, 159, 160;
+      a concomitant of cloudless skies, 160,
+        and vegetation, 160;
+      formation of, 159-161.
+
+    Diablerets, 174.
+
+    Diagram of a vein, 260;
+      showing development of swamp, 335;
+      how a portion of the earth's surface may be sunk by faulting, 374;
+      growth of mangroves, 340;
+      the effect of the position of the fulcrum point
+            in the movement of the land masses, 94.
+
+    Diameter of our sphere at the equator, 62;
+       of the earth, 82.
+
+    Dikes, 192, 293; 305-310;
+      abounding in volcanic cones, 305;
+      cutting through coal, 306;
+      driven upward, 307;
+      formation of, 305, 310;
+      material of, 307, 308;
+      representing movements of softened rock, 309;
+      their relation to volcanic cones, 307;
+      variations of the materials of, 307, 308;
+      waterfalls produced by, 192;
+      zone of, 306.
+
+    Dismal Swamp, 95, 333.
+
+    Distances,
+      general idea of, 27;
+      good way to study, 27, 28;
+      training soldiers to measure, 28.
+
+    Doldrums, 104, 109;
+      doldrum of the equator, 109;
+      of the hurricane, 109.
+
+    Drainage, imperfect, of a country affected by glaciers, 242.
+
+    Dunes, 123, 124, 325, 326, 387;
+      moulded, 387.
+
+    Duration of geological time, 389.
+
+    Dust accumulations from wind, in China, 122.
+
+
+    Earth,
+      a flattened sphere, 82;
+      air envelope of the, 98;
+      amount of heat falling from the sun on the, 41;
+      antiquity of the, 391;
+      atmosphere of the, 98;
+      attracting power of the, 127;
+      axis of the rotation of the, 58;
+      composition of the atmosphere of the, 98;
+      crust of the, affected by weight, 93;
+      deviation of the path of the, varied, 61;
+      diameter of the, 82;
+        of the, affected by loss of heat, 131;
+      difference in altitude of the surface of the, 83;
+      discovery that it was globular, 31, 32;
+      effect of imaginary changes in the relations of sun and, 59;
+      effect of the interior heat of the, 309, 310;
+      effect of the sun on the, 60, 61;
+      formerly in a fluid state, 82;
+      imaginary view of the, from the moon, 81;
+      important feature of the surface of the, 83;
+      jarring caused by faults, 367;
+      surface of the, determined by heat and light from the sun, 57;
+      most important feature of the surface of the, 83;
+      motion of the, affecting the direction of trade winds, 103;
+      movements, 366;
+      natural architecture of the, 377;
+      no part of the, exempt from movement, 384;
+      parting of the moon and, 396;
+      path of the, around the sun, 55, 56, 59, 60;
+      revolving from east to west, 103;
+      shrinking of the, from daily escape of heat, 89;
+      soil-covering of the, 343;
+      study of the, 81-96;
+      swaying, 385;
+      tensions, problem of, 371;
+      tremors, caused by chemical changes in the rocks, 385;
+      tropical belt of the, 74;
+      viewed from the surface of the moon, 311, 312;
+      water store of the, 125.
+
+    Earthquakes, 277, 278, 280, 356, 358, 370-384, 388-390;
+      accidents of, 358;
+      action of, 356;
+      agents of degradation, 383, 384;
+      basis of, 367;
+      certain limitations to, 380, 381;
+      Charleston, of 1883, 374, 375;
+      countries, architecture in, 381;
+      echoes, 369, 370;
+      damages of, 377, 390;
+      effect of,
+        on the soil, 375;
+        the surface of the earth, 371;
+      formed by riving of fissures, 382;
+      great, occurring where rocks have been
+            disturbed by mountain-building, 381, 382;
+      Herculaneum and Pompeii destroyed by an, 277, 280;
+      Italian, in 1783, 371, 372;
+      important, not connected with volcanic explosions, 381;
+      Jamaica, in 1692, 372, 376;
+      Lisbon, in 1755, 368, 369, 373, 374, 381;
+      maximum swing of, 369;
+      measuring the liability to, 386, 387;
+      mechanism of, 370, 371;
+      method of the study of, followed by Mr. Charles Mallet, 382, 383;
+      Mississippi, in 1811, 373, 374, 380, 381;
+      movement of the earth during, 377;
+      originating from a fault plane, 367, 369, 370;
+      originating from the seas, 358, 375;
+      oscillation of, 376;
+      poised rocks indicating a long exemption from strong, 388;
+      Riobamba, in 1797, 375;
+      shocks of, and their effect upon people, 383;
+      the direct calamities of Nature, 386;
+      waves of, 389.
+
+    Earthworms, 317-319;
+      taking food underground, 319.
+
+    Eclipses, record of ancient, 130.
+
+    Electrical action in the formation of rain and snow, 164.
+
+    Elevations of seas and lands, 83.
+
+    Energy indestructible, 23.
+
+    Envelope, lower, of the sun, 74.
+
+    Equator,
+      diameter of our sphere at the, 62;
+      doldrum of the, 109;
+      updraught under the, 102;
+      uprushing current near the, 106.
+
+    Equinoxes, precession of the, 61, 62.
+
+    _Eskers_, 221.
+
+    Expansion of air contained in a hollow wall during the
+            passage of the storm, 114.
+
+    Experiment, illustrating consolidation of disseminated
+            materials of the sun and planets, 40.
+
+
+    Falls. See WATERFALLS.
+
+    Fault planes, 382.
+
+    Feldspar, 324.
+
+    Floods, 180, 197;
+      rarity of, in New England, 121;
+      river, frequent east of Rocky Mountains, 198.
+
+    Föhns, 121.
+
+    Forests, salicified, 124.
+
+    Fossilization, 354-356.
+
+    Fulcrum point, 95.
+
+
+    Galactic plane, 45.
+
+    Galongoon, eruption of, 294.
+
+    Geological work of water, 168-206.
+
+    Glacial action in the valleys of Switzerland, 224;
+      periods, 63, 243, 246;
+      in the northern hemisphere, 246;
+      waste, 324.
+
+    Glaciation,
+      effect of,
+        in North America, 241;
+        in Central America, 234;
+        South America, 234.
+
+    Glaciers, 207-249;
+      action of ice in forming, 230-232;
+      Alaskan, 216;
+      continental, 225, 239, 240;
+      discharge of, 220;
+      exploring, 220;
+      extensive, in Greenland and Scandinavia, 244;
+      former, of North America, 232, 234;
+      map of, and moraines near Mont Blanc, 217;
+      motions of, 213;
+      retreat of the, 228, 230, 235;
+      secrets of the under ice of, 221;
+      speed of a, 224;
+      study of, in the Swiss valleys, 222;
+      testimony of the rocks regarding, 228;
+      when covered with winter snows, 216;
+      valley, 216.
+
+    Gombridge, 1830, 74.
+
+    Gravitation, law of, 4.
+
+    Greeks' idea of the heavens, 31;
+      not mechanically inventive, 22.
+
+    Gulf Stream, current of the, 147.
+
+
+    Heat,
+      amount of, daily escaping from the earth, 89;
+      amount of, falling from the sun on the earth, 41;
+      belief of the ancients regarding, 42;
+      dominating effect on air currents of tropical, 104;
+      energy with which it leaves the sun, 41;
+      internal,
+        of the earth, 88, 89;
+        of the earth's interior, 309, 310;
+      sun, effect on the atmosphere of the, 100;
+      Prof. Newcomb's belief regarding the, of the sun, 52;
+      radiation of the earth's, causing winds, 101;
+      solar, 41;
+      tropical, and air currents, 104.
+
+    Hills, sand, 123.
+
+    Horizontal pendulum, 384.
+
+    Horse latitudes, 104.
+
+    "Horses," 261.
+
+    Hurricanes, 107, 110, 317;
+      commencement of, 107;
+      doldrum of, 109;
+      felt near the sea, 110;
+      in the tropics, 110.
+
+    Hypothesis,
+      nebular, 34, 35, 39, 52, 56;
+      working, 4, 5.
+
+
+    Ice action,
+      effect of intense, 222, 223;
+      in forming glaciers, 230, 232;
+      recent studies in Greenland of, 239;
+      depth of, in Greenland, 227;
+      effect of, on river channels, 196;
+      effect of, on stream beds, 196;
+      expanding when freezing, 237;
+      epoch, 92, 93, 246;
+      floating, 242;
+      made soils rarely fertile, 241;
+      mass, greatest, in Greenland, 226, 227;
+      moulded by pressure, 215;
+      streams,
+        continental, 225, 226;
+        of the mountains, 225;
+        of the Himalayan Mountains, 234.
+
+    Icebergs, 242, 243;
+      indicating oceanic currents, 243.
+
+    Iceland, volcanic eruptions in, 297, 298.
+
+    Instruments, first, astronomical, 10, 11.
+
+    Inventions, mechanical, aiding science, 22.
+
+    Islands, 84, 272;
+      continental, 84;
+      in the deeper seas made up of volcanic ejections, 272;
+      volcanic, 272.
+
+
+    Jack-o'-lantern, 167.
+
+    Jupiter,
+      gaseous wraps of, 97;
+      path of the earth affected by, 59, 60;
+      the largest planet of the sun, 69.
+
+
+    Kames, 325.
+
+    Kant, Immanuel, and nebular hypothesis, 34.
+
+    Kaolin, 324.
+
+    Klondike district, cold in, 243, 244.
+
+    Krakatoa,
+      eruption of, 298-300;
+        effect of, on the sea, 299;
+        effect of, on the sun, 300.
+
+
+    Lacolites, 306.
+
+    Lacustrine beds, 351.
+
+    Lagoons, salt deposits found in, 200.
+
+    Lake basins,
+      formation of, 200, 201;
+      bogs, 331, 333, 334;
+      deposits, 350, 351.
+
+    Lakes, 199-206;
+      effect of, on the river system, 205;
+      fresh-water, 145;
+      formed from caverns, 202;
+      great, changing their outlets, 205;
+      of extinct volcanoes, 203;
+      temporary features of the land, 203;
+      volcanic, 203.
+
+    Lands,
+      great, relatively unchangeable, 96;
+      table, 91;
+      movements resulting in change of coast line, 351, 352;
+      shape of the seas and, 83, 84;
+      accounting for the changes in the attitude of the, 95;
+      and water, divisions of, 84;
+      dry, surface of, 85;
+      general statement as to the division of the, 83, 84;
+      surface, shape of the, 85;
+      triangular forms of great, 90.
+
+    Latitudes, horse, troublesome to mariners, 104.
+
+    Laplace and nebular hypothesis, 34.
+
+    Lava, 266-268, 270, 271, 292, 293, 295, 296, 303, 304;
+      flow of, invading a forest, 268;
+      from Vesuvius, 293;
+      of 1669, 295, 296;
+      temperature of, 295, 296;
+      incipient, 304;
+      outbreaks of, 292, 303;
+      stream eaves, 292, 293.
+
+    Law, natural,
+      Aristotle and, 3;
+      of gravitation, 4;
+      of the conservation of energy, 23.
+
+    Leaves, radiation of, 160.
+
+    Length of days affected by tidal action, 131.
+
+    Level surfaces, 91.
+
+    Life, organic, evolution of, 15, 16.
+
+    Light, belief of the ancients regarding, 42.
+
+    Lightning, 24, 164-168;
+      noise from, 166;
+      proceeding from the earth to the clouds, 165;
+      protection of buildings from, 165;
+      stroke, wearing-out effect of, 165.
+
+    Limestones, 353, 357, 358, 360, 364;
+      formation of, 357, 360.
+
+    Lisbon, earthquake of, 1755, 368, 369.
+
+    Lowell, Mr. Percival, observations on Venus, 64.
+
+    Lunar mountains near the Gulf of Iris, 397.
+
+
+    Mackerel sky, 35.
+
+    Mallet, Mr. Charles, and the study of earthquakes, 382, 383.
+
+    Man as an inventor of tools, 10.
+
+    Mangroves, 340;
+      diagram showing mode of growth, 340;
+      marshes of, 339.
+
+    Map of glaciers and moraines near Mont Blanc, 217;
+      of Ipswich marshes, 338.
+
+    Mapping with contour lines, 27.
+
+    Maps,
+      desirable, for the study of celestial geography, 77;
+      geographic sketch, 26, 27.
+
+    Marching sands jeopardizing agriculture, 123.
+
+    Marine animals, sustenance of, 361-363;
+      deposits, 325-327, 349, 356;
+      marshes, 336-340;
+      waves caused by earthquakes, 387.
+
+    Mars, 65-67, 84, 97;
+      belief that it has an atmosphere, 65;
+      canals of, 67;
+      gaseous wraps of, 97;
+      more efficient telescopes required for the study of, 67;
+      nearer to the earth than other planets, 65.
+
+    Marshes,
+      mangrove, 339;
+      map of Ipswich, 338;
+      marine, 336-340;
+      deposits found in, 336;
+      of North America, 337;
+      on the coast of New England, 339;
+      phenomena of, 167, 168;
+      tidal, good earth for tillage, 337;
+      tidal, of North America, 340.
+
+    Mercury, 55, 63, 78;
+      nearest to the sun, 63;
+      time in which it completes the circle of its year, 55.
+
+    Meteorites, 47, 48;
+      kinship of comets and, 48.
+
+    Meteors, 47;
+      falling, 47;
+      composition of, 48;
+      flashing, 39, 40, 47;
+      speed of, 47;
+      inflamed by friction with air, 99.
+
+    Methods in studying geology, 400.
+
+    Milky Way, 45;
+      voyage along the path of the, 44, 45.
+
+    Mineral crusts, 328, 329;
+      deposits, 308.
+
+    Moon, 38, 395-400;
+      absence of air and water on the, 399;
+      attended by satellites, 57;
+      attraction which it exercises on the earth, 62;
+      curious feature of the, 397;
+      destitute of gaseous or aqueous envelope, 397;
+      diameter of the, 399;
+      imaginary view of the earth from the, 81;
+      "libration" of the, 398;
+      made up of circular depressions, 396, 397;
+      movements of the, 78;
+      no atmosphere in the, 97;
+      parting of the earth and, 396;
+      position of the, in relation to the earth, 62;
+      tidal action and the, 131;
+      tides of the, 126, 127;
+      why does the sun not act in the same manner as the, 78.
+
+    Moraines, 216, 218, 229, 230;
+      map of glaciers and, near Mont Blanc, 217;
+      movements of the, 216-218;
+      terminal, 228.
+
+    _Moulin_, 219.
+
+    Mount Ætna, 288-310;
+      lava yielding, 290, 293, 294;
+      lava stream caves of, 292, 293;
+      more powerful than Vesuvius, 297;
+      peculiarities of, 291, 292;
+      size of, 289-291;
+      turning of the torrents of, 295.
+
+    Mountain-building, 90-93, 304;
+      folding, 86, 87, 90, 365;
+        attributed to cooling of the earth, 88;
+      growth, 392;
+      Swiss falls, 174;
+      torrents, energy of, 177.
+
+    Mountains, 85, 86, 89, 90-93; 174-178;
+      form and structure of, 86;
+      partly caused by escape of heat from the earth, 89;
+      sections of, 87.
+
+    Mount Nuova, formation of, 284.
+
+    Mount Vesuvius, 263-285, 288, 289, 293, 302, 381;
+      description of the eruption of, in A.D. 79, 277-280;
+      diagrammatic sections through, showing changes in the form
+            of the cone, 283;
+      eruption of, in 1056, 281;
+      in 1882-'83, 264, 266;
+      eruption of, in 1872, 282;
+      eruptions of, increased since 1636, 282;
+      flow of lava from, 285;
+      likely to enter on a period of inaction, 282, 283;
+      outbreak of, in 1882-'83, 264, 266.
+
+
+    Naples, prosperity of the city, 289.
+
+    Nebular hypothesis, 34, 35, 39, 52.
+
+    Neptune, 70.
+
+    _Névé_, the, 214;
+      no ice-cutting in the region of the, 224.
+
+    Newcomb's (Prof.) belief regarding the heat of the sun, 52.
+
+    Niagara Falls, 191, 192, 204;
+      cutting back of, 204.
+
+    North America,
+      changes in the form of, 91, 92;
+      triangular form of, 90.
+
+
+    Ocean,
+      average depth of the, 89;
+      climatal effect of the, 147;
+      currents, 145;
+      effect of, on migration, 156;
+      effect of, on organic life, 154;
+      floor, 85, 93;
+      hot and cold currents of the, 102;
+      sinking of the, 93, 94;
+      the laboratory of sedimentary deposits, 351;
+      depth of the, 89, 126.
+
+    Oceanic circulation, effect of, on the temperature, 152.
+
+    Oceans and continents, 83.
+
+    Orbit,
+      alterations of the, and the seasons, 60, 61;
+      changing of the, 59-63;
+      shape of the, 61-63.
+
+    Organic life, 315, 317, 321, 352, 353, 363;
+      action of, on the soil, 317, 321;
+      advantages of the shore belt to, 363;
+      development of in the sea, 352, 353;
+      effect of ocean currents on, 154;
+      processes of, in the soil, 315;
+      decay of, in the earth, 321.
+
+    Orion, 46.
+
+    Oscillations of the shores of the Bay of Naples, 287.
+
+    Oxbow of a river, 182, 183.
+
+    Oxbows and cut-off, 182.
+
+
+    Pebbles,
+      action of seaweeds on, 143;
+      action of the waves on, 142, 144.
+
+    Photosphere, 74.
+
+    Plains, 86;
+      alluvial, 91, 179, 182, 184-186, 325;
+      history of, 91;
+      sand, 325.
+
+    Planets, 38;
+      attended by satellites, 57;
+      comparative sizes of the, 68;
+      experiments illustrating consolidation of disseminated
+            materials of the sun and, 40;
+      gaseous wraps of, 97;
+      important observations by the ancients of fixed stars
+            and planets, 43;
+      movements of, 57-61;
+      outer, 78;
+      table of relative masses of sun and, 77.
+
+    Plant life in the Sargassum basins, 156.
+
+    Plants and animals,
+      protection of,
+        by mechanical contrivances, 364;
+        and trees, work of the roots of, on the soil, 316, 317;
+      water-loving, 181;
+      forming climbing bogs, 332.
+
+    Polar axes, nodding movement of, 54.
+
+    Polar snow cap, 66.
+
+    Polyps, 155, 353.
+
+    Pools, circular, 203.
+
+    Prairies, 340, 342.
+
+
+    Radiation of heat, 159.
+
+    Rain, 152, 156, 164, 168, 170, 328, 330;
+      circuit of the, 156-168;
+      drops, force of, 169, 170;
+      spheroidal form of, 170;
+      electrical action in the formation of snow and, 164;
+      work of the, 171.
+
+    Realm, unseen solar, 75.
+
+    Reeds, 332.
+
+    Religion,
+      conflict between science and, 20, 22;
+      struggle between paganism and, 21.
+
+    Rivers and _débris_, 183;
+      changes in the course of, in alluvial plain, 182;
+      deposition of, accelerated by tree-planting, 181;
+      great, always clear, 205;
+      inundation of the Mississippi, eating away land, 182;
+      muds, 222;
+      newly formed, cutting a cañon, 195;
+      of snow-ice, 211;
+      origin of a normal, 173;
+      oxbow of a, 182,183;
+      sinking of, 199;
+      swinging movement of, 179-181;
+      river-valleys, 193, 194;
+      diversity in the form of 188-191.
+
+    Rocks, 145;
+      accidents from falling, 174;
+      cut away by sandstones, 188;
+      divided by crevices, 252;
+      duration of events recorded in, 389, 390,
+      ejection of, material, 311;
+      falling of, 174-176;
+      formation of, 262, 263;
+      from the present day to the strata of the Laurentian, 390;
+      migration of, 291;
+      poised, indicating a long exemption from strong earthquakes, 388;
+      rents in, 252, 253;
+      stratification of, 349, 350, 352, 365, 390;
+      testimony of the, in regard to glaciers, 228;
+      under volcanoes, 303;
+      variable elasticity of, 366;
+      vibration of, 367, 368;
+      rock-waste, march of the, 343;
+      water, 250, 267.
+
+    Rotation of the earth affected by tides, 130;
+      of the planetary spheres on their axes, 56.
+
+
+    Salicified forests, 124.
+
+    Salt deposits formed in lagoons, 200;
+      found in lakes, 199-200.
+
+    Sand bars, 183;
+      endurance of, against the waves, 145;
+      hills, travelling of, 123;
+      marching, 123;
+      silicious stones cutting away rooks, 188.
+
+    Satellites, 53, 54;
+      motions of, about their centres and about the sun, 53, 54.
+
+    Saturn, 38, 53, 57, 396;
+      cloud bands of, 70;
+      gaseous wraps of, 97;
+      path of the earth affected by, 59, 60.
+
+    Savages, primitive, students of Nature, 1.
+
+    Scandinavia, changes on the coasts of, 96.
+
+    Science,
+      advance of, due to mechanical inventions, 22;
+      astronomy beginning with, 10;
+      chemical, characteristics of, 14;
+      conflict between religion and, 20, 22;
+      conflict between the Roman faith and, 20;
+      mechanical inventions as aids to, 22, 23;
+      modern and ancient, 4;
+      natural, 5, 6;
+      of botany in Aristotle's time, 14;
+      of physiology, 15;
+      of zoölogy in Aristotle's time, 14;
+      resting practically on sight, 10.
+
+    Scientific development,
+      historic outlines of, 17;
+      tools used in measuring and weighing, as an aid to vision, 12.
+
+    Sea,
+      battering action of the, 140;
+      coast ever changing, 385, 386;
+      effect of volcanic eruptions on the, 299;
+      floor deposits of the, affected by volcanoes, 360, 361;
+      in receipt of organic and mineral matter, 359;
+      hot and cold currents of the, 102;
+      littoral zone of the, 351, 352;
+      puss, 142;
+      rich in organic life, 352, 353;
+      solvent action of the, 361;
+      strata, formation of, 354;
+      water, minerals in, 185;
+      weeds, 155, 156.
+
+    Seas, dead,
+      originally living lakes, 200;
+      water of, buoyant, 199;
+      eventually the seat of salt deposits, 199-201;
+      general statement as to division of, 83, 84;
+      shape of the, 83, 84.
+
+    Seashore, air of the, 98.
+
+    Seasons, changing the character of the, 61, 62.
+
+    Sense of hearing, 9,10;
+      of sight, 10;
+      of smell, 9, 10;
+      of taste, 9, 10;
+      of touch, 9, 10.
+
+    _Seracs_, 214.
+
+    Shocks, earthquake. See under EARTHQUAKES.
+
+    Shore lines, variation of, 83, 84.
+
+    Shores, cliff, 138-142.
+
+    Sink holes, 202;
+      in limestone districts, 253, 254.
+
+    Skaptar,
+      eruption of, 297, 298;
+      lava from the eruption of, 298.
+
+    Sky, mackerel, 35.
+
+    Snow, 207-225, 244;
+      as an evidence of atmosphere, 65;
+      blankets, early flowers beginning to blossom under, 208;
+      covering, difference between an annual and perennial, 210;
+      effect of, on plants, 208;
+      electrical action in the formation of rain and, 164;
+      flakes, formation of, 164;
+      red, 210;
+      slides, 210;
+      slides, phenomena of, 210, 211.
+
+    Soil,
+      alluvial, 321, 322;
+      atmospheric circulation of, 330, 331;
+      conditions leading to formation of, 313, 331;
+      continuous motion of the, 314;
+      covering of the earth, 343;
+      decay of the, 314, 315;
+      degradation of the, 344-348;
+      means for correcting, 346-348;
+      destruction in grain fields greater than the accumulation, 344;
+      developing on lava and ashes an interesting study, 343;
+      development of, in desert regions, 340;
+      effect of animals and plants on the, 317-320;
+      effect of earthquakes on the, 375;
+      fertility of the, distinguished from the coating, 344, 345;
+      fertility of, affected by rain, 327;
+      formation of, 314-321;
+      glacial, characteristics of, 324;
+      glaciated, 323, 324;
+      irrigation of the, 328-330;
+      local variation of, 327;
+      mineral, 321;
+      of arid regions fertile when subjected to irrigation, 341;
+      of dust or blown sand, 321;
+      of immediate derivation, 321, 322;
+      phenomena, 313;
+      processes of organic life in the, 315;
+      variation in, 321-331;
+      vegetation protecting the, 316, 317;
+      washing away of the, 346, 347;
+      winning, from the sea, 337;
+      work of ants on the, 318;
+      tiller, duty of the, 348.
+
+    Solar bodies,
+      general conditions of the, 63-71;
+      forces, action of, on the earth, 349;
+      system, 52, 56;
+      independent from the fixed stars system, 43;
+      original vapour of, 52, 53;
+      singular features of our, 68;
+      tide, 127.
+
+    Spheres,
+      difference in magnitude of, 51;
+      motions of the, 50, 51;
+      planetary, rotation of, on their axes, 56.
+
+    Spots, sun, 72.
+
+    Spouting horn, 141.
+
+    Springs, formation of small, 252.
+
+    Stalactitization, 256.
+
+    Stalagmites and stalactites on the roof and floor of a cavern, 257.
+
+    Stars as dark bodies in the heavens, 47;
+      discovery of Fraunhofer and others on, 23, 38;
+      double, 39;
+      and tidal action, 131;
+      earliest study of, 10;
+      fixed, important observations by the ancients of planets and, 43;
+      not isolated suns, 38, 39;
+      variation in the light of, 46;
+      limit of, seen by the naked eye, 11;
+      revolution of one star about another, 46, 47;
+      shooting, 47;
+      speed of certain, 51;
+      study of, 31-80;
+      sudden flashing forth of, due to catastrophe, 46;
+      voyage through the, 44, 45;
+      star, wandering, 74.
+
+    Stellar realm, 31-80.
+
+    Storms,
+      circular, 111;
+      desert, 121, 122;
+      expansion of air contained in a hollow wall during
+            the passage of, 114;
+      great principle of, 105, 106;
+      in the Sahara, 121;
+      lightning, more frequent in summer, 167;
+      paths of, 115;
+      secondary, of cyclones, 112;
+      spinning, 115;
+      thunder, 165-167;
+      whirling, 106, 124;
+      whirling peculiarity of, 108, 109.
+
+    Strabo, writings of, 18.
+
+    Sun,
+      atmosphere of the, 73;
+      constitution of the, 72;
+      distance of the earth from the, 29;
+      effect from changes in the, and earth, 59;
+      envelope of the, 73, 74, 97;
+      experiments illustrating consolidation of disseminated
+            materials of planets and, 40;
+      finally, dark and cold, 42;
+      formation of the eight planets of the, 53;
+      heat leaving the, 41;
+      heat of the, 76;
+      imaginary journey from the, into space, 44;
+      mass of the, 76, 77;
+      path of the earth around the, 55;
+      physical condition of the, 71;
+      Prof. Newcomb's belief regarding the heat of the, 52;
+      spots, 75;
+        abundant at certain intervals, 72;
+        difficulty in revealing cause of, 75;
+      structure of the, a problem before the use of the telescope, 72;
+      table of relative masses of, and planets, 77;
+      three stages in the history of the, 71;
+      tides, 126;
+      why does it not act in the same manner as the moon? 78.
+
+    Surfaces, level, 90.
+
+    Surf belt, swayings of the, 137.
+
+    Swamps,
+      diagram showing remains of, 335;
+      Dismal Swamp, 95, 333;
+      drainage of, 334, 335;
+      fresh-water, 334, 335;
+      phenomena of, 167, 168.
+
+
+    Table-lands, 91.
+
+    Table of relative masses of sun and planets, 77.
+
+    Telescopes, 11, 12, 45;
+      first results of, 72;
+      power of, 11;
+      revelations of, 45.
+
+    Temperature,
+      effects of, produced by vibration, 42;
+      in the doldrum belt, 118;
+      of North America, 118;
+      of the Atlantic Ocean, 118.
+
+    Tempests, rate of, 99, 100.
+
+    Thunder, 166;
+      more pronounced in the mountains, 166.
+
+    Thunderstorms, 165, 166;
+      distribution of, 166, 167.
+
+    Tidal action,
+      recent studies of, 131, 132;
+      marshes of North America, 340.
+
+    Tides,
+      carving channels, 129;
+      effecting the earth's rotation, 130;
+      effect of, on marine life, 130;
+      height of, 128, 129;
+      moon and sun, 126, 127;
+      normal run of the, 127;
+      production of, 131;
+      of the trade winds, 150;
+      solar, 127;
+      travelling of, 127, 128.
+
+    Tillage introducing air into the pores of the soil, 331.
+
+    Tornadoes, 112, 113, 317;
+      development of, 113;
+      effect of, on buildings, 113;
+      fiercest in North America, 113;
+      length of, 115;
+      resemblance of, to hurricanes, 115;
+      upsucking action of, 114, 115.
+
+    Torrents, 177-179, 204.
+
+    Trade winds. See under WINDS.
+
+    Training in language,
+      diminishing visual memory, 401;
+      soldiers to measure distances, 28;
+        to measure intervals of time, 28;
+      for a naturalist, 25-29.
+
+    Tunnels, natural, 257.
+
+
+    Uranus, 70.
+
+
+    Valley of Val del Bove formed from disturbances of Mount Ætna, 294.
+
+    Valleys,
+      diversity in the form of river, 188-191;
+      river, 193.
+
+    Vapour, 156, 157, 159, 163;
+      gravitative attraction of, 34, 35;
+      nebular theory of, 52, 53;
+      original, of the solar system, 52, 53.
+
+    Vegetation,
+      and dew, 160;
+      in a measure, independent of rain, 160;
+      protecting the soil, 316, 317.
+
+    Vein, diagram of a, 260.
+
+    Venus, 64, 78;
+      recent observations of, by Mr. Percival Lowell, 64.
+
+    Vesuvian system, study of the, 285.
+
+    Vesuvius. See MOUNT VESUVIUS.
+
+    Visualizing memories, 402, 403.
+
+    Volcanic action, 268-276.
+
+    Volcanic eruption of A.D. 79, 288;
+      important facts concerning, 276-279;
+      islands, 272;
+      lava a primary feature in, 266;
+      observations of, made from a balloon, 301;
+      peaks along the floor of the sea, 272, 273;
+      possibility of throwing matter beyond control of gravitative
+            energy, 300.
+
+    Volcanoes, 125, 203, 263;
+      abounding on the sea floor, 302;
+      accidents from eruptions of, 288;
+      along the Pacific coast, 271;
+      ash showers of, maintaining fertility of the soil, 289;
+      distribution of, 271;
+      eruption of, 286-294, 368;
+      explosions from, coming from a supposed liquid interior
+            of the earth, 275;
+      exporting earth material, 310;
+      little water, 375;
+      Italian, considered collectively, 296, 297;
+      Neapolitan eruptions of and the history of civilization, 288;
+      subsidence of the earth after eruption of, 287, 291;
+      origin of, 263-274;
+      phenomena of, 263-267;
+      submarine, 301;
+      travelling of ejections from, 287, 288.
+
+
+    Waters,
+      crevice, 250;
+        of the earth, 250, 251;
+      cutting action of, 117, 192;
+      drift, from the poles, 151;
+      journey of, from the Arctic Circle to the tropics, 151, 152;
+      dynamic value of, 171;
+      expansion of, in rocks, 270;
+      geological work of, 168-206;
+      in air, 99;
+      of the clouds usually frozen, 207;
+      pure, no power for cutting rocks, 204;
+      rock, 250, 263;
+      sea, minerals in, 185;
+      store of the earth, 125;
+      system of, 125, 156;
+      tropical, 151;
+      velocity of the, under the equator, 150;
+      wearing away rocks, 178, 179;
+      underground, carrying mineral matter to the sea, 193;
+      chemical changes of, leading to changes in rock material, 262, 263;
+      effect of carbonic-acid gas on, 251;
+      operations of the, 126;
+      wearing away rocks, 178, 179;
+      work of, 250.
+
+    Waterfalls, 189-193;
+      cause of, 191;
+      the Yosemite, 192;
+      Niagara, 191, 192;
+      numerous in the torrent district of rivers, 192;
+      produced by dikes, 192;
+      valuable to manufactures, 192, 193.
+
+    Waterspouts, 115, 116;
+      atmospheric cause of, 116;
+      firing at, 116;
+      life of a, 116;
+      picturesqueness of, 116;
+      the water of fresh, 117.
+
+    Waves, 128, 129, 132, 145;
+      action of friction on, 135, 136;
+      break of the, 136;
+      endurance of sand against the, 145;
+      force of, 133, 136, 139;
+      marine, caused by earthquakes, 387;
+      of earthquakes, 389;
+      peculiar features in the action of, 137;
+      size of, 137, 138;
+      stroke of the, 144;
+      surf, 135;
+      tidal height of, 132;
+      undulations of, 132;
+      wind, 132;
+      wind influence of, on the sea, 134, 135;
+      wind-made, 128.
+
+    Ways and means of studying Nature, 9.
+
+    Weeds of the sea, 155.
+
+    Well, artesian, 258, 259.
+
+    Whirling of fluids and gas, 36, 37.
+
+    Whirlwinds in Sahara, 121.
+
+    Will-o'-the-wisp, 167.
+
+    Winds, 101, 110, 122, 317;
+      effect of sand, 122;
+      hurricane, 110;
+      illustration of how they are produced, 101;
+      in Martha's Vineyard, 120;
+      of the forests, work of the, 317;
+      of tornadoes, effect of, 113;
+      on the island of Jamaica, 119, 120;
+      regimen of the, 119;
+      variable falling away in the nighttime, 100;
+      trade, 102-105; 145, 146, 150;
+      action of, on ocean currents, 145:
+      affected by motion of the earth, 103;
+      belt, motion of the ocean in, 146;
+      flow and counter-flow of the, 150;
+      tide of the, 150;
+      uniform condition of the, 102;
+      waves, work of, 132, 134, 135.
+
+    Witchcraft, belief of, in the early ages, 21.
+
+
+    Zoölogy, rapid advance in, 14, 15.
+
+
+
+
+
+
+End of the Project Gutenberg EBook of Outlines of the Earth's History, by 
+Nathaniel Southgate Shaler
+
+*** END OF THIS PROJECT GUTENBERG EBOOK OUTLINES OF THE EARTH'S HISTORY ***
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+<pre>
+
+The Project Gutenberg EBook of Outlines of the Earth's History, by 
+Nathaniel Southgate Shaler
+
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever.  You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at www.gutenberg.org
+
+
+Title: Outlines of the Earth's History
+       A Popular Study in Physiography
+
+Author: Nathaniel Southgate Shaler
+
+Release Date: June 12, 2006 [EBook #18562]
+
+Language: English
+
+Character set encoding: ISO-8859-1
+
+*** START OF THIS PROJECT GUTENBERG EBOOK OUTLINES OF THE EARTH'S HISTORY ***
+
+
+
+
+Produced by Brendan Lane, Riikka Talonpoika, Jeroen van
+Luin and the Online Distributed Proofreading Team at
+http://www.pgdp.net
+
+
+
+
+
+
+</pre>
+
+
+<div class="figcenter" style="width: 640px;">
+<a name="img01"></a>
+<img src="images/p1.jpg" width="640" height="405" alt="Dunes at Ipswich Light, Massachusetts. Note the
+effect of bushes in arresting the movement of the wind-blown sand." title="" />
+<span class="caption">Dunes at Ipswich Light, Massachusetts.
+Note the effect of bushes in arresting the movement of the wind-blown sand.</span>
+</div>
+
+<p><span class='pagenum'><a name="Page_i" id="Page_i">[Pg i]</a></span></p>
+
+
+<div class="title1">OUTLINES OF THE<br/>EARTH'S HISTORY</div>
+
+<div class="title3">A POPULAR STUDY IN PHYSIOGRAPHY</div>
+
+<div class="title3">BY</div>
+
+<div class="title2">NATHANIEL SOUTHGATE SHALER</div>
+
+<div class="title4">PROFESSOR OF GEOLOGY IN HARVARD UNIVERSITY<br/>DEAN OF LAWRENCE SCIENTIFIC SCHOOL</div>
+
+<div class="title3"><span class="title3">ILLUSTRATED</span><br/><span class="title4">WITH INDEX</span></div>
+
+<div class="title3">NEW YORK AND LONDON</div>
+<div class="title2">D. APPLETON AND COMPANY</div>
+
+<div class="title3">1898, 1910</div>
+
+<p><span class='pagenum'><a name="Page_ii" id="Page_ii">[Pg ii]</a></span></p>
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_iii" id="Page_iii">[Pg iii]</a></span></p>
+
+<h1><a name="PREFACE" id="PREFACE"></a>PREFACE.</h1>
+
+<p>The object of this book is to provide the beginner in the study of the
+earth's history with a general account of those actions which can be
+readily understood and which will afford him clear understandings as
+to the nature of the processes which have made this and other
+celestial spheres. It has been the writer's purpose to select those
+series of facts which serve to show the continuous operations of
+energy, so that the reader might be helped to a truer conception of
+the nature of this sphere than he can obtain from ordinary text-books.</p>
+
+<p>In the usual method of presenting the elements of the earth's history
+the facts are set forth in a manner which leads the student to
+conceive that history as in a way completed. The natural prepossession
+to the effect that the visible universe represents something done,
+rather than something endlessly doing, is thus re-enforced, with the
+result that one may fail to gain the largest and most educative
+impression which physical science can afford him in the sense of the
+swift and unending procession of events.</p>
+
+<p>It is well known to all who are acquainted with the history of geology
+that the static conception of the earth&mdash;the idea that its existing
+condition is the finished product of forces no longer in action&mdash;led
+to prejudices which have long retarded, and indeed still retard, the
+progress of that science. This fact indicates that at the outset of a
+student's work in this field he should be guarded<span class='pagenum'><a name="Page_iv" id="Page_iv">[Pg iv]</a></span> against such
+misconceptions. The only way to attain the end is by bringing to the
+understanding of the beginner a clear idea of successions of events
+which are caused by the forces operating in and on this sphere. Of all
+the chapters of this great story, that which relates to the history of
+the work done by the heat of the sun is the most interesting and
+awakening. Therefore an effort has been made to present the great
+successive steps by which the solar energy acts in the processes of
+the air and the waters.</p>
+
+<p>The interest of the beginner in geology is sure to be aroused when he
+comes to see how very far the history of the earth has influenced the
+fate of men. Therefore the aim has been, where possible, to show the
+ways in which geological processes and results are related to
+ourselves; how, in a word, this earth has been the well-appointed
+nursery of our kind.</p>
+
+<p>All those who are engaged in teaching elementary science learn the
+need of limiting the story they have to tell to those truths which can
+be easily understood by beginners. It is sometimes best, as in stating
+such difficult matters as those concerning the tides, to give
+explanations which are far from complete, and which, as to their mode
+of presentation, would be open to criticism were it not for the fact
+that any more elaborate statements would most likely be
+incomprehensible to the novice, thus defeating the teacher's aim.</p>
+
+<p>It will be observed that no account is here given of the geological
+ages or of the successions of organic life. Chapters on these subjects
+were prepared, but were omitted for the reason that they made the
+story too long, and also because they carried the reader into a field
+of much greater difficulty than that which is found in the physical
+history of the earth.</p>
+
+<p class="ralign">N.S.S.</p>
+
+<p><i>March, 1898.</i></p>
+
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_v" id="Page_v">[Pg v]</a></span></p>
+<h1><a name="CONTENTS" id="CONTENTS"></a>CONTENTS.</h1>
+
+
+<table summary="">
+<tr><td class="ralign">I.&mdash;</td><td><a href="#CHAPTER_I"><span class="smcap">Introduction to the study of Nature</span></a></td></tr>
+<tr><td class="ralign">II.&mdash;</td><td><a href="#CHAPTER_II"><span class="smcap">Ways and means of studying Nature</span></a></td></tr>
+<tr><td class="ralign">III.&mdash;</td><td><a href="#CHAPTER_III"><span class="smcap">The stellar realm</span></a></td></tr>
+<tr><td class="ralign">IV.&mdash;</td><td><a href="#CHAPTER_IV"><span class="smcap">The earth</span></a></td></tr>
+<tr><td class="ralign">V.&mdash;</td><td><a href="#CHAPTER_V"><span class="smcap">The atmosphere</span></a></td></tr>
+<tr><td class="ralign">VI.&mdash;</td><td><a href="#CHAPTER_VI"><span class="smcap">Glaciers</span></a></td></tr>
+<tr><td class="ralign">VII.&mdash;</td><td><a href="#CHAPTER_VII"><span class="smcap">The work of underground water</span></a></td></tr>
+<tr><td class="ralign">VIII.&mdash;</td><td><a href="#CHAPTER_VIII"><span class="smcap">The soil</span></a></td></tr>
+<tr><td class="ralign">IX.&mdash;</td><td><a href="#CHAPTER_IX"><span class="smcap">The rocks and their order</span></a></td></tr>
+</table>
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_vi" id="Page_vi">[Pg vi]</a></span></p>
+
+<h1><a name="LIST_OF_FULL-PAGE_ILLUSTRATIONS" id="LIST_OF_FULL-PAGE_ILLUSTRATIONS"></a>LIST OF FULL-PAGE ILLUSTRATIONS.</h1>
+
+<table summary="">
+<tr><td><a href="#img01">Dunes at Ipswich Light, Massachusetts</a></td></tr>
+<tr><td><a href="#img02">Seal Rocks near San Francisco, California</a></td></tr>
+<tr><td><a href="#img03">Lava stream, in Hawaiian Islands, flowing into the sea</a></td></tr>
+<tr><td><a href="#img04">Waterfall near Gadsden, Alabama</a></td></tr>
+<tr><td><a href="#img05">South shore, Martha's Vineyard, Massachusetts</a></td></tr>
+<tr><td><a href="#img06">Pocket Creek, Cape Ann, Massachusetts</a></td></tr>
+<tr><td><a href="#img07">Muir Glacier, Alaska</a></td></tr>
+<tr><td><a href="#img08">Front of Muir Glacier</a></td></tr>
+<tr><td><a href="#img09">Mount &AElig;tna, seen from near Catania</a></td></tr>
+<tr><td><a href="#img10">Mountain gorge, Himalayas, India</a></td></tr>
+</table>
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_1" id="Page_1">[Pg 1]</a></span></p>
+
+<h1><a name="CHAPTER_I">CHAPTER &nbsp; I.</a><br/>
+<span class="smcap subtitle">an introduction to the study of nature.</span></h1>
+
+
+<p>The object of this book is to give the student who is about to enter
+on the study of natural science some general idea as to the conditions
+of the natural realm. As this field of inquiry is vast, it will be
+possible only to give the merest outline of its subject-matter, noting
+those features alone which are of surpassing interest, which are
+demanded for a large understanding of man's place in this world, or
+which pertain to his duties in life.</p>
+
+<p>In entering on any field of inquiry, it is most desirable that the
+student should obtain some idea as to the ways in which men have been
+led to the knowledge which they possess concerning the world about
+them. Therefore it will be well briefly to sketch the steps by which
+natural science has come to be what it is. By so doing we shall
+perceive how much we owe to the students of other generations; and by
+noting the difficulties which they encountered, and how they avoided
+them, we shall more easily find our own way to knowledge.</p>
+
+<p>The primitive savages, who were the ancestors of all men, however
+civilized they may be, were students of Nature. The remnants of these
+lowly people who were left in different parts of the world show us
+that man was not long in existence before he began to devise some
+explanation concerning the course of events in the outer world.<span class='pagenum'><a name="Page_2" id="Page_2">[Pg 2]</a></span>
+Seeing the sun rise and set, the changes of the moon, the alternation
+of the seasons, the incessant movement of the streams and sea, and the
+other more or less orderly successions of events, our primitive
+forefathers were driven to invent some explanation of them. This,
+independently, and in many different times and places, they did in a
+simple and natural way by supposing that the world was controlled by a
+host of intelligent beings, each of which had some part in ordering
+material things. Sometimes these invisible powers were believed to be
+the spirits of great chieftains, who were active when on earth, and
+who after death continued to exercise their power in the larger realms
+of Nature. Again, and perhaps more commonly, these movements of Nature
+were supposed to be due to the action of great though invisible
+beasts, much like those which the savage found about him. Thus among
+our North American Indians the winds are explained by the supposition
+that the air is fanned by the wings of a great unseen bird, whose duty
+it is to set the atmosphere into motion. That no one has ever seen the
+bird doing the work, or that the task is too great for any conceivable
+bird, is to the simple, uncultivated man no objection to this view. It
+is long, indeed, before education brings men to the point where they
+can criticise their first explanations of Nature.</p>
+
+<p>As men in their advance come to see how much nobler are their own
+natures than those of the lower animals, they gradually put aside the
+explanation of events by the actions of beasts, and account for the
+order of the world by the supposition that each and every important
+detail is controlled by some immortal creature essentially like a man,
+though much more powerful than those of their own kind. This stage of
+understanding is perhaps best shown by the mythology of the Greeks,
+where there was a great god over all, very powerful but not
+omnipotent; and beneath him, in endless successions of command,
+subordinate powers, each with a less range of duties and capacities
+than those of <span class='pagenum'><a name="Page_3" id="Page_3">[Pg 3]</a></span>higher estate, until at the bottom of the system there
+were minor deities and demigods charged with the management of the
+trees, the flowers, and the springs&mdash;creatures differing little from
+man, except that they were immortal, and generally invisible, though
+they, like all the other deities, might at their will display
+themselves to the human beings over whom they watched, and whose path
+in life they guided.</p>
+
+<p>Among only one people do we find that the process of advance led
+beyond this early and simple method of accounting for the processes of
+Nature, bringing men to an understanding such as we now possess. This
+great task was accomplished by the Greeks alone. About twenty-five
+hundred years ago the philosophers of Greece began to perceive that
+the early notion as to the guidance of the world by creatures
+essentially like men could not be accepted, and must be replaced by
+some other view which would more effectively account for the facts.
+This end they attained by steps which can not well be related here,
+but which led them to suppose separate powers behind each of the
+natural series&mdash;powers having no relation to the qualities of mankind,
+but ever acting to a definite end. Thus Plato, who represents most
+clearly this advance in the interpretation of facts, imagined that
+each particular kind of plant or animal had its shape inevitably
+determined by something which he termed an idea, a shape-giving power
+which existed before the object was created, and which would remain
+after it had been destroyed, ever ready again to bring matter to the
+particular form. From this stage of understanding it was but a short
+step to the modern view of natural law. This last important advance
+was made by the great philosopher Aristotle, who, though he died about
+twenty-two hundred years ago, deserves to be accounted the first and
+in many ways the greatest of the ancient men of science who were
+informed with the modern spirit.</p>
+
+<p>With Aristotle, as with all his intellectual successors, the
+operations of Nature were conceived as to be accounted <span class='pagenum'><a name="Page_4" id="Page_4">[Pg 4]</a></span>for by the
+action of forces which we commonly designate as natural laws, of which
+perhaps the most familiar and universal is that of gravitation, which
+impels all bodies to move toward each other with a degree of intensity
+which is measured by their weight and the distance by which they are
+separated.</p>
+
+<p>For many centuries students used the term law in somewhat the same way
+as the more philosophical believers in polytheism spoke of their gods,
+or as Plato of the ideas which he conceived to control Nature. We see
+by this instance how hard it is to get rid of old ways of thinking.
+Even when the new have been adopted we very often find that something
+of the ancient and discarded notions cling in our phrases. The more
+advanced of our modern philosophers are clear in their mind that all
+we know as to the order of Nature is that, given certain conditions,
+certain consequences inevitably follow.</p>
+
+<p>Although the limitations which modern men of science perceive to be
+put upon their labours may seem at first sight calculated to confine
+our understanding within a narrow field of things which can be seen,
+or in some way distinctly proved to exist, the effect of this
+limitation has been to make science what it is&mdash;a realm of things
+known as distinct from things which may be imagined. All the
+difference between ancient science and modern consists in the fact
+that in modern science inquirers demand a businesslike method in the
+interpretation of Nature. Among the Greeks the philosopher who taught
+explanations of any feature in the material world which interested him
+was content if he could imagine some way which would account for the
+facts. It is the modern custom now to term the supposition of an
+explanation a <i>working hypothesis</i>, and only to give it the name of
+theory after a very careful search has shown that all the facts which
+can be gathered are in accordance with the view. Thus when Newton made
+his great suggestion concerning the law of gravitation, which was to
+the effect that all bodies attracted <span class='pagenum'><a name="Page_5" id="Page_5">[Pg 5]</a></span>each other in proportion to
+their masses, and inversely as the square of their distance from each
+other, he did not rest content, as the old Greeks would have done,
+with the probable truth of the explanation, but carefully explored the
+movements of the planets and satellites of the solar system to see if
+the facts accorded with the hypothesis. Even the perfect
+correspondence which he found did not entirely content inquirers, and
+in this century very important experiments have been made which have
+served to show that a ball suspended in front of a precipice will be
+attracted toward the steep, and that even a mass of lead some tons in
+weight will attract toward itself a small body suspended in the manner
+of a pendulum.</p>
+
+<p>It is this incessant revision of the facts, in order to see if they
+accord with the assumed rule or law, which has given modern science
+the sound footing that it lacked in earlier days, and which has
+permitted our learning to go on step by step in a safe way up the
+heights to which it has climbed. All explanations of Nature begin with
+the work of the imagination. In common phrase, they all are guesses
+which have at first but little value, and only attain importance in
+proportion as they are verified by long-continued criticism, which has
+for its object to see whether the facts accord with the theory. It is
+in this effort to secure proof that modern science has gathered the
+enormous store of well-ascertained facts which constitutes its true
+wealth, and which distinguishes it from the earlier imaginative and to
+a great extent unproved views.</p>
+
+<p>In the original state of learning, natural science was confounded with
+political and social tradition, with the precepts of duty which
+constitute the law of the people, as well as with their religion, the
+whole being in the possession of the priests or wise men. So long as
+natural action was supposed to be in the immediate control of numerous
+gods and demigods, so long, in a word, as the explanation of Nature
+was what we term polytheistic, this <span class='pagenum'><a name="Page_6" id="Page_6">[Pg 6]</a></span>association of science with other
+forms of learning was not only natural but inevitable. Gradually,
+however, as the conception of natural law replaced the earlier idea as
+to the intervention of a spirit, science departed from other forms of
+lore and came to possess a field to itself. At first it was one body
+of learning. The naturalists of Aristotle's time, and from his day
+down to near our own, generally concerned themselves with the whole
+field of Nature. For a time it was possible for any one able and
+laborious man to know all which had been ascertained concerning
+astronomy, chemistry, geology, as well as the facts relating to living
+beings. The more, however, as observation accumulated, and the store
+of facts increased, it became difficult for any one man to know the
+whole. Hence it has come about that in our own time natural learning
+is divided into many distinct provinces, each of which demands a
+lifetime of labour from those who would know what has already been
+done in the field, and what it is now important to do in the way of
+new inquiries.</p>
+
+<p>The large divisions which naturalists have usually made of their tasks
+rest in the main on the natural partitions which we may readily
+observe in the phenomenal world. First of all comes astronomy,
+including the phenomena exhibited in the heavens, beyond the limits of
+the earth's atmosphere. Second, geology, which takes account of all
+those actions which in process of time have been developed in our own
+sphere. Third, physics, which is concerned with the laws of energy, or
+those conditions which affect the motion of bodies, and the changes
+which are impressed upon them by the different natural forces. Fourth,
+chemistry, which seeks to interpret the principles which determine the
+combination of atoms and the molecules which are built of them under
+the influence of the chemical affinities. Fifth, biology, or the laws
+of life, a study which pertains to the forms and structures of animals
+and plants, and their wonderful successions in the history of the
+world. Sixth, mathematics, or the science of space <span class='pagenum'><a name="Page_7" id="Page_7">[Pg 7]</a></span>and number, that
+deals with the principles which underlie the order of Nature as
+expressed at once in the human understanding and in the material
+universe. By its use men were made able to calculate, as in
+arithmetic, the problems which concern their ordinary business, as
+well as to compute the movements of the celestial bodies, and a host
+of actions which take place on the earth that would be inexplicable
+except by the aid of this science. Last of all among the primary
+sciences we may name that of psychology, which takes account of mental
+operations among man and his lower kindred, the animals.</p>
+
+<p>In addition to the seven sciences above mentioned, which rest in a
+great measure on the natural divisions of phenomena, there are many,
+indeed, indefinitely numerous, subdivisions which have been made to
+suit the convenience of students. Thus astronomy is often separated
+into physical and mathematical divisions, which take account either of
+the physical phenomena exhibited by the heavenly bodies or of their
+motions. In geology there are half a dozen divisions relating to
+particular branches of that subject. In the realm of organic life, in
+chemistry, and in physics there are many parts of these sciences which
+have received particular names.</p>
+
+<p>It must not be supposed that these sciences have the independence of
+each other which their separate names would imply. In fact, the
+student of each, however, far he may succeed in separating his field
+from that of the other naturalists, as we may fitly term all students
+of Nature, is compelled from time to time to call in the aid of his
+brethren who cultivate other branches of learning. The modern
+astronomer needs to know much of chemistry, or else he can not
+understand many of his observations on the sun. The geologists have to
+share their work with the student of animal and vegetable life, with
+the physicists; they must, moreover, know something of the celestial
+spheres in order to interpret the history of the earth. In fact, day
+by day, with the advance of learning, we come <span class='pagenum'><a name="Page_8" id="Page_8">[Pg 8]</a></span>more clearly to
+perceive that all the processes of Nature are in a way related to each
+other, and that in proportion as we understand any part of the great
+mechanism, we are forced in a manner to comprehend the whole. In other
+words, we are coming to understand that these divisions of the field
+of science depend upon the limitations of our knowledge, and not upon
+the order of Nature itself. For the purposes of education it is
+important that every one should know something of the great truths
+which each science has disclosed. No mortal man can compass the whole
+realm of this knowledge, but every one can gain some idea of the
+larger truths which may help him to understand the beauty and grandeur
+of the sphere in which he dwells, which will enable him the better to
+meet the ordinary duties of life, that in almost all cases are related
+to the facts of the world about us. It has been of late the custom to
+term this body of general knowledge which takes account of the more
+evident facts and important series of terrestrial actions
+physiography, or, as the term implies, a description of Nature, with
+the understanding that the knowledge chosen for the account is that
+which most intimately concerns the student who seeks information that
+is at once general and important. Therefore, in this book the effort
+is made first to give an account as to the ways and means which have
+led to our understanding of scientific problems, the methods by which
+each person may make himself an inquirer, and the outline of the
+knowledge that has been gathered since men first began to observe and
+criticise the revelations the universe may afford them.</p>
+
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_9" id="Page_9">[Pg 9]</a></span></p>
+
+<h1><a name="CHAPTER_II" id="CHAPTER_II"></a>CHAPTER &nbsp; II.<br/>
+<span class="smcap subtitle">ways and means of studying nature.</span></h1>
+
+
+<p>It is desirable that the student of Nature keep well in mind the means
+whereby he is able to perceive what goes on in the world about him. He
+should understand something as to the nature of his senses, and the
+extent to which these capacities enable him to discern the operations
+of Nature. Man, in common with his lower kindred, is, by the mechanism
+of the body, provided with five somewhat different ways by which he
+may learn something of the things about him. The simplest of these
+capacities is that of touch, a faculty that is common to the general
+surface of the body, and which informs us when the surface is affected
+by contact with some external object. It also enables us to discern
+differences of temperature. Next is the sense of taste, which is
+limited to the mouth and the parts about it. This sense is in a way
+related to that of touch, for the reason that it depends on the
+contact of our body with material things. Third is the sense of smell,
+so closely related to that of taste that it is difficult to draw the
+line between the two. Yet through the apparatus of the nose we can
+perceive the microscopically small parts of matter borne to us through
+the air, which could not be appreciated by the nerves of the mouth.
+Fourth in order of scope comes the hearing, which gives us an account
+of those waves of matter that we understand as sound. This power is
+much more far ranging than those before noted; in some cases, as in
+that of the volcanic explosions from the island of Krakatoa, in the
+eruption of 1883, the con<span class='pagenum'><a name="Page_10" id="Page_10">[Pg 10]</a></span>vulsions were audible at the distance of
+more than a thousand miles away. The greater cannon of modern days may
+be heard at the distance of more than a hundred miles, so that while
+the sense of touch, taste, and smell demand contact with the bodies
+which we appreciate, hearing gives us information concerning objects
+at a considerable distance. Last and highest of the senses, vastly the
+most important in all that relates to our understanding of Nature, is
+sight, or the capacity which enables us to appreciate the movement of
+those very small waves of ether which constitute light. The eminent
+peculiarity of sight is that it may give us information concerning
+things which are inconceivably far away; it enables us to discern the
+light of suns probably millions of times as remote from us as is the
+centre of our own solar system.</p>
+
+<p>Although much of the pleasure which the world affords us comes through
+the other senses, the basis of almost all our accurate knowledge is
+reported by sight. It is true that what we have observed with our eyes
+may be set forth in words, and thus find its way to the understanding
+through the ears; also that in many instances the sense of touch
+conveys information which extends our perceptions in many important
+ways; but science rests practically on sight, and on the insight that
+comes from the training of the mind which the eyes make possible.</p>
+
+<p>The early inquirers had no resources except those their bodies
+afforded; but man is a tool-making creature, and in very early days he
+began to invent instruments which helped him in inquiry. The earliest
+deliberate study was of the stars. Science began with astronomy, and
+the first instruments which men contrived for the purpose of
+investigation were astronomical. In the beginning of this search the
+stars were studied in order to measure the length of the year, and
+also for the reason that they were supposed in some way to control the
+fate of men. So far as we know, the first pieces of apparatus for this
+purpose were invented in Egypt, perhaps about four thousand years
+<span class='pagenum'><a name="Page_11" id="Page_11">[Pg 11]</a></span>before the Christian era. These instruments were of a simple nature,
+for the magnifying glass was not yet contrived, and so the telescope
+was impossible. They consisted of arrangements of straight edges and
+divided circles, so that the observers, by sighting along the
+instruments, could in a rough way determine the changes in distance
+between certain stars, or the height of the sun above the horizon at
+the various seasons of the year. It is likely that each of the great
+pyramids of Egypt was at first used as an observatory, where the
+priests, who had some knowledge of astronomy, found a station for the
+apparatus by which they made the observations that served as a basis
+for casting the horoscope of the king.</p>
+
+<p>In the progress of science and of the mechanical invention attending
+its growth, a great number of inventions have been contrived which
+vastly increase our vision and add inconceivably to the precision it
+may attain. In fact, something like as much skill and labour has been
+given to the development of those inventions which add to our learning
+as to those which serve an immediate economic end. By far the greatest
+of these scientific inventions are those which depend upon the lens.
+By combining shaped bits of glass so as to control the direction in
+which the light waves move through them, naturalists have been able to
+create the telescope, which in effect may bring distant objects some
+thousand times nearer to view than they are to the naked eye; and the
+microscope, which so enlarges minute objects as to make them visible,
+as they were not before. The result has been enormously to increase
+our power of vision when applied to distant or to small objects. In
+fact, for purposes of learning, it is safe to say that those tools
+have altogether changed man's relation to the visible universe. The
+naked eye can see at best in the part of the heavens visible from any
+one point not more than thirty thousand stars. With the telescope
+somewhere near a hundred million are brought within the limits of
+vision. Without the help of the microscope an object a thousandth <span class='pagenum'><a name="Page_12" id="Page_12">[Pg 12]</a></span>of
+an inch in diameter appears as a mere point, the existence of which we
+can determine only under favourable circumstances. With that
+instrument the object may reveal an extended and complicated structure
+which it may require a vast labour for the observer fully to explore.</p>
+
+<p>Next in importance to the aid of vision above noted come the
+scientific tools which are used in weighing and measuring. These
+balances and gauges have attained such precision that intervals so
+small as to be quite invisible, and weights as slight as a
+ten-thousandth of a grain, can be accurately measured. From these
+instruments have come all those precise examinations on which the
+accuracy of modern science intimately depends. All these instruments
+of precision are the inventions of modern days. The simplest
+telescopes were made only about two hundred and fifty years ago, and
+the earlier compound microscopes at a yet later date. Accurate
+balances and other forms of gauges of space, as well as good means of
+dividing time, such as our accurate astronomical clocks and
+chronometers, are only about a century old. The instruments have made
+science accurate, and have immensely extended its powers in nearly all
+the fields of inquiry.</p>
+
+<p>Although the most striking modern discoveries are in the field which
+was opened to us by the lens in its manifold applications, it is in
+the chemist's laboratory that we find that branch of science, long
+cultivated, but rapidly advanced only within the last two centuries,
+which has done the most for the needs of man. The ancients guessed
+that the substances which make up the visible world were more
+complicated in their organization than they appear to our vision. They
+even suggested the great truth that matter of all kinds is made up of
+inconceivably small indivisible bits which they and we term atoms. It
+is likely that in the classic days of Greece men began to make simple
+experiments of a chemical nature. A century or two after the time of
+Mohammed, the Arabians of his faith, a people who had acquired Greek
+science from the libraries <span class='pagenum'><a name="Page_13" id="Page_13">[Pg 13]</a></span>which their conquests gave them, conducted
+extensive experiments, and named a good many familiar chemical
+products, such as alcohol, which still bears its Arabic name.</p>
+
+<p>These chemical studies were continued in Europe by the alchemists, a
+name also of Arabic origin, a set of inquirers who were to a great
+extent drawn away from scientific studies by vain though unending
+efforts to change the baser metals into gold and silver, as well as to
+find a compound which would make men immortal in the body. By the
+invention of the accurate balance, and by patient weighing of the
+matters which they submitted to experiment, by the invention of
+hypotheses or guesses at truth, which were carefully tested by
+experiment, the majestic science of modern chemistry has come forth
+from the confused and mystical studies of the alchemists. We have
+learned to know that there are seventy or more primitive or apparently
+unchangeable elements which make up the mass of this world, and
+probably constitute all the celestial spheres, and that these elements
+in the form of their separate atoms may group themselves in almost
+inconceivably varied combinations. In the inanimate realm these
+associations, composed of the atoms of the different substances,
+forming what are termed molecules, are generally composed of but few
+units. Thus carbonic-acid gas, as it is commonly called, is made up of
+an aggregation of molecules, each composed of one atom of carbon and
+two of oxygen; water, of two atoms of hydrogen and one of oxygen;
+ordinary iron oxide, of two atoms of iron and three of oxygen. In the
+realm of organic life, however, these combinations become vastly more
+complicated, and with each of them the properties of the substance
+thus produced differ from all others. A distinguished chemist has
+estimated that in one group of chemical compounds, that of carbon, it
+would be possible to make such an array of substances that it would
+require a library of many thousand ordinary volumes to contain their
+names alone.</p>
+
+<p><span class='pagenum'><a name="Page_14" id="Page_14">[Pg 14]</a></span></p><p>It is characteristic of chemical science that it takes account of
+actions which are almost entirely invisible. No contrivances have been
+or are likely to be invented which will show the observer what takes
+place when the atoms of any substance depart from their previous
+combination and enter on new arrangements. We only know that under
+certain conditions the old atomic associations break up, and new ones
+are formed. But though the processes are hidden, the results are
+manifest in the changes which are brought about upon the masses of
+material which are subjected to the altering conditions. Gradually the
+chemists of our day are learning to build up in their laboratories
+more and more complicated compounds; already they have succeeded in
+producing many of the materials which of old could only be obtained by
+extracting them from plants. Thus a number of the perfumes of flowers,
+and many of the dye-stuffs which a century ago were extracted from
+vegetables, and were then supposed to be only obtainable in that way,
+are now readily manufactured. In time it seems likely that important
+articles of food, for which we now depend upon the seeds of plants,
+may be directly built up from the mineral kingdom. Thus the result of
+chemical inquiry has been not only to show us much of the vast realm
+of actions which go on in the earth, but to give us control of many of
+these movements so that we may turn them to the needs of man.</p>
+
+<p>Animals and plants were at an early day very naturally the subjects of
+inquiry. The ancients perceived that there were differences of kind
+among these creatures, and even in Aristotle's time the sciences of
+zo&ouml;logy and botany had attained the point where there were
+considerable treatises on those subjects. It was not, however, until a
+little more than a century ago that men began accurately to describe
+and classify these species of the organic world. Since the time of
+Linn&aelig;us the growth of our knowledge has gone forward with amazing
+swiftness. Within a century we have come to know perhaps a hundred
+times as much con<span class='pagenum'><a name="Page_15" id="Page_15">[Pg 15]</a></span>cerning these creatures as was learned in all the
+earlier ages. This knowledge is divisible into two main branches: in
+one the inquirers have taken account of the different species, genera,
+families, orders, and classes of living forms with such effect that
+they have shown the existence at the present time of many hundred
+thousand distinct species, the vast assemblage being arranged in a
+classification which shows something as to the relationship which the
+forms bear to each other, and furthermore that the kinds now living
+have not been long in existence, but that at each stage in the history
+of the earth another assemblage of species peopled the waters and the
+lands.</p>
+
+<p>At first naturalists concerned themselves only with the external forms
+of living creatures; but they soon came to perceive that the way in
+which these organisms worked, their physiology, in a word, afforded
+matters for extended inquiry. These researches have developed the
+science of physiology, or the laws of bodily action, on many accounts
+the most modern and extensive of our new acquisitions of natural
+learning. Through these studies we have come to know something of the
+laws or principles by which life is handed on from generation to
+generation, and by which the gradations of structure have been
+advanced from the simple creatures which appear like bits of animated
+jelly to the body and mind of man.</p>
+
+<p>The greatest contribution which modern naturalists have made to
+knowledge concerns the origin of organic species. The students of a
+century ago believed that all these different kinds had been suddenly
+created either through natural law or by the immediate will of God. We
+now know that from the beginning of organic life in the remote past to
+the present day one kind of animal or plant has been in a natural and
+essentially gradual way converted into the species which was to be its
+successor, so that all the vast and complicated assemblage of kinds
+which now exists has been derived by a process of change from the
+forms which in earlier ages dwelt upon this <span class='pagenum'><a name="Page_16" id="Page_16">[Pg 16]</a></span>planet. The exact manner
+in which these alterations were produced is not yet determined, but in
+large part it has evidently been brought about by the method indicated
+by Mr. Darwin, through the survival of the fittest individuals in the
+struggle for existence.</p>
+
+<p>Until men came to have a clear conception as to the spherical form of
+the earth, it was impossible for them to begin any intelligent
+inquiries concerning its structure or history. The Greeks knew the
+earth to be a sphere, but this knowledge was lost among the early
+Christian people, and it was not until about four hundred years ago
+that men again came to see that they dwelt upon a globe. On the basis
+of this understanding the science of geology, which had in a way been
+founded by the Greeks, was revived. As this science depends upon the
+knowledge which we have gained of astronomy, physics, chemistry, and
+biology, all of which branches of learning have to be used in
+explaining the history of the earth, the advance which has been made
+has been relatively slow. Geology as a whole is the least perfectly
+organized of all the divisions of learning. A special difficulty
+peculiar to this science has also served to hinder its development.
+All the other branches of learning deal mainly, if not altogether,
+with the conditions of Nature as they now exist. In this alone is it
+necessary at every step to take account of actions which have been
+performed in the remote past.</p>
+
+<p>It is an easy matter for the students of to-day to imagine that the
+earth has long endured; but to our forefathers, who were educated in
+the view that it had been brought from nothingness into existence
+about seven thousand years ago, it was most difficult and for a time
+impossible to believe in its real antiquity. Endeavouring, as they
+naturally did, to account for all the wonderful revolutions, the
+history of which is written in the pages of the great stone book, the
+early geologists supposed this planet to have been the seat of
+frequent and violent changes, each of which revolutionized its shape
+and de<span class='pagenum'><a name="Page_17" id="Page_17">[Pg 17]</a></span>stroyed its living tenants. It was only very gradually that
+they became convinced that a hundred million years or more have
+elapsed since the dawn of life on the earth, and that in this vast
+period the march of events has been steadfast, the changes taking
+place at about the same rate in which they are now going on. As yet
+this conception as to the history of our sphere has not become the
+general property of the people, but the fact of it is recognised by
+all those who have attentively studied the matter. It is now as well
+ascertained as any of the other truths which science has disclosed to
+us.</p>
+
+<p>It is instructive to note the historic outlines of scientific
+development. The most conspicuous truth which this history discloses
+is that all science has had its origin and almost all its development
+among the peoples belonging to the Aryan race. This body of folk
+appears to have taken on its race characteristics, acquired its
+original language, its modes of action, and the foundations of its
+religion in that part of northern Europe which is about the Baltic
+Sea. Thence the body of this people appear to have wandered toward
+central Asia, where after ages of pastoral life in the high table
+lands and mountains of their country it sent forth branches to India,
+Asia Minor and Greece, to Persia, and to western Europe. It seems ever
+to have been a characteristic of these Aryan peoples that they had an
+extreme love for Nature; moreover, they clearly perceived the need of
+accounting for the things that happened in the world about them. In
+general they inclined to what is called the pantheistic explanation of
+the universe. They believed a supreme God in many different forms to
+be embodied in all the things they saw. Even their own minds and
+bodies they conceived as manifestations of this supreme power. Among
+the Aryans who came to dwell in Europe and along the eastern
+Mediterranean this method of explaining Nature was in time changed to
+one in which humanlike gods were supposed to control the visible and
+invisible worlds. In that mar<span class='pagenum'><a name="Page_18" id="Page_18">[Pg 18]</a></span>vellous centre of culture which was
+developed among the Greeks this conception of humanlike deities was in
+time replaced by that of natural law, and in their best days the
+Greeks were men of science essentially like those of to-day, except
+that they had not learned by experience how important it was to
+criticise their theories by patiently comparing them with the facts
+which they sought to explain. The last of the important Greek men of
+science, Strabo, who was alive when Christ was born, has left us
+writings which in quality are essentially like many of the able works
+of to-day. But for the interruption in the development of Greek
+learning, natural science would probably have been fifteen hundred
+years ahead of its present stage. This interruption came in two ways.
+In one, through the conquest of Greece and the destruction of its
+intellectual life by the Romans, a people who were singularly
+incapable of appreciating natural science, and who had no other
+interest in it except now and then a vacant and unprofitable curiosity
+as to the processes of the natural world. A second destructive
+influence came through the fact that Christianity, in its energetic
+protest against the sins of the pagan civilization, absolutely
+neglected and in a way despised all forms of science.</p>
+
+<p>The early indifference of Christians to natural learning is partly to
+be explained by the fact that their religion was developed among the
+Hebrews, a people remarkable for their lack of interest in the
+scientific aspects of Nature. To them it was a sufficient explanation
+that one omnipotent God ruled all things at his will, the heavens and
+the earth alike being held in the hollow of his hand.</p>
+
+<p>Finding the centre of its development among the Romans, Christianity
+came mainly into the control of a people who, as we have before
+remarked, had no scientific interest in the natural world. This
+condition prolonged the separation of our faith from science for
+fifteen hundred years after its beginning. In this time the records of
+Greek scientific learning mostly disappeared. The writ<span class='pagenum'><a name="Page_19" id="Page_19">[Pg 19]</a></span>ings of
+Aristotle were preserved in part for the reason that the Church
+adopted many of his views concerning questions in moral philosophy and
+in politics. The rest of Greek learning was, so far as Europe was
+concerned, quite neglected.</p>
+
+<p>A large part of Greek science which has come down to us owes its
+preservation to a very singular incident in the history of learning.
+In the ninth century, after the Arabs had been converted to
+Mohammedanism, and on the basis of that faith had swiftly organized a
+great and cultivated empire, the scholars of that folk became deeply
+interested in the remnants of Greek learning which had survived in the
+monastic and other libraries about the eastern Mediterranean. So
+greatly did they prize these records, which were contemned by the
+Christians, that it was their frequent custom to weigh the old
+manuscripts in payment against the coin of their realm. In astronomy,
+mathematics, chemistry, and geology the Arabian students, building on
+the ancient foundations, made notable and for a time most important
+advances. In the tenth century of our era they seemed fairly in the
+way to do for science what western Europe began five centuries later
+to accomplish. In the fourteenth century the centre of Mohammedan
+strength was transferred from the Arabians to the Turks, from a people
+naturally given to learning to a folk of another race, who despised
+all such culture. Thenceforth in place of the men who had treasured
+and deciphered with infinite pains all the records of earlier
+learning, the followers of Mohammed zealously destroyed all the
+records of the olden days. Some of these records, however, survived
+among the Arabs of Spain, and others were preserved by the Christian
+scholars who dwelt in Byzantium, or Constantinople, and were brought
+into western Europe when that city was captured by the Turks in the
+fifteenth century.</p>
+
+<p>Already the advance of the fine arts in Italy and the general tendency
+toward the study of Nature, such as <span class='pagenum'><a name="Page_20" id="Page_20">[Pg 20]</a></span>painting and sculpture indicate,
+had made a beginning, or rather a proper field for a beginning, of
+scientific inquiry. The result was a new interest in Greek learning in
+all its branches, and a very rapid awakening of the scientific spirit.
+At first the Roman Church made no opposition to this new interest
+which developed among its followers, but in the course of a few years,
+animated with the fear that science would lead men to doubt many of
+the dogmas of the Church, it undertook sternly to repress the work of
+all inquirers.</p>
+
+<p>The conflict between those of the Roman faith and the men of science
+continued for above two hundred years. In general, the part which the
+Church took was one of remonstrance, but in a few cases the spirit of
+fanaticism led to the persecution of the men who did not obey its
+mandates and disavow all belief in the new opinions which were deemed
+contrary to the teachings of Scripture. The last instance of such
+oppression occurred in France in the year 1756, when the great Buffon
+was required to recant certain opinions concerning the antiquity of
+the earth which he had published in his work on Natural History. This
+he promptly did, and in almost servile language withdrew all the
+opinions to which the fathers had objected. A like conflict between
+the followers of science and the clerical authorities occurred in
+Protestant countries. Although in no case were the men of science
+physically tortured or executed for their opinions, they were
+nevertheless subjected to great religious and social pressure: they
+were almost as effectively disciplined as were those who fell under
+the ban of the Roman Church.</p>
+
+<p>Some historians have criticised the action of the clerical authorities
+toward science as if the evil which was done had been performed in our
+own day. It should be remembered, however, that in the earlier
+centuries the churches regarded themselves as bound to protect all men
+from the dangers of heresy. For centuries in the early history of
+Christianity the defenders of the faith had been engaged <span class='pagenum'><a name="Page_21" id="Page_21">[Pg 21]</a></span>in a
+life-and-death struggle with paganism, the followers of which held all
+that was known of Nature. Quite naturally the priestly class feared
+that the revival of scientific inquiry would bring with it the evils
+from which the world had suffered in pagan times. There is no doubt
+that these persecutions of science were done under what seemed the
+obligations of duty. They may properly be explained particularly by
+men of science as one of the symptoms of development in the day in
+which they were done. It is well for those who harshly criticise the
+relations of the Church to science to remember that in our own
+country, about two centuries ago, among the most enlightened and
+religious people of the time, Quakers were grievously persecuted, and
+witches hanged, all in the most dutiful and God-fearing way. In
+considering these relations of science to our faith, the matter should
+be dealt with in a philosophical way, and with a sense of the
+differences between our own and earlier ages.</p>
+
+<p>To the student of the relations between Christianity and science it
+must appear doubtful whether the criticism or the other consequences
+which the men of science had to meet from the Church was harmful to
+their work. The early naturalists, like the Greeks whom they followed,
+were greatly given to speculations concerning the processes of Nature,
+which, though interesting, were unprofitable. They also showed a
+curious tendency to mingle their scientific speculations with ancient
+and base superstitions. They were often given to the absurdity
+commonly known as the "black art," or witchcraft, and held to the
+preposterous notions of the astrologists. Even the immortal astronomer
+Kepler, who lived in the sixteenth century, was a professional
+astrologer, and still held to the notion that the stars determined the
+destiny of men. Many other of the famous inquirers in those years
+which ushered in modern science believed in witchcraft. Thus for a
+time natural learning was in a way associated with ancient and
+pernicious beliefs which the Church was seeking to overthrow. One
+result <span class='pagenum'><a name="Page_22" id="Page_22">[Pg 22]</a></span>of the clerical opposition to the advancement of science was
+that its votaries were driven to prove every step which led to their
+conclusions. They were forced to abandon the loose speculation of
+their intellectual guides, the Greeks, and to betake themselves to
+observation. Thus a part of the laborious fact-gathering habit on
+which the modern advance of science has absolutely depended was due to
+the care which men had to exercise in face of the religious
+authorities.</p>
+
+<p>In our own time, in the latter part of the nineteenth century, the
+conflict between the religious authority and the men of science has
+practically ceased. Even the Roman Church permits almost everywhere an
+untrammelled teaching of the established learning to which it was at
+one time opposed. Men have come to see that all truth is accordant,
+and that religion has nothing to fear from the faithful and devoted
+study of Nature.</p>
+
+<p>The advance of science in general in modern times has been greatly due
+to the development of mechanical inventions. Among the ancients, the
+tools which served in the arts were few in number, and these of
+exceeding simplicity. So far as we can ascertain, in the five hundred
+years during which the Greeks were in their intellectual vigour, not
+more than half a dozen new machines were invented, and these were
+exceedingly simple. The fact seems to be that a talent for mechanical
+invention is mainly limited to the peoples of France, Germany, and of
+the English-speaking folk. The first advances in these contrivances
+were made in those countries, and all our considerable gains have come
+from their people. Thus, while the spirit of science in general is
+clearly limited to the Aryan folk, that particular part of the motive
+which leads to the invention of tools is restricted to western and
+northern Europe, to the people to whom we give the name of Teutonic.</p>
+
+<p>Mechanical inventions have aided the development of our sciences in
+several ways. They have furnished inquirers <span class='pagenum'><a name="Page_23" id="Page_23">[Pg 23]</a></span>with instruments of
+precision; they have helped to develop accuracy of observation; best
+of all, they have served ever to bring before the attention of men a
+spectacle of the conditions in Nature which we term cause and effect.
+The influence of these inventions on the development of learning has
+been particularly great where the machines, such as our wind and water
+mills, and our steam engine, make use of the forces of Nature,
+subjugating them to the needs of man. Such instruments give an
+unending illustration as to the presence in Nature of energy. They
+have helped men to understand that the machinery of the universe is
+propelled by the unending application of power. It was, in fact,
+through such machines that men of science first came to understand
+that energy, manifested in the natural forces, is something that
+eternally endures; that we may change its form in our arts as its form
+is changed in the operations of Nature, but the power endures forever.</p>
+
+<p>It is interesting to note that the first observation which led to this
+most important scientific conclusion that energy is indestructible
+however much it may change its form, was made by an American, Benjamin
+Thompson, who left this country at the time of the Revolution, and
+after a curious life became the executive officer, and in effect king,
+of Bavaria. While engaged in superintending the manufacture of cannon,
+he observed that in boring out the barrel of the gun an amount of heat
+was produced which evaporated a certain amount of water. He therefore
+concluded that the energy required to do the boring of the metal
+passed into the state of heat, and thus only changed its state, in no
+wise disappearing from the earth. Other students pursuing the same
+line of inquiry have clearly demonstrated what is called the law of
+the conservation of energy, which more than anything has helped us to
+understand the large operations of Nature. Through these studies we
+have come to see that, while the universe is a place of ceaseless
+change, the quantities of energy and of matter remain unaltered.</p>
+
+<p><span class='pagenum'><a name="Page_24" id="Page_24">[Pg 24]</a></span></p><p>The foregoing brief sketch, which sets forth some of the important
+conditions which have affected the development of science, may in a
+way serve to show the student how he can himself become an interpreter
+of Nature. The evidence indicates that the people of our race have
+been in a way chosen among all the varieties of mankind to lead in
+this great task of comprehending the visible universe. The facts,
+moreover, show that discovery usually begins with the interest which
+men feel in the world immediately about them, or which is presented to
+their senses in a daily spectacle. Thus Benjamin Franklin, in the
+midst of a busy life, became deeply interested in the phenomena of
+lightning, and by a very simple experiment proved that this wonder of
+the air was due to electrical action such as we may arouse by rubbing
+a stick of sealing-wax or a piece of amber with a cloth. All
+discoveries, in a word, have had their necessary beginnings in an
+interest in the facts which daily experience discloses. This desire to
+know something more than the first sight exhibits concerning the
+actions in the world about us is native in every human soul&mdash;at least,
+in all those who are born with the heritage of our race. It is
+commonly strong in childhood; if cultivated by use, it will grow
+throughout a lifetime, and, like other faculties, becomes the stronger
+and more effective by the exertions which it inspires. It is therefore
+most important that every one should obey this instinctive command to
+inquiry, and organize his life and work so that he may not lose but
+gain more and more as time goes on of this noble capacity to
+interrogate and understand the world about him.</p>
+
+<p>It is best that all study of Nature should begin not in laboratories,
+nor with the things which are remote from us, but in the field of
+Nature which is immediately about us. The student, even if he dwell in
+the unfavourable conditions of a great city, is surrounded by the
+world which has yielded immeasurable riches in the way of learning,
+which he can appropriate by a little study. He can readily <span class='pagenum'><a name="Page_25" id="Page_25">[Pg 25]</a></span>come to
+know something of the movements of the air; the buildings will give
+him access to a great many different kinds of stone; the smallest
+park, a little garden, or even a few potted plants and captive
+animals, may tell him much concerning the forms and actions of living
+beings. By studying in this way he can come to know something of the
+differences between things and their relations to each other. He will
+thus have a standard by which he can measure and make familiar the
+body of learning concerning Nature which he may find in books. From
+printed pages alone, however well they be written, he can never hope
+to catch the spirit that animates the real inquirer, the true lover of
+Nature.</p>
+
+<p>On many accounts the most attractive way of beginning to form the
+habit of the naturalist is by the study of living animals and plants.
+To all of us life adds interest, and growth has a charm. Therefore it
+is well for the student to start on the way of inquiry by watching the
+actions of birds and insects or by rearing plants. It is fortunate if
+he can do both these agreeable things. When the habit of taking an
+account of that most important part of the world which is immediately
+about him has been developed in the student, he may profitably proceed
+to acquire the knowledge of the invisible universe which has been
+gathered by the host of inquirers of his race. However far he
+journeys, he should return to the home world that lies immediately and
+familiarly about him, for there alone can he acquire and preserve that
+personal acquaintance with things which is at once the inspiration and
+the test of all knowledge.</p>
+
+<p>Along with this study of the familiar objects about us the student may
+well combine some reading which may serve to show him how others have
+been successful in thus dealing with Nature at first hand. For this
+purpose there are, unfortunately, but few works which are well
+calculated to serve the needs of the beginner. Perhaps the best
+naturalist book, though its form is somewhat ancient, is White's<span class='pagenum'><a name="Page_26" id="Page_26">[Pg 26]</a></span>
+Natural History of Selborne. Hugh Miller's works, particularly his Old
+Red Sandstone and My Schools and Schoolmasters, show well how a man
+may become a naturalist under difficulties. Sir John Lubbock's studies
+on Wasps, and Darwin's work on Animals and Plants under Domestication
+are also admirable to show how observation should be made. Dr. Asa
+Gray's little treatise on How Plants Grow will also be useful to the
+beginner who wishes to approach botany from its most attractive
+side&mdash;that of the development of the creature from the seed to seed.</p>
+
+<p>There is another kind of training which every beginner in the art of
+observing Nature should obtain, and which many naturalists of repute
+would do well to give themselves&mdash;namely, an education in what we may
+call the art of distance and geographical forms. With the primitive
+savage the capacity to remember and to picture to the eye the shape of
+a country which he knows is native and instinctive. Accustomed to
+range the woods, and to trust to his recollection to guide him through
+the wilderness to his home, the primitive man develops an important
+art which among civilized people is generally dormant. In fact, in our
+well-trodden ways people may go for many generations without ever
+being called upon to use this natural sense of geography. The easiest
+way to cultivate the geographic sense is by practising the art of
+making sketch maps. This the student, however untrained, can readily
+do by taking first his own dwelling house, on which he should practise
+until he can readily from memory make a tolerably correct and
+proportional plan of all its rooms. Then on a smaller scale he should
+begin to make also from recollection a map showing the distribution of
+the roads, streams, and hills with which his daily life makes him
+familiar. From time to time this work from memory should be compared
+with the facts. At first the record will be found to be very poor, but
+with a few months of occasional endeavour the observer will find that
+his mind takes account of geographic features in a way it did not
+<span class='pagenum'><a name="Page_27" id="Page_27">[Pg 27]</a></span>before, and, moreover, that his mind becomes enriched with
+impressions of the country which are clear and distinct, in place of
+the shadowy recollections which he at first possessed.</p>
+
+<p>When the student has attained the point where, after walking or riding
+over a country, he can readily recall its physical features of the
+simpler sort, he will find it profitable to undertake the method of
+mapping with contour lines&mdash;that is, by pencilling in indications to
+show the exact shape of the elevations and depressions. The principle
+of contour lines is that each of them represents where water would
+come against the slope if the area were sunk step by step below the
+sea level&mdash;in other words, each contour line marks the intersection of
+a horizontal plane with the elevation of the country. Practice on this
+somewhat difficult task will soon give the student some idea as to the
+complication of the surface of a region, and afford him the basis for
+a better understanding of what geography means than all the reading he
+can do will effect. It is most desirable that training such as has
+been described should be a part of our ordinary school education.</p>
+
+<p>Very few people have clear ideas of distances. Even the men whose
+trade requires some such knowledge are often without that which a
+little training could give them. Without some capacity in this
+direction, the student is always at a disadvantage in his contact with
+Nature. He can not make a record of what he sees as long as the
+element of horizontal and vertical distance is not clearly in mind. To
+attain this end the student should begin by pacing some length of road
+where the distances are well known. In this way he will learn the
+length of his step, which with a grown man generally ranges between
+two and a half and three feet. Learning the average length of his
+stride by frequent counting, it is easy to repeat the trial until one
+can almost unconsciously keep the count as he walks. Properly to
+secure the training of this sort the observer should first attentively
+look across the distance <span class='pagenum'><a name="Page_28" id="Page_28">[Pg 28]</a></span>which is to be determined. He should notice
+how houses, fences, people, and trees appear at that distance. He will
+quickly perceive that each hundred feet of additional interval
+somewhat changes their aspect. In training soldiers to measure with
+the eye the distances which they have to know in order effectively to
+use the modern weapons of war, a common device is to take a squad of
+men, or sometimes a company, under the command of an officer, who
+halts one man at each hundred yards until the detachment is strung out
+with that interval as far as the eye can see them. The men then walk
+to and fro so that the troops who are watching them may note the
+effects of increased distance on their appearance, whether standing or
+in motion. At three thousand yards a man appears as a mere dot, which
+is not readily distinguishable. Schoolboys may find this experiment
+amusing and instructive.</p>
+
+<p>After the student has gained, as he readily may, some sense of the
+divisions of distance within the range of ordinary vision, he should
+try to form some notion of greater intervals, as of ten, a hundred,
+and perhaps a thousand miles. The task becomes more difficult as the
+length of the line increases, but most persons can with a little
+address manage to bring before their eyes a tolerably clear image of a
+hundred miles of distance by looking from some elevation which
+commands a great landscape. It is doubtful, however, whether the
+best-trained man can get any clear notion of a thousand miles&mdash;that
+is, can present it to himself in imagination as he may readily do with
+shorter intervals.</p>
+
+<p>The most difficult part of the general education which the student has
+to give himself is begun when he undertakes to picture long intervals
+of time. Space we have opportunities to measure, and we come in a way
+to appreciate it, but the longest lived of men experiences at most a
+century of life, and this is too small a measure to give any notion as
+to the duration of such great events as are involved in the history of
+the earth, where the periods <span class='pagenum'><a name="Page_29" id="Page_29">[Pg 29]</a></span>are to be reckoned by the millions of
+years. The only way in which we can get any aid in picturing to
+ourselves great lapses of time is by expressing them in units of
+distance. Let a student walk away on a straight road for the distance
+of a mile; let him call each step a year; when he has won the first
+milestone, he may consider that he has gone backward in time to the
+period of Christ's birth. Two miles more will take him to the station
+which will represent the age when the oldest pyramids were built. He
+is still, however, in the later days of man's history on this planet.
+To attain on the scale the time when man began, he might well have to
+walk fifty miles away, while a journey which would thus by successive
+steps describe the years of the earth's history since life appeared
+upon its surface would probably require him to circle the earth at
+least four times. We may accept it as impossible for any one to deal
+with such vast durations save with figures which are never really
+comprehended. It is well, however, to enlarge our view as to the age
+of the earth by such efforts as have just been indicated.</p>
+
+<p>When we go beyond the earth into the realm of the stars all efforts
+toward understanding the ranges of space or the durations of time are
+quite beyond the efforts of man. Even the distance of about two
+hundred and forty thousand miles which separates us from the moon can
+not be grasped by even the greater minds. No human intelligence,
+however cultivated, can conceive the distance of about ninety-five
+million miles which separates us from the sun. In the celestial realm
+we can only deal with relations of space and time in a general and
+comparative way. We can state the distances if we please in millions
+of miles, or we can reckon the ampler spaces by using the interval
+which separates the earth from the sun as we do a foot rule in our
+ordinary work, but the depths of the starry spaces can only be sounded
+by the winged imagination.</p>
+
+<p>Although the student has been advised to begin his <span class='pagenum'><a name="Page_30" id="Page_30">[Pg 30]</a></span>studies of Nature
+on the field whereon he dwells, making that study the basis of his
+most valuable communications with Nature, it is desirable that he
+should at the same time gain some idea as to the range and scope of
+our knowledge concerning the visible universe. As an aid toward this
+end the following chapters of this book will give a very brief survey
+of some of the most important truths concerning the heavens and the
+earth which have rewarded the studies of scientific men. Of remoter
+things, such as the bodies in the stellar spaces, the account will be
+brief, for that which is known and important to the general student
+can be briefly told. So, too, of the earlier ages of the earth's
+history, although a vast deal is known, the greater part of the
+knowledge is of interest and value mainly to geologists who cultivate
+that field. That which is most striking and most important to the mass
+of mankind is to be found in the existing state of our earth, the
+conditions which make it a fit abode for our kind, and replete with
+lessons which he may study with his own eyes without having to travel
+the difficult paths of the higher sciences.</p>
+
+<p>Although physiography necessarily takes some account of the things
+which have been, even in the remote past, and this for the reason that
+everything in this day of the world depends on the events of earlier
+days, the accent of its teaching is on the immediate, visible, as we
+may say, living world, which is a part of the life of all its
+inhabitants.</p>
+
+
+
+<hr style="width: 65%;" />
+<p><span class='pagenum'><a name="Page_31" id="Page_31">[Pg 31]</a></span></p>
+
+<h1><a name="CHAPTER_III" id="CHAPTER_III"></a>CHAPTER &nbsp; III.<br/>
+<span class="smcap subtitle">the stellar realm.</span></h1>
+
+
+<p>Even before men came to take any careful account of the Nature
+immediately about them they began to conjecture and in a way to
+inquire concerning the stars and the other heavenly bodies. It is
+difficult for us to imagine how hard it was for students to gain any
+adequate idea of what those lights in the sky really are. At first men
+imagined the celestial bodies to be, as they seemed, small objects not
+very far away. Among the Greeks the view grew up that the heavens were
+formed of crystal spheres in which the lights were placed, much as
+lanterns may be hung upon a ceiling. These spheres were conceived to
+be one above the other; the planets were on the lower of them, and the
+fixed stars on the higher, the several crystal roofs revolving about
+the earth. So long as the earth was supposed to be a flat and
+limitless expanse, forming the centre of the universe, it was
+impossible for the students of the heavens to attain any more rational
+view as to their plan.</p>
+
+<p>The fact that the earth was globular in form was understood by the
+Greek men of science. They may, indeed, have derived the opinion from
+the Egyptian philosophers. The discovery rested upon the readily
+observed fact that on a given day the shadow of objects of a certain
+height was longer in high latitude than in low. Within the tropics,
+when the sun was vertical, there would be no shadow, while as far
+north as Athens it would be of considerable length. The conclusion
+that the earth was a sphere appears to have been the first large
+discovery made by our race. It was, indeed, one of the most important
+intellectual acquisitions of man.</p>
+
+<p>Understanding the globular form of the earth, the next and most
+natural step was to learn that the earth was not the centre of the
+planetary system, much less of the universe, but that that centre was
+the sun, around which the earth and the other planets revolved. The
+Greeks appear to have had some idea that this was the case, and their
+spirit of inquiry would probably have led them to the whole truth but
+for the overthrow of their thought by the Roman conquest and the
+spread of Christianity. It was therefore not until after the revival
+of learning that astronomers won their way to our modern understanding
+concerning the relation of the planets to the sun. With Galileo this
+opinion was affirmed. Although for a time the Church, resting its
+opposition on the interpretation of certain passages of Scripture,
+resisted this view, and even punished the men who held it, it
+steadfastly made its way, and for more than two centuries has been the
+foundation of all the great discoveries in the stellar realm. Yet long
+after the fact that the sun was the centre of the solar system was
+well established no one understood why the planets should move in
+their ceaseless, orderly procession around the central mass. To Newton
+we owe the studies on the law of gravitation which brought us to our
+present large conception as to the origin of this order. Starting with
+the view that bodies attracted each other in proportion to their
+weight, and in diminishing proportion as they are removed from each
+other, Newton proceeded by most laborious studies to criticise this
+view, and in the end definitely proved it by finding that the motions
+of the moon about the earth, as well as the paths of the planets,
+exactly agreed with the supposition.</p>
+
+<p>The last great path-breaking discovery which has helped us in our
+understanding of the stars was made by Fraunhofer and other
+physicists, who showed us that su<span class='pagenum'><a name="Page_33" id="Page_33">[Pg 33]</a></span><span class='pagenum'><a name="Page_32" id="Page_32">[Pg 32]</a></span>bstances when in a heated, gaseous,
+or vaporous state produced, in a way which it is not easy to explain
+in a work such as this, certain dark lines in the spectrum, or streak
+of divided light which we may make by means of a glass prism, or, as
+in the rainbow, by drops of water. Carefully studying these very
+numerous lines, those naturalists found that they could with singular
+accuracy determine what substances there were in the flame which gave
+the light. So accurate is this determination that it has been made to
+serve in certain arts where there is no better means of ascertaining
+the conditions of a flaming substance except by the lines which its
+light exhibits under this kind of analysis. Thus, in the manufacture
+of iron by what is called the Bessemer process, it has been found very
+convenient to judge as to the state of the molten metal by such an
+analysis of the flame which comes forth from it.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a name="img02"></a>
+<img src="images/p2.jpg" width="640" height="376" alt="Seal Rocks near San Francisco, California, showing
+slight effect of waves where there is no beach." title="" />
+<span class="caption">Seal Rocks near San Francisco, California, showing
+slight effect of waves where there is no beach.</span>
+</div>
+
+<p>No sooner was the spectroscope invented than astronomers hastened by
+its aid to explore the chemical constitution of the sun. These studies
+have made it plain that the light of our solar centre comes forth from
+an atmosphere composed of highly heated substances, all of which are
+known among the materials forming the earth. Although for various
+reasons we have not been able to recognise in the sun all the elements
+which are found in our sphere, it is certain that in general the two
+bodies are alike in composition. An extension of the same method of
+inquiry to the fixed stars was gradually though with difficulty
+attained, and we now know that many of the elements common to the sun
+and earth exist in those distant spheres. Still further, this method
+of inquiry has shown us, in a way which it is not worth while here to
+describe, that among these remoter suns there are many aggregations of
+matter which are not consolidated as are the spheres of our own solar
+system, but remain in the gaseous state, receiving the name of nebul&aelig;.</p>
+
+<p>Along with the growth of observational astronomy which has taken place
+since the discoveries of Galileo, <span class='pagenum'><a name="Page_34" id="Page_34">[Pg 34]</a></span>there has been developed a view
+concerning the physical history of the stellar world, known as the
+nebular hypothesis, which, though not yet fully proved, is believed by
+most astronomers and physicists to give us a tolerably correct notion
+as to the way in which the heavenly spheres were formed from an
+earlier condition of matter. This majestic conception was first
+advanced, in modern times at least, by the German philosopher Immanuel
+Kant. It was developed by the French astronomer Laplace, and is often
+known by his name. The essence of this view rests upon the fact
+previously noted that in the realm of the fixed stars there are many
+faintly shining aggregations of matter which are evidently not solid
+after the manner of the bodies in our solar system, but are in the
+state where their substances are in the condition of dustlike
+particles, as are the bits of carbon in flame or the elements which
+compose the atmosphere. The view held by Laplace was to the effect
+that not only our own solar system, but the centres of all the other
+similar systems, the fixed stars, were originally in this gaseous
+state, the material being disseminated throughout all parts of the
+heavenly realm, or at least in that portion of the universe of which
+we are permitted to know something. In this ancient state of matter we
+have to suppose that the particles of it were more separated from each
+other than are the atoms of the atmospheric gases in the most perfect
+vacuum which we can produce with the air-pump. Still we have to
+suppose that each of these particles attract the other in the
+gravitative way, as in the present state of the universe they
+inevitably do.</p>
+
+<p>Under the influence of the gravitative attraction the materials of
+this realm of vapour inevitably tended to fall in toward the centre.
+If the process had been perfectly simple, the result would have been
+the formation of one vast mass, including all the matter which was in
+the original body. In some way, no one has yet been able to make a
+reasonable suggestion of just how, there were developed <span class='pagenum'><a name="Page_35" id="Page_35">[Pg 35]</a></span>in the
+process of concentration a great many separate centres of aggregation,
+each of which became the beginning of a solar system. The student may
+form some idea of how readily local centres may be produced in
+materials disseminated in the vaporous state by watching how fog or
+the thin, even misty clouds of the sunrise often gather into the
+separate shapes which make what we term a "mackerel" sky. It is
+difficult to imagine what makes centres of attraction, but we readily
+perceive by this instance how they might have occurred.</p>
+
+<p>When the materials of each solar system were thus set apart from the
+original mass of star dust or vapour, they began an independent
+development which led step by step, in the case of our own solar
+system at least, and presumably also in the case of the other suns,
+the fixed stars, to the formation of planets and their moons or
+satellites, all moving around the central sun. At this stage of the
+explanation the nebular hypothesis is more difficult to conceive than
+in the parts of it which have already been described, for we have now
+to understand how the planets and satellites had their matter
+separated from each other and from the solar centre, and why they came
+to revolve around that central body. These problems are best
+understood by noting some familiar instances connected with the
+movement of fluids and gases toward a centre. First let us take the
+case of a basin in which the water is allowed to flow out through a
+hole in its centre. When we lift the stopper the fluid for a moment
+falls straight down through the opening. Very quickly, however, all
+the particles of the water start to move toward the centre, and almost
+at once the mass begins to whirl round with such speed that, although
+it is working toward the middle, it is by its movement pushed away
+from the centre and forms a conical depression. As often as we try the
+experiment, the effect is always the same. We thus see that there is
+some principle which makes particles of fluid that tend toward a
+<span class='pagenum'><a name="Page_36" id="Page_36">[Pg 36]</a></span>centre fail directly to attain it, but win their way thereto in a
+devious, spinning movement.</p>
+
+<p>Although the fact is not so readily made visible to the eye, the same
+principle is illustrated in whirling storms, in which, as we shall
+hereafter note with more detail, the air next the surface of the earth
+is moving in toward a kind of chimney by which it escapes to the upper
+regions of the atmosphere. A study of cyclones and tornadoes, or even
+of the little air-whirls which in hot weather lift the dust of our
+streets, shows that the particles of the atmosphere in rushing in
+toward the centre of upward movement take on the same whirling motion
+as do the molecules of water in the basin&mdash;in fact, the two actions
+are perfectly comparable in all essential regards, except that the
+fluid is moving downward, while the air flows upward. Briefly stated,
+the reason for the movement of fluid and gas in the whirling way is as
+follows: If every particle on its way to the centre moved on a
+perfectly straight line toward the point of escape, the flow would be
+directly converging, and the paths followed would resemble the spokes
+of a wheel. But when by chance one of the particles sways ever so
+little to one side of the direct way, a slight lateral motion would
+necessarily be established. This movement would be due to the fact
+that the particle which pursued the curved line would press against
+the particles on the out-curved side of its path&mdash;or, in other words,
+shove them a little in that direction&mdash;to the extent that they
+departed from the direct line they would in turn communicate the
+shoving to the next beyond. When two particles are thus shoving on one
+side of their paths, the action which makes for revolution is doubled,
+and, as we readily see, the whole mass may in this way become quickly
+affected, the particles driven out of their path, moving in a curve
+toward the centre. We also see that the action is accumulative: the
+more curved the path of each particle, the more effectively it shoves;
+and so, in the case of the basin, we see the whirling rapidly
+developed before our eyes.</p>
+
+<p><span class='pagenum'><a name="Page_37" id="Page_37">[Pg 37]</a></span></p><p>In falling in toward the centre the particles of star dust or vapour
+would no more have been able one and all to pursue a perfectly
+straight line than the particles of water in the basin. If a man
+should spend his lifetime in filling and emptying such a vessel, it is
+safe to say that he would never fail to observe the whirling movement.
+As the particles of matter in the nebular mass which was to become a
+solar system are inconceivably greater than those of water in the
+basin, or those of air in the atmospheric whirl, the chance of the
+whirling taking place in the heavenly bodies is so great that we may
+assume that it would inevitably occur.</p>
+
+<p>As the vapours in the olden day tended in toward the centre of our
+solar system, and the mass revolved, there is reason to believe that
+ringlike separations took place in it. Whirling in the manner
+indicated, the mass of vapour or dust would flatten into a disk or a
+body of circular shape, with much the greater diameter in the plane of
+its whirling. As the process of concentration went on, this disk is
+supposed to have divided into ringlike masses, some approach to which
+we can discern in the existing nebul&aelig;, which here and there among the
+farther fixed stars appear to be undergoing such stages of development
+toward solar systems. It is reasonably supposed that after these rings
+had been developed they would break to pieces, the matter in them
+gathering into a sphere, which in time was to become a planet. The
+outermost of these rings led to the formation of the planet farthest
+from the sun, and was probably the first to separate from the parent
+mass. Then in succession rings were formed inwardly, each leading in
+turn to the creation of another planet, the sun itself being the
+remnant, by far the greater part of the whole mass of matter, which
+did not separate in the manner described, but concentrated on its
+centre. Each of these planetary aggregations of vapour tended to
+develop, as it whirled upon its centre, rings of its own, which in
+turn formed, by breaking and concentrating, the satellites or moons
+<span class='pagenum'><a name="Page_38" id="Page_38">[Pg 38]</a></span>which attend the earth, as they do all the planets which lie farther
+away from the sun than our sphere.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f1.jpg" width="640" height="301" alt="Fig. 1.&mdash;Saturn, Jan. 26, 1889 (Antoniadi)." title="" />
+<span class="figcaption">Fig. 1.&mdash;Saturn, Jan. 26, 1889 (Antoniadi).</span>
+</div>
+
+<p>As if to prove that the planets and moons of the solar system were
+formed somewhat in the manner in which we have described it, one of
+these spheres, Saturn, retains a ring, or rather a band which appears
+to be divided obscurely into several rings which lie between its group
+of satellites and the main sphere. How this ring has been preserved
+when all the others have disappeared, and what is the exact
+constitution of the mass, is not yet well ascertained. It seems clear,
+however, that it can not be composed of solid matter. It is either in
+the form of dust or of small spheres, which are free to move on each
+other; otherwise, as computation shows, the strains due to the
+attraction which Saturn itself and its moons exercise upon it would
+serve to break it in pieces. Although this ring theory of the
+formation of the planets and satellites is not completely proved, the
+occurrence of such a structure as that which girdles Saturn affords
+presumptive evidence that it is true. Taken in connection with what we
+know of the nebul&aelig;, the proof of Laplace's nebular hypothesis may
+fairly be regarded as complete.</p>
+
+<p>It should be said that some of the fixed stars are not isolated suns
+like our own, but are composed of two great <span class='pagenum'><a name="Page_39" id="Page_39">[Pg 39]</a></span>spheres revolving about
+one another; hence they are termed double stars. The motions of these
+bodies are very peculiar, and their conditions show us that it is not
+well to suppose that the solar system in which we dwell is the only
+type of order which prevails in the celestial families; there may,
+indeed, be other variations as yet undetected. Still, these
+differences throw no doubt on the essential truth of the theory as to
+the process of development of the celestial systems. Though there is
+much room for debate as to the details of the work there, the general
+truth of the theory is accepted by nearly all the students of the
+problem.</p>
+
+<p>A peculiar advantage of the nebular hypothesis is that it serves to
+account for the energy which appears as light and heat in the sun and
+the fixed stars, as well as that which still abides in the mass of our
+earth, and doubtless also in the other large planets. When the matter
+of which these spheres were composed was disseminated through the
+realms of space, it is supposed to have had no positive temperature,
+and to have been dark, realizing the conception which appears in the
+first chapter of Genesis, "without form, and void." With each stage of
+the falling in toward the solar centres what is called the "energy of
+position" of this original matter became converted into light and
+heat. To understand how this took place, the reader should consider
+certain simple yet noble generalizations of physics. We readily
+recognise the fact that when a hammer falls often on an anvil it heats
+itself and the metal on which it strikes. Those who have been able to
+observe the descent of meteoric stones from the heavens have remarked
+that when they came to the earth they were, on their surfaces at
+least, exceedingly hot. Any one may observe shining meteors now and
+then flashing in the sky. These are known commonly to be very small
+bits of matter, probably not larger than grains of sand, which,
+rushing into our atmosphere, are so heated by the friction which they
+encounter that they burn to a gas or vapour <span class='pagenum'><a name="Page_40" id="Page_40">[Pg 40]</a></span>before they attain the
+earth. As we know that these particles come from the starry spaces,
+where the temperature is somewhere near 500&deg; below 0&deg; Fahr., it is
+evident that the light and heat are not brought with them into the
+atmosphere; it can only be explained by the fact that when they enter
+the air they are moving at an average speed of about twenty miles a
+second, and that the energy which this motion represents is by the
+resistance which the body encounters converted into heat. This fact
+will help us to understand how, as the original star dust fell in
+toward the centre of attraction, it was able to convert what we have
+termed the energy of position into temperature. We see clearly that
+every such particle of dust or larger bit of matter which falls upon
+the earth brings about the development of heat, even though it does
+not actually strike upon the solid mass of our sphere. The conception
+of what took place in the consolidation of the originally disseminated
+materials of the sun and planets can be somewhat helped by a simple
+experiment. If we fit a piston closely into a cylinder, and then
+suddenly drive it down with a heavy blow, the compressed air is so
+heated that it may be made to communicate fire. If the piston should
+be slowly moved, the same amount of heat would be generated, or, as we
+may better say, liberated by the compression, though the effect would
+not be so striking. A host of experiments show that when a given mass
+of matter is brought to occupy a less space the effect is in
+practically all cases to increase the temperature. The energy which
+kept the particles apart is, when they are driven together, converted
+into heat. These two classes of actions are somewhat different in
+their nature; in the case of the meteors, or the equivalent star dust,
+the coming together of the particles is due to gravitation. In the
+experiment with the cylinder above described, the compression is due
+to mechanical energy, a force of another nature.</p>
+
+<p>There is reason for believing that all our planets, as well as the sun
+itself, and also the myriad other orbs of <span class='pagenum'><a name="Page_41" id="Page_41">[Pg 41]</a></span>space, have all passed
+through the stages of a transition in which a continually
+concentrating vapour, drawn together by gravitation, became
+progressively hotter and more dense until it assumed the condition of
+a fluid. This fluid gradually parted with its heat to the cold spaces
+of the heavens, and became more and more concentrated and of a lower
+temperature until in the end, as in the case of our earth and of other
+planets, it ceased to glow on the outside, though it remained
+intensely heated in the inner parts. It is easy to see that the rate
+of this cooling would be in some proportion to the size of the sphere.
+Thus the earth, which is relatively small, has become relatively cold,
+while the sun itself, because of its vastly greater mass, still
+retains an exceedingly high temperature. The reason for this can
+readily be conceived by making a comparison of the rate of cooling
+which occurs in many of our ordinary experiences. Thus a vial of hot
+water will quickly come down to the temperature of the air, while a
+large jug filled with the fluid at the same temperature will retain
+its heat many times as long. The reason for this rests upon the simple
+principle that the contents of a sphere increase with its enlargement
+more rapidly than the surface through which the cooling takes place.</p>
+
+<p>The modern studies on the physical history of the sun and other
+celestial bodies show that their original store of heat is constantly
+flowing away into the empty realms of space. The rate at which this
+form of energy goes away from the sun is vast beyond the powers of the
+imagination to conceive; thus, in the case of our earth, which viewed
+from the sun would appear no more than a small star, the amount of
+heat which falls upon it from the great centre is enough each day to
+melt, if it all could be put to such work, about eight thousand cubic
+miles of ice. Yet the earth receives only
+<span class="fraction"><span class="above">1</span>/<span class="below">2,170,000,000</span></span>
+part of the solar radiation. The greater part of this solar heat&mdash;in fact, we may
+say nearly all of it&mdash;slips by the few and relatively small planets
+and disappears in the great void.</p>
+
+<p><span class='pagenum'><a name="Page_42" id="Page_42">[Pg 42]</a></span></p><p>The destiny of all the celestial spheres seems in time to be that
+they shall become cooled down to a temperature far below anything
+which is now experienced on this earth. Even the sun, though its heat
+will doubtless endure for millions of years to come, must in time, so
+far as we can see, become dark and cold. So far as we know, we can
+perceive no certain method by which the life of the slowly decaying
+suns can be restored. It has, however, been suggested that in many
+cases a planetary system which has attained the lifeless and lightless
+stage may by collision with some other association of spheres be by
+the blow restored to its previous state of vapour, the joint mass of
+the colliding systems once again to resume the process of
+concentration through which it had gone before. Now and then stars
+have been seen to flash suddenly into great brilliancy in a way which
+suggests that possibly their heat had been refreshed by a collision
+with some great mass which had fallen into them from the celestial
+spaces. There is room for much speculation in this field, but no
+certainty appears to be attainable.</p>
+
+<p>The ancients believed that light and heat were emanations which were
+given off from the bodies that yielded them substantially as odours
+are given forth by many substances. Since the days of Newton inquiry
+has forced us to the conviction that these effects of temperature are
+produced by vibrations having the general character of waves, which
+are sent through the spaces with great celerity. When a ray of light
+departs from the sun or other luminous body, it does not convey any
+part of the mass; it transmits only motion. A conception of the action
+can perhaps best be formed by suspending a number of balls of ivory,
+stone, or other hard substance each by a cord, the series so arranged
+that they touch each other. Then striking a blow against one end of
+the line, we observe that the ball at the farther end of the line is
+set in motion, swinging a little away from the place it occupied
+before. The movement of the intermediate balls may be so slight as to
+escape <span class='pagenum'><a name="Page_43" id="Page_43">[Pg 43]</a></span>attention. We thus perceive that energy can be transmitted
+from one to another of these little spheres. Close observation shows
+us that under the impulse which the blow gives each separate body is
+made to sway within itself much in the manner of a bell when it is
+rung, and that the movement is transmitted to the object with which it
+is in contact. In passing from the sun to the earth, the light and
+heat traverse a space which we know to be substantially destitute of
+any such materials as make up the mass of the earth or the sun. Judged
+by the standards which we can apply, this space must be essentially
+empty. Yet because motions go through it, we have to believe that it
+is occupied by something which has certain of the properties of
+matter. It has, indeed, one of the most important properties of all
+substances, in that it can vibrate. This practically unknown thing is
+called ether.</p>
+
+<p>The first important observational work done by the ancients led them
+to perceive that there was a very characteristic difference between
+the planets and the fixed stars. They noted the fact that the planets
+wandered in a ceaseless way across the heavens, while the fixed stars
+showed little trace of changing position in relation to one another.
+For a long time it was believed that these, as well as the remoter
+fixed stars, revolved about the earth. This error, though great, is
+perfectly comprehensible, for the evident appearance of the movement
+is substantially what would be brought about if they really coursed
+around our sphere. It was only when the true nature of the earth and
+its relations to the sun were understood that men could correct this
+first view. It was not, indeed, until relatively modern times that the
+solar system came to be perceived as something independent and widely
+detached from the fixed stars system; that the spaces which separate
+the members of our own solar family, inconceivably great as they are,
+are but trifling as compared with the intervals which part us from the
+nearer fixed stars. At this stage of our knowledge men came to the
+noble suggestion that each of the <span class='pagenum'><a name="Page_44" id="Page_44">[Pg 44]</a></span>fixed stars was itself a sun, each
+of the myriad probably attended by planetary bodies such as exist
+about our own luminary.</p>
+
+<p>It will be well for the student to take an imaginary journey from the
+sun forth into space, along the plane in which extends that vast
+aggregation of stars which we term the Milky Way. Let him suppose that
+his journey could be made with something like the speed of light, or,
+say, at the rate of about two hundred thousand miles a second. It is
+fit that the imagination, which is free to go through all things,
+should essay such excursions. On the fancied outgoing, the observer
+would pass the interval between the sun and the earth in about eight
+minutes. It would require some hours before he attained to the outer
+limit of the solar system. On his direct way he would pass the orbits
+of the several planets. Some would have their courses on one side or
+the other of his path; we should say above or below, but for the fact
+that we leave these terms behind in the celestial realm. On the margin
+of the solar system the sun would appear shrunken to the state where
+it was hardly greater than the more brilliant of the other fixed
+stars. The onward path would then lead through a void which it would
+require years to traverse. Gradually the sun which happened to lie
+most directly in his path would grow larger; with nearer approach, it
+would disclose its planets. Supposing that the way led through this
+solar system, there would doubtless be revealed planets and satellites
+in their order somewhat resembling those of our own solar family, yet
+there would doubtless be many surprises in the view. Arriving near the
+first sun to be visited, though the heavens would have changed their
+shape, all the existing constellations having altered with the change
+in the point of view, there would still be one familiar element in
+that the new-found planets would be near by, and the nearest fixed
+stars far away in the firmament.</p>
+
+<p>With the speed of light a stellar voyage could be taken along the path
+of the Milky Way, which would endure for <span class='pagenum'><a name="Page_45" id="Page_45">[Pg 45]</a></span>thousands of years. Through
+all the course the journeyer would perceive the same vast girdle of
+stars, faint because they were far away, which gives the dim light of
+our galaxy. At no point is it probable that he would find the separate
+suns much more aggregated or greatly farther apart than they are in
+that part of the Milky Way which our sun now occupies. Looking forth
+on either side of the "galactic plane," there would be the same
+scattering of stars which we now behold when we gaze at right angles
+to the way we are supposing the spirit to traverse.</p>
+
+<p>As the form of the Milky Way is irregular, the mass, indeed, having
+certain curious divisions and branches, it well might be that the
+supposed path would occasionally pass on one or the other side of the
+vast star layer. In such positions the eye would look forth into an
+empty firmament, except that there might be in the far away, tens of
+thousands of years perhaps at the rate that light travels away from
+the observer, other galaxies or Milky Ways essentially like that which
+he was traversing. At some point the journeyer would attain the margin
+of our star stratum, whence again he would look forth into the
+unpeopled heavens, though even there he might discern other remote
+star groups separated from his own by great void intervals.</p>
+
+<hr style='width: 45%;' />
+
+<p>The revelations of the telescope show us certain features in the
+constitution and movements of the fixed stars which now demand our
+attention. In the first place, it is plain that not all of these
+bodies are in the same physical condition. Though the greater part of
+these distant luminous masses are evidently in the state of
+aggregation displayed by our own sun, many of them retain more or less
+of that vaporous, it may be dustlike, character which we suppose to
+have been the ancient state of all the matter in the universe. Some of
+these masses appear as faint, almost indistinguishable clouds, which
+even to the greatest telescope and the best-trained vision show no
+distinct fea<span class='pagenum'><a name="Page_46" id="Page_46">[Pg 46]</a></span>tures of structure. In other cases the nebulous
+appearance is hardly more than a mist about a tolerably distinct
+central star. Yet again, and most beautifully in the great nebula of
+the constellation of Orion, the cloudy mass, though hardly visible to
+the naked eye, shows a division into many separate parts, the whole
+appearing as if in process of concentration about many distinct
+centres.</p>
+
+<p>The nebulas are reasonably believed by many astronomers to be examples
+of the ancient condition of the physical universe, masses of matter
+which for some reason as yet unknown have not progressed in their
+consolidation to the point where they have taken on the
+characteristics of suns and their attendant planets.</p>
+
+<p>Many of the fixed stars, the incomplete list of which now amounts to
+several hundred, are curiously variable in the amount of light which
+they send out to the earth. Sometimes these variations are apparently
+irregular, but in the greater number of cases they have fixed periods,
+the star waxing and waning at intervals varying from a few months to a
+few years. Although some of the sudden flashings forth of stars from
+apparent small size to near the greatest brilliancy may be due to
+catastrophes such as might be brought about by the sudden falling in
+of masses of matter upon the luminous spheres, it is more likely that
+the changes which we observe are due to the fact that two suns
+revolving around a common centre are in different stages of
+extinction. It may well be that one of these orbs, presumably the
+smaller, has so far lost temperature that it has ceased to glow. If in
+its revolution it regularly comes between the earth and its luminous
+companion, the effect would be to give about such a change in the
+amount of light as we observe.</p>
+
+<p>The supposition that a bright sun and a relatively dark sun might
+revolve around a common centre of gravity may at first sight seem
+improbable. The fact is, however, that imperfect as our observations
+on the stars really are, we know many instances in which this kind of
+revolution of <span class='pagenum'><a name="Page_47" id="Page_47">[Pg 47]</a></span>one star about another takes place. In some cases these
+stars are of the same brilliancy, but in others one of the lights is
+much brighter than the other. From this condition to the state where
+one of the stars is so nearly dark as to be invisible, the transition
+is but slight. In a word, the evidence goes to show that while we see
+only the luminous orbs of space, the dark bodies which people the
+heavens are perhaps as numerous as those which send us light, and
+therefore appear as stars.</p>
+
+<p>Besides the greater spheres of space, there is a vast host of lesser
+bodies, the meteorites and comets, which appear to be in part members
+of our solar system, and perhaps of other similar systems, and in part
+wanderers in the vast realm which intervenes between the solar
+systems. Of these we will first consider the meteors, of which we know
+by far the most; though even of them, as we shall see, our knowledge
+is limited.</p>
+
+<p>From time to time on any starry night, and particularly in certain
+periods of the year, we may behold, at the distance of fifty or more
+miles above the surface of the earth, what are commonly called
+"shooting stars." The most of these flashing meteors are evidently
+very small, probably not larger than tiny sand grains, possibly no
+greater than the fragments which would be termed dust. They enter the
+air at a speed of about thirty miles a second. They are so small that
+they burn to vapour in the very great heat arising from their friction
+on the air, and do not attain the surface of the earth. These are so
+numerous that, on the average, some hundreds of thousands probably
+strike the earth's atmosphere each day. From time to time larger
+bodies fall&mdash;bodies which are of sufficient bulk not to be burned up
+in the air, but which descend to the ground. These may be from the
+smallest size which may be observed to masses of many hundred pounds
+in weight. These are far less numerous than the dust meteorites; it is
+probable, however, that several hundred fragments each year attain the
+earth's surface. They come from various direc<span class='pagenum'><a name="Page_48" id="Page_48">[Pg 48]</a></span>tions of space, and
+there is as yet no means of determining whether they were formed in
+some manner within our planetary system or whether they wander to us
+from remoter realms. We know that they are in part composed of
+metallic iron commingled with nickel and carbon (sometimes as very
+small diamonds) in a way rarely if ever found on the surface of our
+sphere, and having a structure substantially unknown in its deposits.
+In part they are composed of materials which somewhat resemble certain
+lavas. It is possible that these fragments of iron and stone which
+constitute the meteorites have been thrown into the planetary spaces
+by the volcanic eruption of our own and other planets. If hurled forth
+with a sufficient energy, the fragments would escape from the control
+of the attraction of the sphere whence they came, and would become
+independent wanderers in space, moving around the sun in varied orbits
+until they were again drawn in by some of the greater planets.</p>
+
+<p>As they come to us these meteorites often break up in the atmosphere,
+the bits being scattered sometimes over a wide area of country. Thus,
+in the case of the Cocke County meteorite of Tennessee, one of the
+iron species, the fragments, perhaps thousands in number, which came
+from the explosion of the body were scattered over an area of some
+thousand square miles. When they reach the surface in their natural
+form, these meteors always have a curious wasted and indented
+appearance, which makes it seem likely that they have been subject to
+frequent collisions in their journeys after they were formed by some
+violent rending action.</p>
+
+<p>In some apparent kinship with the meteorites may be classed the
+comets. The peculiarity of these bodies is that they appear in most
+cases to be more or less completely vaporous. Rushing down from the
+depths of the heavens, these bodies commonly appear as faintly
+shining, cloudlike masses. As they move in toward the sun long trails
+of vapour stream back from the somewhat consolidated head.<span class='pagenum'><a name="Page_49" id="Page_49">[Pg 49]</a></span> Swinging
+around that centre, they journey again into the outer realm. As they
+retreat, their tail-like streamers appear to gather again upon their
+centres, and when they fade from view they are again consolidated. In
+some cases it has been suspected that a part at least of the cometary
+mass was solid. The evidence goes to show, however, that the matter is
+in a dustlike or vaporous condition, and that the weight of these
+bodies is relatively very small.</p>
+
+<div class="figcenter" style="width: 422px;">
+<img src="images/f2.jpg" width="422" height="512" alt="Fig. 2.&mdash;The Great Comet of 1811, one of the many
+varied forms of these bodies." title="" />
+<span class="figcaption">Fig. 2.&mdash;The Great Comet of 1811, one of the many
+varied forms of these bodies.</span>
+</div>
+
+<p><span class='pagenum'><a name="Page_50" id="Page_50">[Pg 50]</a></span>
+Owing to their strange appearance, comets were to the ancients omens
+of calamity. Sometimes they were conceived as flaming swords; their
+forms, indeed, lend themselves to this imagining. They were thought to
+presage war, famine, and the death of kings. Again, in more modern
+times, when they were not regarded as portents of calamity, it was
+feared that these wanderers moving vagariously through our solar
+system might by chance come in contact with the earth with disastrous
+results. Such collisions are not impossible, for the reason that the
+planets would tend to draw these errant bodies toward them if they
+came near their spheres; yet the chance of such collisions happening
+to the earth is so small that they may be disregarded.</p>
+
+
+<h2 class="subtitle smcap">Motions of the Spheres.</h2>
+
+<p>Although little is known of the motions which occur among the
+celestial bodies beyond the sphere of our solar family, that which has
+been ascertained is of great importance, and serves to make it likely
+that all the suns in space are upon swift journeys which in their
+speed equal, if they do not exceed, the rate of motion among the
+planetary spheres, which may, in general, be reckoned at about twenty
+miles a second. Our whole solar system is journeying away from certain
+stars, and in the direction of others which are situated in the
+opposite part of the heavens. The proof of this fact is found in the
+observations which show that on one side of us the stars are
+apparently coming closer together, while on the other side they are
+going farther apart. The phenomenon, in a word, is one of perspective,
+and may be made real to the understanding by noting what takes place
+when we travel down a street <span class='pagenum'><a name="Page_51" id="Page_51">[Pg 51]</a></span>along which there are lights. We readily
+note that these lights appear to close in behind us, and widen their
+intervals in the direction in which we journey. By such evidence
+astronomers have become convinced that our sphere, along with the sun
+which controls it, is each second a score of miles away from the point
+where it was before.</p>
+
+<p>There is yet other and most curious evidence which serves to show that
+certain of the stars are journeying toward our part of the heavens at
+great speed, while others are moving away from us by their own proper
+motion. These indications are derived from the study of the lines in
+the light which the spectrum reveals to us when critically examined.
+The position of these cross lines is, as we know, affected by the
+motion of the body whence the light comes, and by close analysis of
+the facts it has been pretty well determined that the distortion in
+their positions is due to very swift motions of the several stars. It
+is not yet certain whether these movements of our sun and of other
+solar bodies are in straight lines or in great circles.</p>
+
+<p>It should be noted that, although the evidence from the spectroscope
+serves to show that the matter in the stars is akin to that of our own
+earth, there is reason to believe that those great spheres differ much
+from each other in magnitude.</p>
+
+<p>We have now set forth some of the important facts exhibited by the
+stellar universe. The body of details concerning that realm is vast,
+and the conclusions drawn from it important; only a part, however, of
+the matter with which it deals is of a nature to be apprehended by the
+student who does not approach it in a somewhat professional way. We
+shall therefore now turn to a description of the portion of the starry
+world which is found in the limits of our solar system. There the
+influences of the several spheres upon our planet are matters of vital
+importance; they in a way affect, if they do not control, all the
+operations which go on upon the surface of the earth.</p>
+
+<p><span class='pagenum'><a name="Page_52" id="Page_52">[Pg 52]</a></span></p>
+
+<h2 class="subtitle smcap">The Solar System.</h2>
+
+<p>We have seen that the matter in the visible universe everywhere tends
+to gather into vast associations which appear to us as stars, and that
+these orbs are engaged in ceaseless motion in journeys through space.
+In only one of these aggregations&mdash;that which makes our own solar
+system&mdash;are the bodies sufficiently near to our eyes for us, even with
+the resources of our telescopes and other instruments, to divine
+something of the details which they exhibit. In studying what we may
+concerning the family of the sun, the planets, and their satellites,
+we may reasonably be assured that we are tracing a history which with
+many differences is in general repeated in the development of each
+star in the firmament. Therefore the inquiry is one of vast range and
+import.</p>
+
+<p>Following, as we may reasonably do, the nebular hypothesis&mdash;a view
+which, though not wholly proved, is eminently probable&mdash;we may regard
+our solar system as having begun when the matter of which it is
+composed, then in a finely divided, cloudy state, was separated from
+the similar material which went to make the neighbouring fixed stars.
+The period when our solar system began its individual life was remote
+beyond the possibility of conception. Naturalists are pretty well
+agreed that living beings began to exist upon the earth at least a
+hundred million years ago; but the beginnings of our solar system must
+be placed at a date very many times as remote from the present day.<a name="FNanchor_1_1" id="FNanchor_1_1"></a><a href="#Footnote_1_1" class="fnanchor">[1]</a></p>
+
+<p>According to the nebular theory, the original vapour of the solar
+system began to fall in toward its centre and to whirl about that
+point at a time long before the mass <span class='pagenum'><a name="Page_53" id="Page_53">[Pg 53]</a></span>had shrunk to the present limits
+of the solar system as defined by the path of the outermost planets.
+At successive stages of the concentration, rings after the manner of
+those of Saturn separated from the disklike mass, each breaking up and
+consolidating into a body of nebulous matter which followed in the
+same path, generally forming rings which became by the same process
+the moons or satellites of the sphere. In this way the sun produced
+eight planets which are known, and possibly others of small size on
+the outer verge of the system which have eluded discovery. According
+to this view, the planetary masses were born in succession, the
+farthest away being the oldest. It is, however, held by an able
+authority that the mass of the solar system would first form a rather
+flat disk, the several rings forming and breaking into planets at
+about the same time. The conditions in Saturn, where the inner ring
+remains parted, favours the view just stated.</p>
+
+<p>Before making a brief statement of the several planets, the asteroids,
+and the satellites, it will be well to consider in a general way the
+motions of these bodies about their centres and about the sun. The
+most characteristic and invariable of these movements is that by which
+each of the planetary spheres, as well as the satellites, describes an
+orbit around the gravitative centre which has the most influence upon
+it&mdash;the sun. To conceive the nature of this movement, it will be well
+to imagine a single planet revolving around the sun, each of these
+bodies being perfect spheres, and the two the only members of the
+solar system. In this condition the attraction of the two bodies would
+cause them to circle around a common centre of gravity, which, if the
+planet were not larger or the sun smaller than is the case in our
+solar system, would lie within the mass of the sun. In proportion as
+the two bodies might approach each other in size, the centre of
+gravity would come the nearer to the middle point in a line connecting
+the two spheres. In this condition of a sun with a single planet,
+whatever were the relative size of sun and planet, <span class='pagenum'><a name="Page_54" id="Page_54">[Pg 54]</a></span>the orbits which
+they traverse would be circular. In this state of affairs it should be
+noted that each of the two bodies would have its plane of rotation
+permanently in the same position. Even if the spheres were more or
+less flattened about the poles of their axes, as is the case with all
+the planets which we have been able carefully to measure, as well as
+with the sun, provided the axes of rotation were precisely parallel to
+each other, the mutual attraction of the masses would cause no
+disturbance of the spheres. The same would be the case if the polar
+axis of one sphere stood precisely at right angles to that of the
+other. If, however, the spheres were somewhat flattened at the poles,
+and the axes inclined to each other, then the pull of one mass on the
+other would cause the polar axes to keep up a constant movement which
+is called nutation, or nodding.</p>
+
+<p>The reason why this nodding movement of the polar axes would occur
+when these lines were inclined to each other is not difficult to see
+if we remember that the attraction of masses upon each other is
+inversely as the square of the distance; each sphere, pulling on the
+equatorial bulging of the other, pulls most effectively on the part of
+it which is nearest, and tends to draw it down toward its centre. The
+result is that the axes of the attracted spheres are given a wobbling
+movement, such as we may note in the spinning top, though in the toy
+the cause of the motion is not that which we are considering.</p>
+
+<p>If, now, in that excellent field for the experiment we are essaying,
+the mind's eye, we add a second planet outside of the single sphere
+which we have so far supposed to journey about the sun, or rather
+about the common centre of gravity, we perceive at once that we have
+introduced an element which leads to a complication of much
+importance. The new sphere would, of course, pull upon the others in
+the measure of its gravitative value&mdash;i.e., its weight. The centre of
+gravity of the system would now be determined not by two distinct
+bodies, but by three. If we conceive the second planet to journey
+around the <span class='pagenum'><a name="Page_55" id="Page_55">[Pg 55]</a></span>sun at such a rate that a straight line always connected
+the centres of the three orbs, then the only effect on their
+gravitative centre would be to draw the first-mentioned planet a
+little farther away from the centre of the sun; but in our own solar
+system, and probably in all others, this supposition is inadmissible,
+because the planets have longer journeys to go and also move slower,
+the farther they are from the sun. Thus Mercury completes the circle
+of its year in eighty-eight of our days, while the outermost planet
+requires sixty thousand days (more than one hundred and sixty-four
+years) for the same task. The result is not only that the centre of
+gravity of the system is somewhat displaced&mdash;itself a matter of no
+great account&mdash;but also that the orbit of the original planet ceases
+to be circled and becomes elliptical, and this for the evident reason
+that the sphere will be drawn somewhat away from the sun when the
+second planet happens to lie in the part of its orbit immediately
+outside of its position, in which case the pull is away from the solar
+centre; while, on the other hand, when the new planet was on the other
+side of the sun, its pull would serve to intensify the attraction
+which drew the first sphere toward the centre of gravity. As the
+pulling action of the three bodies upon each other, as well as upon
+their equatorial protuberances, would vary with every change in their
+relative position, however slight, the variations in the form of their
+orbits, even if the spheres were but three in number, would be very
+important. The consequences of these perturbations will appear in the
+sequel.</p>
+
+<p>In our solar system, though there are but eight great planets, the
+group of asteroids, and perhaps a score of satellites, the variety of
+orbital and axial movement which is developed taxes the computing
+genius of the ablest astronomer. The path which our earth follows
+around the sun, though it may in general and for convenience be
+described as a variable ellipse, is, in fact, a line of such
+complication that if we should essay a diagram of it <span class='pagenum'><a name="Page_56" id="Page_56">[Pg 56]</a></span>on the scale of
+this page it would not be possible to represent any considerable part
+of its deviations. These, in fact, would elude depiction, even if the
+draughtsman had a sheet for his drawing as large as the orbit itself,
+for every particle of matter in space, even if it be lodged beyond the
+limits of the farthest stars revealed to us by the telescope,
+exercises a certain attraction, which, however small, is effective on
+the mass of the earth. Science has to render its conclusions in
+general terms, and we can safely take them as such; but in this, as in
+other instances, it is well to qualify our acceptance of the
+statements by the memory that all things are infinitely more
+complicated than we can possibly conceive or represent them to be.</p>
+
+<p>We have next to consider the rotations of the planetary spheres upon
+their axes, together with the similar movement, or lack of it, in the
+case of their satellites. This rotation, according to the nebular
+hypothesis, may be explained by the movements which would set up in
+the share of matter which was at first a ring of the solar nebula, and
+which afterward gathered into the planetary aggregation. The way of it
+may be briefly set forth as follows: Such a ring doubtless had a
+diameter of some million miles; we readily perceive that the particles
+of matter in the outer part of the belt would have a swifter movement
+around the sun than those on the inside. When by some disturbance, as
+possibly by the passage of a great meteoric body of a considerable
+gravitative power, this ring was broken in two, the particles
+composing it on either side would, because of their mutual attraction,
+tend to draw away from the breach, widening that gap until the matter
+of the broken ring was aggregated into a sphere of the star dust or
+vapour. When the nebulous matter originally in the ring became
+aggregated into a spherical form, it would, on account of the
+different rates at which the particles were moving when they came
+together, be the surer to fall in toward the centre, not in straight
+lines, but in curves&mdash;in other words, the mass would necessarily take
+on a move<span class='pagenum'><a name="Page_57" id="Page_57">[Pg 57]</a></span>ment of rotation essentially like that which we have
+described in setting forth the nebular hypothesis.</p>
+
+<p>In the stages of concentration the planetary nebul&aelig; might well repeat
+those through which the greater solar mass proceeded. If the volume of
+the material were great, subordinate rings would be formed, which when
+they broke and concentrated would constitute secondary planets or
+satellites, such as our moon. For some reason as yet unknown the outer
+planets&mdash;in fact, all those in the solar system except the two inner,
+Venus and Mercury and the asteroids&mdash;formed such attendants. All these
+satellite-forming rings have broken and concentrated except the inner
+of Saturn, which remains as an intellectual treasure of the solar
+system to show the history of its development.</p>
+
+<p>To the student who is not seeking the fulness of knowledge which
+astronomy has to offer, but desires only to acquaint himself with the
+more critical and important of the heavenly phenomena which help to
+explain the earth, these features of planetary movement should prove
+especially interesting for the reason that they shape the history of
+the spheres. As we shall hereafter see, the machinery of the earth's
+surface, all the life which it bears, its winds and rains&mdash;everything,
+indeed, save the actions which go on in the depths of the sphere&mdash;is
+determined by the heat and light which come from the sun. The
+conditions under which this vivifying tide is received have their
+origin in the planetary motion. If our earth's path around the centre
+of the system was a perfect circle, and if its polar axis lay at right
+angles to the plane of its journey, the share of light and heat which
+would fall upon any one point on the sphere would be perfectly
+uniform. There would be no variations in the length of day or night;
+no changes in the seasons; the winds everywhere would blow with
+exceeding steadiness&mdash;in fact, the present atmospheric confusion would
+be reduced to something like order. From age to age, except so far as
+the sun itself might vary in the amount of energy which it radiated,
+or lands rose up <span class='pagenum'><a name="Page_58" id="Page_58">[Pg 58]</a></span>into the air or sunk down toward the sea level, the
+climate of each region would be perfectly stable. In the existing
+conditions the influences bring about unending variety. First of all,
+the inclined position of the polar axis causes the sun apparently to
+move across the heavens, so that it comes in an overhead position once
+or twice in the year in quite half the area of the lands and seas.
+This apparent swaying to and fro of the sun, due to the inclination of
+the axis of rotation, also affects the width of the climatal belts on
+either side of the equator, so that all parts of the earth receive a
+considerable share of the sun's influence. If the axis of the earth's
+rotation were at right angles to the plane of its orbit, there would
+be a narrow belt of high temperature about the equator, north and
+south of which the heat would grade off until at about the parallels
+of fifty degrees we should find a cold so considerable and uniform
+that life would probably fade away; and from those parallels to the
+poles the conditions would be those of permanent frost, and of days
+which would darken into the enduring night or twilight in the realm
+of the far north and south. Thus the wide habitability of the earth is
+an effect arising from the inclination of its polar axis.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f3.jpg" width="640" height="223" alt="Fig. 3.&mdash;Inclination of Planetary Orbits (from
+Chambers)." title="" />
+<span class="figcaption">Fig. 3.&mdash;Inclination of Planetary Orbits (from Chambers).</span>
+</div>
+
+<p><span class='pagenum'><a name="Page_59" id="Page_59">[Pg 59]</a></span>
+As the most valuable impression which the student can receive from his
+study of Nature is that sense of the order which has made possible all
+life, including his own, it will be well for him to imagine, as he may
+readily do, what would be the effect arising from changes in relations
+of earth and sun. Bringing the earth's axis in imagination into a
+position at right angles to the plane of the orbit, he will see that
+the effect would be to intensify the equatorial heat, and to rob the
+high latitudes of the share which they now have. On moving the axis
+gradually to positions where it approaches the plane of the orbit, he
+will note that each stage of the change widens the tropic belt.
+Bringing the polar axis down to the plane of the orbit, one hemisphere
+would receive unbroken sunshine, the other remaining in perpetual
+darkness and cold. In this condition, in place of an equatorial line
+we should have an equatorial point at the pole nearest the sun; thence
+the temperatures would grade away to the present equator, beyond which
+half the earth would be in more refrigerating condition than are the
+poles at the present day. In considering the movements of our planet,
+we shall see that no great changes in the position of the polar axis
+can have taken place. On this account the suggested alterations of the
+axis should not be taken as other than imaginary changes.</p>
+
+<p>It is easy to see that with a circular orbit and with an inclined axis
+winter and summer would normally come always at the same point in the
+orbit, and that these seasons would be of perfectly even length. But,
+as we have before noted, the earth's path around the sun is in its
+form greatly affected by the attractions which are exercised by the
+neighbouring planets, principally by those great spheres which lie in
+the realm without its orbit, Jupiter and Saturn. When these attracting
+bodies, as is the case from <span class='pagenum'><a name="Page_60" id="Page_60">[Pg 60]</a></span>time to time, though at long intervals,
+are brought together somewhere near to that part of the solar system
+in which the earth is moving around the sun, they draw our planet
+toward them, and so make its path very elliptical. When, however, they
+are so distributed that their pulling actions neutralize each other,
+the orbit returns more nearly to a circular form. The range in its
+eccentricity which can be brought about by these alterations is very
+great. When the path is most nearly circular, the difference in the
+major and minor axis may amount to as little as about five hundred
+thousand miles, or about one one hundred and eighty-sixth of its
+average diameter. When the variation is greatest the difference in
+these measurements may be as much as near thirteen million miles, or
+about one seventh of the mean width of the orbit.</p>
+
+<p>The first and most evident effect arising from these changes of the
+orbit comes from the difference in the amount of heat which the earth
+may receive according as it is nearer or farther from the sun. As in
+the case of other fires, the nearer a body is to it the larger the
+share of light and heat which it will receive. In an orbit made
+elliptical by the planetary attraction the sun necessarily occupies
+one of the foci of the ellipse. The result is, of course, that the
+side of the earth which is toward the sun, while it is thus brought
+the nearer to the luminary, receives more energy in the form of light
+and heat than come to any part which is exposed when the spheres are
+farther away from each other in the other part of the orbit.
+Computations clearly show that the total amount of heat and the
+attendant light which the earth receives in a year is not affected by
+these changes in the form of its path. While it is true that it
+receives heat more rapidly in the half of the ellipse which is nearest
+the source of the inundation, it obtains less while it is farther
+away, and these two variations just balance each other.</p>
+
+<p>Although the alterations in the eccentricity of its orbit do not vary
+the annual supply of heat which the earth re<span class='pagenum'><a name="Page_61" id="Page_61">[Pg 61]</a></span>ceives, they are capable
+of changing the character of the seasons, and this in the way which we
+will now endeavour to set forth, though we must do it at the cost of
+considerable attention on the part of the reader, for the facts are
+somewhat complicated. In the first place, we must note that the
+ellipticity of the earth's orbit is not developed on fixed lines, but
+is endlessly varied, as we can readily imagine it would be for the
+reason that its form depends upon the wandering of the outer planetary
+spheres which pull the earth about. The longer axis of the ellipse is
+itself in constant motion in the direction in which the earth travels.
+This movement is slow, and at an irregular rate. It is easy to see
+that the effect of this action, which is called the revolution of the
+apsides, or, as the word means, the movement of the poles of the
+ellipse, is to bring the earth, when a given hemisphere is turned
+toward the sun, sometimes in the part of the orbit which is nearest
+the source of light and heat, and sometimes farther away. It may thus
+well come about that at one time the summer season of a hemisphere
+arrives when it is nearest the sun, so that the season, though hot,
+will be very short, while at another time the same season will arrive
+when the earth is farthest from the sun, and receives much less heat,
+which would tend to make a long and relatively cool summer. The reason
+for the difference in length of the seasons is to be found in the
+relative swiftness of the earth's revolution when it is nearest the
+sun, and the slowness when it is farther away.</p>
+
+<p>There is a further complication arising from that curious phenomenon
+called the precession of the equinoxes, which has to be taken into
+account before we can sufficiently comprehend the effect of the
+varying eccentricity of the orbit on the earth's seasons. To
+understand this feature of precession we should first note that it
+means that each year the change from the winter to the summer&mdash;or, as
+we phrase it, the passage of the equinoctial line&mdash;occurs a little
+sooner than the year before. The cause of <span class='pagenum'><a name="Page_62" id="Page_62">[Pg 62]</a></span>this is to be found in the
+attraction which the heavenly bodies, practically altogether the moon,
+exercises on the equatorial protuberance of the earth. We know that
+the diameter of our sphere at the equator is, on the average,
+something more than twenty-six miles greater than it is through the
+poles. We know, furthermore, that the position of the moon in relation
+to the earth is such that it causes the attraction on one half of this
+protuberance to be greater than it is upon the other. We readily
+perceive that this action will cause the polar axis to make a certain
+revolution, or, what comes to the same thing, that the plane of the
+equator will constantly be altering its position. Now, as the
+equinoctial points in the orbit depend for their position upon the
+attitude of the equatorial plane, we can conceive that the effect is a
+change in position of the place in that orbit where summer and winter
+begin. The actual result is to bring the seasonal points backward,
+step by step, through the orbit in a regular measure until in
+twenty-two thousand five hundred years they return to the place where
+they were before. This cycle of change was of old called the Annus
+Magnus, or great year.</p>
+
+<p>If the earth's orbit were an ellipse, the major axis of which remained
+in the same position, we could readily reckon all the effects which
+arise from the variations of the great year. But this ellipse is ever
+changing in form, and in the measure of its departure from a circle
+the effects on the seasons distributed over a great period of time are
+exceedingly irregular. Now and then, at intervals of hundreds of
+thousands or millions of years, the orbit becomes very elliptical;
+then again for long periods it may in form approach a circle. When in
+the state of extreme ellipticity, the precession of the equinoxes will
+cause the hemispheres in turn each to have their winter and summer
+alternately near and far from the sun. It is easily seen that when the
+summer season comes to a hemisphere in the part of the orbit which is
+then nearest the sun the period will be <span class='pagenum'><a name="Page_63" id="Page_63">[Pg 63]</a></span>very hot. When the summer
+came farthest from the sun that part of the year would have the
+temperature mitigated by its removal to a greater distance from the
+source of heat. A corresponding effect would be produced in the winter
+season. As long as the orbit remained eccentric the tendency would be
+to give alternately intense seasons to each hemisphere through periods
+of about twelve thousand years, the other hemisphere having at the
+same time a relatively slight variation in the summer and winter.</p>
+
+<p>At first sight it may seem to the reader that these studies we have
+just been making in matters concerning the shape of the orbit and the
+attendant circumstances which regulate the seasons were of no very
+great consequence; but, in the opinion of some students of climate, we
+are to look to these processes for an explanation of certain climatal
+changes on the earth, including the Glacial periods, accidents which
+have had the utmost importance in the history of man, as well as of
+all the other life of the planet.</p>
+
+<p>It is now time to give some account as to what is known concerning the
+general conditions of the solar bodies&mdash;the planets and satellites of
+our own celestial group. For our purpose we need attend only to the
+general physical state of these orbs so far as it is known to us by
+the studies of astronomers. The nearest planet to the sun is Mercury.
+This little sphere, less than half the diameter of our earth, is so
+close to the sun that even when most favourably placed for observation
+it is visible for but a few minutes before sunrise and after sunset.
+Although it may without much difficulty be found by the ordinary eye,
+very few people have ever seen it. To the telescope when it is in the
+<i>full moon</i> state it appears as a brilliant disk; it is held by most
+astronomers that the surface which we see is made up altogether of
+clouds, but this, as most else that has been stated concerning this
+planet, is doubtful. The sphere is so near to the sun that if it were
+possessed of water it would inevitably bear an atmosphere full of
+<span class='pagenum'><a name="Page_64" id="Page_64">[Pg 64]</a></span>vapour. Under any conceivable conditions of a planet placed as
+Mercury is, provided it had an atmosphere to retain the heat, its
+temperature would necessarily be very high. Life as we know it could
+not well exist upon such a sphere.</p>
+
+<p>Next beyond Mercury is Venus, a sphere only a little less in diameter
+than the earth. Of this sphere we know more than we do of Mercury, for
+the reason that it is farther from the sun and so appears in the
+darkened sky. Most astronomers hold that the surface of this planet
+apparently is almost completely and continually hidden from us by what
+appears to be a dense cloud envelope, through which from time to time
+certain spots appear of a dark colour. These, it is claimed, retain
+their place in a permanent way; it is, indeed, by observing them that
+the rotation period of the planet has, according to some observers,
+been determined. It therefore seems likely that these spots are the
+summits of mountains, which, like many of our own earth, rise above
+the cloud level.</p>
+
+<p>Recent observations on Venus made by Mr. Percival Lowell appear to
+show that the previous determinations of the rotation of that planet,
+as well as regards its cloud wrap, are in error. According to these
+observations, the sphere moves about the sun, always keeping the same
+side turned toward the solar centre, just as the moon does in its
+motion around the earth. Moreover, Mr. Lowell has failed to discover
+any traces of clouds upon the surface of the planet. As yet these
+results have not been verified by the work of other astronomers;
+resting, however, as they do on studies made with an excellent
+telescope and in the very translucent and steady air of the Flagstaff
+Station, they are more likely to be correct than those obtained by
+other students. If it be true that Venus does not turn upon its axis,
+such is likely to be the case also with the planet Mercury.</p>
+
+<p>Next in the series of the planets is our own earth. As the details of
+this planet are to occupy us during nearly <span class='pagenum'><a name="Page_65" id="Page_65">[Pg 65]</a></span>all the remainder of this
+work, we shall for the present pass it by.</p>
+
+<p>Beyond the earth we pass first to the planet Mars, a sphere which has
+already revealed to us much concerning its peculiarities of form and
+physical state, and which is likely in the future to give more
+information than we shall obtain from any other of our companions in
+space, except perhaps the moon. Mars is not only nearer to us than any
+other planet, but it is so placed that it receives the light of the
+sun under favourable conditions for our vision. Moreover, its sky
+appears to be generally almost cloudless, so that when in its orbital
+course the sphere is nearest our earth it is under favourable
+conditions for telescopic observation. At such times there is revealed
+to the astronomer a surface which is covered with an amazing number of
+shadings and markings which as yet have been incompletely interpreted.
+The faint nature of these indications has led to very contradictory
+statements as to their form; no two maps which have been drawn agree
+except in their generalities. There is reason to believe that Mars has
+an atmosphere; this is shown by the fact that in the appropriate
+season the region about either pole is covered by a white coating,
+presumably snow. This covering extends rather less far toward the
+planet's equator than does the snow sheet on our continents. Taking
+into account the colour of the coating, and the fact that it
+disappears when the summer season comes to the hemisphere in which it
+was formed, we are, in fact, forced to believe that the deposit is
+frozen water, though it has been suggested that it may be frozen
+carbonic acid. Taken in connection with what we have shortly to note
+concerning the apparent seas of this sphere, the presumption is
+overwhelmingly to the effect that Mars has seasons not unlike our own.</p>
+
+<p>The existence of snow on any sphere may safely be taken as evidence
+that there is an atmosphere. In the case of Mars, this supposition is
+borne out by the appearance of its surface. The ruddy light which it
+sends back <span class='pagenum'><a name="Page_66" id="Page_66">[Pg 66]</a></span>to us, and the appearance on the margin of the sphere,
+which is somewhat dim, appears to indicate that its atmosphere is
+dense. In fact, the existence of an atmosphere much denser than that
+of our own earth appears to be demanded by the fact that the
+temperatures are such as to permit the coming and going of snow. It is
+well known that the temperature of any point on the earth, other
+things being equal, is proportionate to the depth of atmosphere above
+its surface. If Mars had no more air over its surface than has an
+equal area of the earth, it would remain at a temperature so low that
+such seasonal changes as we have observed could not take place. The
+planet receives one third less heat than an equal area of the earth,
+and its likeness to our own temperature, if such exists, is doubtless
+brought about by the greater density of its atmosphere, that serves to
+retain the heat which comes upon its surface. The manner in which this
+is effected will be set forth in the study of the earth's atmosphere.</p>
+
+<div class="figleft" style="width: 320px;">
+<img src="images/f4.jpg" width="320" height="309" alt="Fig. 4.&mdash;Mars, August 27, 1892 (Guiot), the white patch
+is the supposed Polar Snow Cap." title="" />
+<span class="figcaption">Fig. 4.&mdash;Mars, August 27, 1892 (Guiot), the white patch
+is the supposed Polar Snow Cap.</span>
+</div>
+
+<p>As is shown by the maps of Mars, the surface is occupied by shadings
+which seem to indicate the existence of water and lands. Those
+portions of the area which are taken to be land are very much divided
+by what appear to be narrow seas. The general geographic conditions
+differ much from those of <span class='pagenum'><a name="Page_67" id="Page_67">[Pg 67]</a></span>our own sphere in that the parts of the
+planet about the water level are not grouped in great continents, and
+there are no large oceans. The only likeness to the conditions of our
+earth which we can perceive is in a general pointing of the somewhat
+triangular masses of what appears to be land toward one pole. As a
+whole, the conditions of the Martial lands and seas as regards their
+form, at least, is more like that of Europe than that of any other
+part of the earth's surface. Europe in the early Tertiary times had a
+configuration even more like that of Mars than it exhibits at present,
+for in that period the land was very much more divided than it now is.</p>
+
+<p>If the lands of Mars are framed as are those of our own earth, there
+should be ridges of mountains constituting what we may term the
+backbones of the continent. As yet such have not been discerned, which
+may be due to the fact that they have not been carefully looked for.
+The only peculiar physical features which have as yet been discerned
+on the lands of Mars are certain long, straight, rather narrow
+crevicelike openings, which have received the name of "canals." These
+features are very indistinct, and are just on the limit of visibility.
+As yet they have been carefully observed by but few students, so that
+their features are not yet well recorded; as far as we know them,
+these fissures have no likeness in the existing conditions of our
+earth. It is difficult to understand how they are formed or preserved
+on a surface which is evidently subjected to rainfalls.</p>
+
+<p>It will require much more efficient telescopes than we now have before
+it will be possible to begin any satisfactory study on the geography
+of this marvellous planet. We can not hope as yet to obtain any
+indications as to the details of its structure; we can not see closely
+enough to determine whether rivers exist, or whether there is a
+coating which we may interpret as vegetation, changing its hues in the
+different seasons of the year. An advance in our instruments of
+research during the coming century, <span class='pagenum'><a name="Page_68" id="Page_68">[Pg 68]</a></span>if made with the same speed as
+during the last, will perhaps enable us to interpret the nature of
+this neighbour, and thereby to extend the conception of planetary
+histories which we derive from our own earth.</p>
+
+<div class="figcenter" style="width: 521px;">
+<img src="images/f5.jpg" width="521" height="640" alt="Fig. 5.&mdash;Comparative Sizes of the Planets (Chambers)." title="" />
+<span class="figcaption">Fig. 5.&mdash;Comparative Sizes of the Planets (Chambers).</span>
+</div>
+
+<p>Beyond Mars we find one of the most singular features of our solar
+system in a group of small planetary bodies, the number of which now
+known amounts to some two hundred, and the total may be far greater.
+These bodies are evidently all small; it is doubtful if the largest is
+three hundred and the smaller more than twenty miles in diameter. So
+far as it has been determined by the effect of their aggregate mass in
+attracting the other spheres, they would, <span class='pagenum'><a name="Page_69" id="Page_69">[Pg 69]</a></span>if put together, make a
+sphere far less in diameter than our earth, perhaps not more than five
+hundred miles through. The forms of these asteroids is as yet unknown;
+we therefore can not determine whether their shapes are spheroidal, as
+are those of the other planets, or whether they are angular bits like
+the meteorites. We are thus not in a position to conjecture whether
+their independence began when the nebulous matter of the ring to which
+they belonged was in process of consolidation, or whether, after the
+aggregation of the sphere was accomplished, and the matter solidified,
+the mass was broken into bits in some way which we can not yet
+conceive. It has been conjectured that such a solid sphere might have
+been driven asunder by a collision with some wandering celestial body;
+but all we can conceive of such actions leads us to suppose that a
+blow of this nature would tend to melt or convert materials subjected
+to it into the state of vapour, rather than to drive them asunder in
+the manner of an explosion.</p>
+
+<p>The four planets which lie beyond the asteroids give us relatively
+little information concerning their physical condition, though they
+afford a wide field for the philosophic imagination. From this point
+of view the reader is advised to consult the writings of the late R.A.
+Proctor, who has brought to the task of interpreting the planetary
+conditions the skill of a well-trained astronomer and a remarkable
+constructive imagination.</p>
+
+<p>The planet Jupiter, by far the largest of the children of the sun,
+appears to be still in a state where its internal heat has not so far
+escaped that the surface has cooled down in the manner of our earth.
+What appear to be good observations show that the equatorial part of
+its area, at least, still glows from its own heat. The sphere is
+cloud-wrapped, but it is doubtful whether the envelope be of watery
+vapour; it is, indeed, quite possible that besides such vapour it may
+contain some part of the many substances which occupy the atmosphere
+of the sun. If the Jovian sphere were no larger than the earth, it
+would, on account <span class='pagenum'><a name="Page_70" id="Page_70">[Pg 70]</a></span>of its greater age, long ago have parted with its
+heat; but on account of its great size it has been able,
+notwithstanding its antiquity, to retain a measure of temperature
+which has long since passed away from our earth.</p>
+
+<p>In the case of Saturn, the cloud bands are somewhat less visible than
+on Jupiter, but there is reason to suppose in this, as in the
+last-named planet, that we do not behold the more solid surface of the
+sphere, but see only a cloud wrap, which is probably due rather to the
+heat of the sphere itself than to that which comes to it from the sun.
+At the distance of Saturn from the centre of the solar system a given
+area of surface receives less than one ninetieth of the sun's heat as
+compared with the earth; therefore we can not conceive that any
+density of the atmosphere whatever would suffice to hold in enough
+temperature to produce ordinary clouds. Moreover, from time to time
+bright spots appear on the surface of the planet, which must be due to
+some form of eruptions from its interior.</p>
+
+<p>Beyond Saturn the two planets Uranus and Neptune, which occupy the
+outer part of the solar system, are so remote that even our best
+telescopes discern little more than their presence, and the fact that
+they have attendant moons.</p>
+
+<p>From the point of view of astronomical science, the outermost planet
+Neptune, of peculiar interest for the reason that it was, as we may
+say, discovered by computation. Astronomers had for many years
+remarked the fact that the next inner planetary sphere exhibited
+peculiarities in its orbit which could only be accounted for on the
+supposition that it was subjected to the attraction of another
+wandering body which had escaped observation. By skilful computation
+the place in the heavens in which this disturbing element lay was so
+accurately determined that when the telescope was turned to the given
+field a brief study revealed the planet. Nothing else in the history
+of the science of astronomy, unless it be the computation of eclipses,
+so clearly and popularly shows the accuracy <span class='pagenum'><a name="Page_71" id="Page_71">[Pg 71]</a></span>of the methods by which
+the work of that science may be done.</p>
+
+<p>As we shall see hereafter, in the chapters which are devoted to
+terrestrial phenomena, the physical condition of the sun determines
+the course of all the more important events which take place on the
+surface of the earth. It is therefore fit that in this preliminary
+study of the celestial bodies, which is especially designed to make
+the earth more interpretable to us, we should give a somewhat special
+attention to what is known under the title of "Solar Physics."</p>
+
+<p>The reader has already been told that the sun is one of many million
+similar bodies which exist in space, and, furthermore, that these
+aggregations of matter have been developed from an original nebulous
+condition. The facts indicate that the natural history of the sun, as
+well as that of its attendant spheres, exhibits three momentous
+stages: First, that of vapour; second, that of igneous fluidity;
+third, that in which the sphere is so far congealed that it becomes
+dark. Neither of these states is sharply separated from the other; a
+mass may be partly nebulous and partly fluid; even when it has been
+converted into fluid, or possibly into the solid state, it may still
+retain on the exterior some share of its original vaporous condition.
+In our sun the concentration has long since passed beyond the limits
+of the nebulous state; the last of the successively developed rings
+has broken, and has formed itself into the smallest of the planets,
+which by its distance from the sun seems to indicate that the process
+of division by rings long ago attained in our solar system its end,
+the remainder of its nebulous material concentrating on its centre
+without sign of any remaining tendency to produce these planet-making
+circles.</p>
+
+<p><span class='pagenum'><a name="Page_72" id="Page_72">[Pg 72]</a></span></p>
+<h2 class="subtitle smcap">The Constitution of the Sun.</h2>
+
+<p>Before the use of the telescope in astronomical work, which was begun
+by the illustrious Galileo in 1608, astronomers were unable to
+approach the problem of the structure of the sun. They could discern
+no more than can be seen by any one who looks at the great sphere
+through a bit of smoked glass, as we know this reveals a disklike body
+of very uniform appearance. The only variation in this simple aspect
+occurs at the time of a total eclipse, when for a minute or two the
+moon hides the whole body of the sun. On such occasions even the
+unaided eye can see that there is about the sphere a broad, rather
+bright field, of an aspect like a very thin cloud or fog, which rises
+in streamer like projections at points to a quarter of a million miles
+or more above the surface of the sphere. The appearance of this
+shining field, which is called the corona, reminds one of the aurora
+which glows in the region about either pole of the earth.</p>
+
+<p>One of the first results of the invention of the telescope was the
+revelation of the curious dark objects on the sun's disk, known by the
+name of spots from the time of their discovery, or, at least, from the
+time when it was clearly perceived that they were not planets, but
+really on the solar body. The interest in the constitution of the
+sphere has increased during the last fifty years. This interest has
+rapidly grown until at the present time a vast body of learning has
+been gathered for the solution of the many problems concerning the
+centre of our system. As yet there is great divergence in the views of
+astronomers as to the interpretation of their observations, but
+certain points of great general interest have been tolerably well
+determined. These may be briefly set forth by an account of what would
+meet the eye if an observer were able to pass from the surface of the
+earth to the central part of the sun.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a name="img03"></a>
+<img src="images/p3.jpg" width="640" height="399" alt="Lava stream, in Hawaiian Islands, flowing into the
+sea. Note the &quot;ropy&quot; character of the half-frozen rock on the sides of
+the nearest rivulet of the lava." title="" />
+<span class="caption">Lava stream, in Hawaiian Islands, flowing into the
+sea. Note the &quot;ropy&quot; character of the half-frozen rock on the sides of
+the nearest rivulet of the lava.</span>
+</div>
+
+<p>In passing from the earth to a point about a quarter <span class='pagenum'><a name="Page_73" id="Page_73">[Pg 73]</a></span>of a million
+miles from the sun's surface&mdash;a distance about that of the moon from
+our sphere&mdash;the observer would traverse the uniformly empty spaces of
+the heavens, where, but for the rare chance of a passing meteorite or
+comet, there would be nothing that we term matter. Arriving at a point
+some two or three hundred thousand miles from the body of the sun, he
+would enter the realm of the corona; here he would find scattered
+particles of matter, the bits so far apart that there would perhaps be
+not more than one or two in the cubic mile; yet, as they would glow
+intensely in the central light, they would be sufficient to give the
+illumination which is visible in an eclipse. These particles are most
+likely driven up from the sun by some electrical action, and are
+constantly in motion, much as are the streamers of the aurora.</p>
+
+<p>Below the corona and sharply separated from it the observer finds
+another body of very dense vapour, which is termed the chromosphere,
+and which has been regarded as the atmosphere of the sun. This layer
+is probably several thousand miles thick. From the manner in which it
+moves, in the way the air of our own planet does in great storms, it
+is not easy to believe that it is a fluid, yet its sharply defined
+upper surface leads us to suppose that it can not well be a mere mass
+of vapour. The spectroscope shows us that this chromosphere contains
+in the state of vapour a number of metallic substances, such as iron
+and magnesium. To an observer who could behold this envelope of the
+sun from the distance at which we see the moon, the spectacle would be
+more magnificent than the imagination, guided by the sight of all the
+relatively trifling fractures of our earth, can possibly conceive.
+From the surface of the fiery sea vast uprushes of heated matter rise
+to the height of two or three hundred thousand miles, and then fall
+back upon its surface. These jets of heated matter have the aspect of
+flames, but they would not be such in fact, for the materials are not
+burning, but merely kept at a high temperature by the heat of the
+great sphere <span class='pagenum'><a name="Page_74" id="Page_74">[Pg 74]</a></span>beneath. They spring up with such energy that they at
+times move with a speed of one hundred and fifty miles a second, or at
+a rate which is attained by no other matter in the visible universe,
+except that strange, wandering star known to astronomers as
+"Grombridge, 1830," which is traversing the firmament with a speed of
+not less than two hundred miles a second.</p>
+
+<p>Below the chromosphere is the photosphere, the lower envelope of the
+sun, if it be not indeed the body of the sphere itself; from this
+comes the light and heat of the mass. This, too, can not well be a
+firm-set mass, for the reason that the spots appear to form in and
+move over it. It may be regarded as an extremely dense mass of gas, so
+weighed down by the vast attraction of the great sphere below it that
+it is in effect a fluid. The near-at-hand observer would doubtless
+find this photosphere, as it appears in the telescope, to be sharply
+separated from the thinner and more vaporous envelopes&mdash;the
+chromosphere and the corona&mdash;which are, indeed, so thin that they are
+invisible even with the telescope, except when the full blaze of the
+sun is cut off in a total eclipse. The fact that the photosphere,
+except when broken by the so-called spots, lies like a great smooth
+sea, with no parts which lie above the general line, shows that it has
+a very different structure from the envelope which lies upon it. If
+they were both vaporous, there would be a gradation between them.</p>
+
+<p>On the surface of the photosphere, almost altogether within thirty
+degrees of the equator of the sun, a field corresponding approximately
+to the tropical belt of the earth, there appear from time to time the
+curious disturbances which are termed spots. These appear to be
+uprushes of matter in the gaseous state, the upward movement being
+upon the margins of the field and a downward motion taking place in
+the middle of the irregular opening, which is darkened in its central
+part, thus giving it, when seen by an ordinary telescope, the aspect
+of a black patch on the glowing surface. These spots, which are from
+some <span class='pagenum'><a name="Page_75" id="Page_75">[Pg 75]</a></span>hundred to some thousand miles in diameter, may endure for
+months before they fade away. It is clear that they are most abundant
+at intervals of about eleven years, the last period of abundance being
+in 1893. The next to come may thus be expected in 1904. In the times
+of least spotting more than half the days of a year may pass without
+the surface of the photosphere being broken, while in periods of
+plenty no day in the year is likely to fail to show them.</p>
+
+<div class="figleft" style="width: 320px;">
+<img src="images/f6.jpg" width="320" height="289" alt="Fig. 6.&mdash;Ordinary Sun-spot, June 22, 1885." title="" />
+<span class="figcaption">Fig. 6.&mdash;Ordinary Sun-spot, June 22, 1885.</span>
+</div>
+
+<p>It is doubtful if the closest seeing would reveal the cause of the
+solar spots. The studies of the physicists who have devoted the most
+skill to the matter show little more than that they are tumults in the
+photosphere, attended by an uprush of vapours, in which iron and other
+metals exist; but whether these movements are due to outbreaks from
+the deeper parts of the sun or to some action like the whirling storms
+of the earth's atmosphere is uncertain. It is also uncertain what
+effect these convulsions of the sun have on the amount of the heat and
+light which is poured forth from the orb. The common opinion that the
+sun-spot years are the hottest is not yet fully verified.</p>
+
+<p>Below the photosphere lies the vast unknown mass of the unseen solar
+realm. It was at one time supposed that the dark colour of the spots
+was due to the fact that the photosphere was broken through in those
+spaces, and that we looked down through them upon the surface of the
+slightly illuminated central part of the sphere. This view is
+unten<span class='pagenum'><a name="Page_76" id="Page_76">[Pg 76]</a></span>able, and in its place we have to assume that for the eight
+hundred and sixty thousand miles of its diameter the sun is composed
+of matter such as is found in our earth, but throughout in a state of
+heat which vastly exceeds that known on or in our planet. Owing to its
+heat, this matter is possibly not in either the solid or the fluid
+state, but in that of very compressed gases, which are kept from
+becoming solid or even fluid by the very high temperature which exists
+in them. This view is apparently supported by the fact that, while the
+pressure upon its matter is twenty-seven times greater in the sun than
+it is in the earth, the weight of the whole mass is less than we
+should expect under these conditions.</p>
+
+<p>As for the temperature of the sun, we only know that it is hot enough
+to turn the metals into gases in the manner in which this is done in a
+strong electric arc, but no satisfactory method of reckoning the scale
+of this heat has been devised. The probabilities are to the effect
+that the heat is to be counted by the tens of thousands of degrees
+Fahrenheit, and it may amount to hundreds of thousands; it has,
+indeed, been reckoned as high as a million degrees. This vast
+discharge is not due to any kind of burning action&mdash;i.e., to the
+combustion of substances, as in a fire. It must be produced by the
+gradual falling in of the materials, due to the gravitation of the
+mass toward its centre, each particle converting its energy of
+position into heat, as does the meteorite when it comes into the air.</p>
+
+<p>It is well to close this very imperfect account of the learning which
+relates to the sun with a brief tabular statement showing the relative
+masses of the several bodies of the solar system. It should be
+understood that by mass is meant not the bulk of the object, but the
+actual amount of matter in it as determined by the gravitative
+attraction which it exercises on other celestial bodies. In this test
+the sun is taken as the measure, and its mass is for convenience
+reckoned at 1,000,000,000.</p>
+
+<p><span class='pagenum'><a name="Page_77" id="Page_77">[Pg 77]</a></span></p>
+
+<table summary="" style="border-width: thin; border-style: solid; padding: 10pt;">
+<tr><th colspan="2"  style="padding-bottom: 10pt;" class="smcap">Table of Relative Masses of Sun and Planets.
+<a name="FNanchor_2_2" id="FNanchor_2_2"></a><a href="#Footnote_2_2" class="fnanchor">[2]</a></th></tr>
+<tr><td>The sun</td><td class="ralign">1,000,000,000</td></tr>
+<tr><td>Mercury</td><td class="ralign">200</td></tr>
+<tr><td>Venus</td><td class="ralign">2,353</td></tr>
+<tr><td>Earth</td><td class="ralign">3,060</td></tr>
+<tr><td>Mars</td><td class="ralign">339</td></tr>
+<tr><td>Asteroids</td><td class="ralign">?</td></tr>
+<tr><td>Saturn</td><td class="ralign">285,580</td></tr>
+<tr><td>Jupiter</td><td class="ralign">954,305</td></tr>
+<tr><td>Uranus</td><td class="ralign">44,250</td></tr>
+<tr><td>Neptune</td><td class="ralign">51,600</td></tr>
+<tr><td><span style="margin-left: 1em;">Combined mass of the four inner planets</span></td><td class="ralign">5,952</td></tr>
+<tr><td><span style="margin-left: 1em;">Combined mass of all the planets</span></td><td class="ralign">1,341,687</td></tr>
+</table>
+
+<p>It thus appears that the mass of all the planets is about one seven
+hundredth that of the sun.</p>
+
+<p>Those who wish to make a close study of celestial geography will do
+well to procure the interesting set of diagrams prepared by the late
+James Freeman Clarke, in which transparencies placed in a convenient
+lantern show the grouping of the important stars in each
+constellation. The advantage of this arrangement is that the little
+maps can be consulted at night and in the open air in a very
+convenient manner. After the student has learned the position of a
+dozen of the constellations visible in the northern hemisphere, he can
+rapidly advance his knowledge in the admirable method invented by Dr.
+Clarke.</p>
+
+<p>Having learned the constellations, the student may well proceed to
+find the several planets, and to trace them in their apparent path
+across the fixed stars. It will be well for him here to gain if he can
+the conception that their apparent movement is compounded of their
+motion around the sun and that of our own sphere; that it would be
+very different if our earth stood still in the heavens. At this stage
+he may well begin to take in mind the evidence which the planetary
+motion supplies that the earth <span class='pagenum'><a name="Page_78" id="Page_78">[Pg 78]</a></span>really moves round the sun, and not
+the sun and planets round the earth. This discovery was one of the
+great feats of the human mind; it baffled the wits of the best men for
+thousands of years. Therefore the inquirer who works over the evidence
+is treading one of the famous paths by which his race climbed the
+steeps of science.</p>
+
+<p>The student must not expect to find the evidence that the sun is the
+centre of the solar system very easy to interpret; and yet any youth
+of moderate curiosity, and that interest in the world about him which
+is the foundation of scientific insight, can see through the matter.
+He will best begin his inquiries by getting a clear notion of the fact
+that the moon goes round the earth. This is the simplest case of
+movements of this nature which he can see in the solar system. Noting
+that the moon occupies a different place at a given hour in the
+twenty-four, but is evidently at all times at about the same distance
+from the earth, he readily perceives that it circles about our sphere.
+This the people knew of old, but they made of it an evidence that the
+sun also went around our sphere. Here, then, is the critical point.
+Why does the sun not behave in the same manner as the moon? At this
+stage of his inquiry the student best notes what takes place in the
+motions of the planets between the earth and the sun. He observes that
+those so-called inferior planets Mercury and Venus are never very far
+away from the central body; that they appear to rise up from it, and
+then to go back to it, and that they have phases like the moon. Now
+and then Venus may be observed as a black spot crossing the disk of
+the sun. A little consideration will show that on the theory that
+bodies revolve round each other in the solar system these movements of
+the inner planets can only be explained on the supposition that they
+at least travel around the great central fire. Now, taking up the
+outer planets, we observe that they occasionally appear very bright,
+and that they are then at a place in the heavens where we see that
+they are far from the solar centre. Gradually they move <span class='pagenum'><a name="Page_79" id="Page_79">[Pg 79]</a></span>down toward
+the sunset and disappear from view. Here, too, the movement, though
+less clearly so, is best reconcilable with the idea that these bodies
+travel in orbits, such as those which are traversed by the inner
+planets. The wonder is that with these simple facts before them, and
+with ample time to think the matter over, the early astronomers did
+not learn the great truth about the solar system&mdash;namely, that the sun
+is the centre about which the planets circled. Their difficulty lay
+mainly in the fact that they did not conceive the earth as a sphere,
+and even after they attained that conception they believed that our
+globe was vastly larger than the planets, or even than the sun. This
+misconception kept even the thoughtful Greeks, who knew that the earth
+was spherical in form, from a clear notion as to the structure of our
+system. It was not, indeed, until mathematical astronomy attained a
+considerable advance, and men began to measure the distances in the
+solar system, and until the Newtonian theory of gravitation was
+developed, that the planetary orbits and the relation of the various
+bodies in the solar system to each other could be perfectly discerned.</p>
+
+<p>Care has been taken in the above statements to give the student
+indices which may assist him in working out for himself the evidence
+which may properly lead a person, even without mathematical
+considerations of a formal kind, to construct a theory as to the
+relation of the planets to the sun. It is not likely that he can go
+through all the steps of this argument at once, but it will be most
+useful to him to ponder upon the problem, and gradually win his way to
+a full understanding of it. With that purpose in mind, he should avoid
+reading what astronomers have to say on the matter until he is
+satisfied that he has done as much as he can with the matter on his
+own account. He should, however, state his observations, and as far as
+possible draw the results in his note-book in a diagrammatic form. He
+should endeavour to see if the facts are reconcilable with any other
+supposition than that the earth and <span class='pagenum'><a name="Page_80" id="Page_80">[Pg 80]</a></span>the other planets move around the
+sun. When he has done his task, he will have passed over one of the
+most difficult roads which his predecessors had to traverse on their
+way to an understanding of the heavens. Even if he fail he will have
+helped himself to some large understandings.</p>
+
+<p>The student will find it useful to make a map of the heavens, or
+rather make several representing their condition at different times in
+the year. On this plot he should put down only the stars whose places
+and names he has learned, but he should plot the position of the
+planets at different times. In this way, though at first his efforts
+will be very awkward, he will soon come to know the general geography
+of the heavens.</p>
+
+<p>Although the possession or at least the use of a small astronomical
+telescope is a great advantage to a student after he has made a
+certain advance in his work, such an instrument is not at all
+necessary, or, indeed, desirable at the outset of his studies. An
+ordinary opera-glass, however, will help him in picking out the stars
+in the constellations, in identifying the planets, and in getting a
+better idea as to the form of the moon's surface&mdash;a matter which will
+be treated in this work in connection with the structure of the earth.</p>
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_81" id="Page_81">[Pg 81]</a></span></p>
+
+<h1><a name="CHAPTER_IV" id="CHAPTER_IV"></a>CHAPTER &nbsp; IV.<br/>
+<span class="subtitle smcap">the earth.</span></h1>
+
+
+<p>In beginning the study of the earth it is important that the student
+should at once form the habit of keeping in mind the spherical form of
+the planet. Many persons, while they may blindly accept the fact that
+the earth is a sphere, do not think of it as having that form. Perhaps
+the simplest way of securing the correct image of the shape is to
+imagine how the earth would appear as seen from the moon. In its full
+condition the moon is apt to appear as a disk. When it is new, and
+also when in its waning stages it is visible in the daytime, the
+spherical form is very apparent. Imagining himself on the surface of
+the moon, the student can well perceive how the earth would appear as
+a vast body in the heavens; its eight thousand miles of diameter,
+about four times that of the satellite, would give an area sixteen
+times the size which the moon presents to us. On this scale the
+continents and oceans would appear very much more plain than do the
+relatively slight irregularities on the lunar surface.</p>
+
+<p>With the terrestrial globe in hand, the student can readily construct
+an image which will represent, at least in outline, the appearance
+which the sphere he inhabits would present when seen from a distance
+of about a quarter of a million miles away. The continent of
+Europe-Asia would of itself appear larger than all the lunar surface
+which is visible to us. Every continent and all the greater islands
+would be clearly indicated. The snow covering which in <span class='pagenum'><a name="Page_82" id="Page_82">[Pg 82]</a></span>the winter of
+the northern hemisphere wraps so much of the land would be seen to
+come and go in the changes of the seasons; even the permanent ice
+about either pole, and the greater regions of glaciers, such as those
+of the Alps and the Himalayas, would appear as brilliant patches of
+white amid fields of darker hue. Even the changes in the aspect of the
+vegetation which at one season clothes the wide land with a green
+mantle, and at another assumes the dun hue of winter, would be, to the
+unaided eye, very distinct. It is probable that all the greater rivers
+would be traceable as lines of light across the relatively dark
+surface of the continents. By such exercises of the constructive
+imagination&mdash;indeed, in no other way&mdash;the student can acquire the
+habit of considering the earth as a vast whole. From time to time as
+he studies the earth from near by he should endeavour to assemble the
+phenomena in the general way which we have indicated.</p>
+
+<p>The reader has doubtless already learned that the earth is a slightly
+flattened sphere, having an average diameter of about eight thousand
+miles, the average section at the equator being about twenty-six miles
+greater than that from pole to pole. In a body of such large
+proportions this difference in measurement appears not important; it
+is, however, most significant, for it throws light upon the history of
+the earth's mass. Computation shows that the measure of flattening at
+the poles is just what would occur if the earth were or had been at
+the time when it assumed its present form in a fluid condition. We
+readily conceive that a soft body revolving in space, while all its
+particles by gravitation tended to the centre, would in turning
+around, as our earth does upon its axis, tend to bulge out in those
+parts which were remote from the line upon which the turning took
+place. Thus the flattening of our sphere at the poles corroborates the
+opinion that its mass was once molten&mdash;in a word, that its ancient
+history was such as the nebular theory suggests.</p>
+
+<p>Although we have for convenience termed the earth <span class='pagenum'><a name="Page_83" id="Page_83">[Pg 83]</a></span>a flattened
+spheroid, it is only such in a very general sense. It has an infinite
+number of minor irregularities which it is the province of the
+geographer to trace and that of the geologist to account for. In the
+first place, its surface is occupied by a great array of ridges and
+hollows. The larger of these, the oceans and continents, first deserve
+our attention. The difference in altitude of the earth's surface from
+the height of the continents to the deepest part of the sea is
+probably between ten and eleven miles, thus amounting to about two
+fifths of the polar flattening before noted. The average difference
+between the ocean floor and the summits of the neighbouring continents
+is probably rather less than four miles. It happens, most fortunately
+for the history of the earth, that the water upon its surface fills
+its great concavities on the average to about four fifths of their
+total depth, leaving only about one fifth of the relief projecting
+above the ocean level. We have termed this arrangement fortunate, for
+it insures that rainfall visits almost all the land areas, and thereby
+makes those realms fit for the uses of life. If the ocean had only
+half its existing area, the lands would be so wide that only their
+fringes would be fertile. If it were one fifth greater than it is, the
+dry areas would be reduced to a few scattered islands.</p>
+
+<p>From all points of view the most important feature of the earth's
+surface arises from its division into land and water areas, and this
+for the reason that the physical and vital work of our sphere is
+inevitably determined by this distribution. The shape of the seas and
+lands is fixed by the positions at which the upper level of the great
+water comes against the ridges which fret the earth's surface. These
+elevations are so disposed that about two thirds of the hard mass is
+at the present time covered with water, and only one third exposed to
+the atmosphere. This proportion is inconstant. Owing to the endless
+up-and-down goings of the earth's surface, the place of the shore
+lines varies from year to year, and in the geological ages great
+<span class='pagenum'><a name="Page_84" id="Page_84">[Pg 84]</a></span>revolutions in the forms and relative area of water and land are
+brought about.</p>
+
+<p>Noting the greater divisions of land and water as they are shown on a
+globe, we readily perceive that those parts of the continental ridges
+which rise above the sea level are mainly accumulated in the northern
+hemisphere&mdash;in fact, far more than half the dry realm is in that part
+of the world. We furthermore perceive that all the continents more or
+less distinctly point to the southward; they are, in a word,
+triangles, with their bases to the northward, and their apices,
+usually rather acute, directed to the southward. This form is very
+well indicated in three of the great lands, North and South America
+and Africa; it is more indistinctly shown in Asia and in Australia. As
+yet we do not clearly understand the reason why the continents are
+triangular, why they point toward the south pole, or why they are
+mainly accumulated in the northern hemisphere. As stated in the
+chapter on astronomy, some trace of the triangular form appears in the
+land masses of the planet Mars. There, too, these triangles appear to
+point toward one pole.</p>
+
+<p>Besides the greater lands, the seas are fretted by a host of smaller
+dry areas, termed islands. These, as inquiry has shown, are of two
+very diverse natures. Near the continents, practically never more than
+a thousand miles from their shores, we find isles, often of great
+size, such as Madagascar, which in their structure are essentially
+like the continents&mdash;that is, they are built in part or in whole of
+non-volcanic rocks, sandstones, limestones, etc. In most cases these
+islands, to which we may apply the term continental, have at some time
+been connected with the neighbouring mainland, and afterward separated
+from it by a depression of the surface which permitted the sea to flow
+over the lowlands. Geologists have traced many cases where in the past
+elevations which are now parts of a continent were once islands next
+its shore. In the deeper seas far removed from the margins of the
+continents the islands <span class='pagenum'><a name="Page_85" id="Page_85">[Pg 85]</a></span>are made up of volcanic ejections of lava,
+pumice, and dust, which has been thrown up from craters and fallen
+around their margin or are formed of coral and other organic remains.</p>
+
+<p>Next after this general statement as to the division of sea and land
+we should note the peculiarities which the earth's surface exhibits
+where it is bathed by the air, and where it is covered by the water.
+Beginning with the best-known region, that of the dry land, we observe
+that the surface is normally made up of continuous slopes of varying
+declivity, which lead down from the high points to the sea. Here and
+there, though rarely, these slopes centre in a basin which is occupied
+by a lake or a dead sea. On the deeper ocean floors, so far as we may
+judge with the defective information which the plumb line gives us,
+there is no such continuity in the downward sloping of the surface,
+the area being cast into numerous basins, each of great extent.</p>
+
+<p>When we examine in some detail the shape of the land surface, we
+readily perceive that the continuous down slopes are due to the
+cutting action of rivers. In the basin of a stream the waters act to
+wear away the original heights, filling them into the hollows, until
+the whole area has a continuous down grade to the point where the
+waters discharge into the ocean or perhaps into a lake. On the bottom
+of the sea, except near the margin of the continent, where the floor
+may in recent geological times have been elevated into the air, and
+thus exposed to river action, there is no such agent working to
+produce continuous down grades.</p>
+
+<p>Looking upon a map of a continent which shows the differences in
+altitude of the land, we readily perceive that the area is rather
+clearly divided into two kinds of surface, mountains and plains, each
+kind being sharply distinguished from the other by many important
+peculiarities. Mountains are characteristically made up of distinct,
+more or less parallel ridges and valleys, which are grouped in <span class='pagenum'><a name="Page_86" id="Page_86">[Pg 86]</a></span>very
+elongated belts, which, in the case of the American Cordilleras,
+extend from the Arctic to the Antarctic Circle. Only in rare instances
+do we find mountains occupying an area which is not very distinctly
+elongated, and in such cases the elevations are usually of no great
+height. Plains, on the other hand, commonly occupy the larger part of
+the continent, and are distributed around the flanks of the mountain
+systems. There is no rule as to their shape; they normally grade away
+from the bases of the mountains toward the sea, and are often
+prolonged below the level of the water for a considerable distance
+beyond the shore, forming what is commonly known as the continental
+shelf or belt of shallows along the coast line. We will now consider
+some details concerning the form and structure of mountains.</p>
+
+<p>In almost any mountain region a glance over the surface of the country
+will give the reader a clew to the principal factor which has
+determined the existence of these elevations. Wherever the bed rocks
+are revealed he will recognise the fact that they have been much
+disturbed. Almost everywhere the strata are turned at high angles;
+often their slopes are steeper than those of house roofs, and not
+infrequently they stand in attitudes where they appear vertical. Under
+the surface of plains bedded rocks generally retain the nearly
+horizontal position in which all such deposits are most likely to be
+found. If the observer will attentively study the details of position
+of these tilted rocks of mountainous districts, he will in most cases
+be able to perceive that the beds have been flexed or folded in the
+manner indicated by the diagram. Sometimes, though rarely, the tops of
+these foldings or arches have been preserved, so that the nature of
+the movement can be clearly discerned. More commonly the upper parts
+of the upward-arching strata have been cut off by the action of the
+decay-bringing forces&mdash;frost, flowing water, or creeping ice in
+glaciers&mdash;so that only the downward pointing folds which were formed
+in the mountain-making are well <span class='pagenum'><a name="Page_88" id="Page_88">[Pg 88]</a></span><span class='pagenum'><a name="Page_87" id="Page_87">[Pg 87]</a></span>preserved, and these are almost
+invariably hidden within the earth.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a href="images/f7-large.jpg">
+<img style="border-style: none;" src="images/f7.jpg" width="640" height="322" alt="Fig. 7.&mdash;Section of mountains. Rockbridge and Bath
+counties, Va. (from Dana). The numbers indicate the several formations." title="" />
+</a>
+<span class="figcaption">Fig. 7.&mdash;Section of mountains. Rockbridge and Bath
+counties, Va. (from Dana).<br/>The numbers indicate the several formations.<br/>
+(Transcriber's note: click on the image for a full-size version of the figure.)</span>
+</div>
+
+<p>By walking across any considerable mountain chain, as, for instance,
+that of the Alleghanies, it is generally possible to trace a number of
+these parallel up-and-down folds of the strata, so that we readily
+perceive that the original beds had been packed together into a much
+less space than they at first occupied. In some cases we could prove
+that the shortening of the line has amounted to a hundred miles or
+more&mdash;in other words, points on the plain lands on either side of the
+mountain range which now exists may have been brought a hundred miles
+or so nearer together than they were before the elevations were
+produced. The reader can make for himself a convenient diagram showing
+what occurred by pressing a number of leaves of this book so that the
+sheets of paper are thrown into ridges and furrows. By this experiment
+he also will see that the easiest way to account for such foldings as
+we observe in mountains is by the supposition that some force residing
+in the earth tends to shove the beds into a smaller space than they
+originally occupied. Not only are the rocks composing the mountains
+much folded, but they are often broken through after the manner of
+masonry which has been subjected to earthquake shocks, or of ice which
+has been strained by the expansion that affects it as it becomes
+warmed before it is melted. In fact, many of our small lakes in New
+England and in other countries of a long winter show in a miniature
+way during times of thawing ice folds which much resemble mountain
+arches.</p>
+
+<p>At first geologists were disposed to attribute all the phenomena of
+mountain-folding to the progressive cooling of the earth. Although
+this sphere has already lost a large part of the heat with which it
+was in the beginning endowed, it is still very hot in its deeper
+parts, as is shown by the phenomena of volcanoes. This internal heat,
+which to the present day at the depth of a hundred miles below the
+surface is probably greater than that of molten iron, <span class='pagenum'><a name="Page_89" id="Page_89">[Pg 89]</a></span>is constantly
+flowing away into space; probably enough of it goes away on the
+average each day to melt a hundred cubic miles or more of ice, or, in
+more scientific phrase, the amount of heat rendered latent by melting
+that volume of frozen water. J.R. Meyer, an eminent physicist,
+estimated the quantity of heat so escaping each day of the year to be
+sufficient to melt two hundred and forty cubic miles of ice. The
+effect of this loss of heat is constantly to shrink the volume of the
+earth; it has, indeed, been estimated that the sphere on this account
+contracts on the average to the amount of some inches each thousand
+years. For the reason that almost all this heat goes from the depths
+of the earth, the cool outer portion losing no considerable part of
+it, the contraction that is brought about affects the interior
+portions of the sphere alone. The inner mass constantly shrinking as
+it loses heat, the outer, cold part is by its weight forced to settle
+down, and can only accomplish this result by wrinkling. An analogous
+action may be seen where an apple or a potato becomes dried; in this
+case the hard outer rind is forced to wrinkle, because, losing no
+water, it does not diminish in its extent, and can only accommodate
+itself to the interior by a wrinkling process. In one case it is water
+which escapes, in the other heat; but in both contraction of the part
+which suffers the loss leads to the folding of the outside of the
+spheroid.</p>
+
+<p>Although this loss of heat on the part of the earth accounts in some
+measure for the development of mountains, it is not of itself
+sufficient to explain the phenomena, and this for the reason that
+mountains appear in no case to develop on the floors of the wide sea.
+The average depth of the ocean is only fifteen thousand feet, while
+there are hundreds, if not thousands, of mountain crests which exceed
+that height above the sea. Therefore if mountains grew on the sea
+floor as they do upon the land, there should be thousands of peaks
+rising above the plain of the waters, while, in fact, all of the
+islands except those near the shores <span class='pagenum'><a name="Page_90" id="Page_90">[Pg 90]</a></span>of continents are of volcanic
+origin&mdash;that is, are lands of totally different nature.</p>
+
+<p>Whenever a considerable mountain chain is formed, although the actual
+folding of the beds is limited to the usually narrow field occupied by
+these disturbances, the elevation takes place over a wide belt of
+country on one or both sides of the range. Thus if we approach the
+Rocky Mountains from the Mississippi Valley, we begin to mount up an
+inclined plane from the time we pass westward from the Mississippi
+River. The beds of rock as well as the surface rises gradually until
+at the foot of the mountain; though the rocks are still without
+foldings, they are at a height of four or five thousand feet above the
+sea. It seems probable&mdash;indeed, we may say almost certain&mdash;that when
+the crust is broken, as it is in mountain-building, by extensive folds
+and faults, the matter which lies a few score miles below the crust
+creeps in toward those fractures, and so lifts up the country on which
+they lie. When we examine the forms of any of our continents, we find
+that these elevated portions of the earth's crust appear to be made up
+of mountains and the table-lands which fringe those elevations. There
+is not, as some of our writers suppose, two different kinds of
+elevation in our great lands&mdash;the continents and the mountains which
+they bear&mdash;but one process of elevation by which the foldings and the
+massive uplifts which constitute the table-lands are simultaneously
+and by one process formed.</p>
+
+<p>Looking upon continents as the result of mountain growth, we may say
+that here and there on the earth's crust these dislocations have
+occurred in such association and of such magnitude that great areas
+have been uplifted above the plain of the sea. In general, we find
+these groups of elevations so arranged that they produce the
+triangular form which is characteristic of the great lands. It will be
+observed, for instance, that the form of North America is in general
+determined by the position of the Appalachian and Cordilleran systems
+on its eastern and western mar<span class='pagenum'><a name="Page_91" id="Page_91">[Pg 91]</a></span>gins, though there are a number of
+smaller chains, such as the Laurentians in Canada and the ice-covered
+mountains of Greenland, which have a measure of influence in fixing
+its shore lines.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a name="img04"></a>
+<img src="images/p4.jpg" width="640" height="377" alt="Waterfall near Gadsden, Alabama. The upper shelf of
+rock is a hard sandstone, the lower beds are soft shale. The
+conditions are those of most waterfalls, such as Niagara." title="" />
+<span class="caption">Waterfall near Gadsden, Alabama. The upper shelf of
+rock is a hard sandstone, the lower beds are soft shale. The
+conditions are those of most waterfalls, such as Niagara.</span>
+</div>
+
+<p>The history of plains, as well as that of mountains, will have further
+light thrown upon it when in the next chapter we come to consider the
+effect of rain water on the land. We may here note the fact that the
+level surfaces which are above the seashores are divisible into two
+main groups&mdash;those which have been recently lifted above the sea
+level, composed of materials laid down in the shallows next the shore,
+and which have not yet shared in mountain-building disturbances, and
+those which have been slightly tilted in the manner before indicated
+in the case of the plains which border the Rocky Mountains on the
+east. The great southern plain of eastern and southern United States,
+extending from near New York to Mexico, is a good specimen of the
+level lands common on all the continents which have recently emerged
+from the sea. The table-lands on either side of the Mississippi
+Valley, sloping from the Alleghanies and the Cordilleras, represent
+the more ancient type of plain which has already shared in the
+elevation which mountain-building brings about. In rarer cases plains
+of small area are formed where mountains formerly existed by the
+complete moving down of the original ridges.</p>
+
+<p>There is a common opinion that the continents are liable in the course
+of the geologic ages to very great changes of position; that what is
+now sea may give place to new great lands, and that those already
+existing may utterly disappear. This opinion was indeed generally held
+by geologists not more than thirty years ago. Further study of the
+problem has shown us that while parts of each continent may at any
+time be depressed beneath the sea, the whole of its surface rarely if
+ever goes below the water level. Thus, in the case of North America,
+we can readily note very great changes in its form since the land
+<span class='pagenum'><a name="Page_92" id="Page_92">[Pg 92]</a></span>began to rise above the water. But always, from that ancient day to
+our own, some portion of the area has been above the level of the sea,
+thus providing an ark of refuge for the land life when it was
+disturbed by inundations. The strongest evidence in favour of the
+opinion that the existing continents have endured for many million
+years is found in the fact that each of the great lands preserves many
+distinct groups of animals and plants which have descended from
+ancient forms dwelling upon the same territory. If at any time the
+relatively small continent of Australia had gone beneath the sea, all
+of the curious pouched animals akin to the opossum and kangaroo which
+abound in that country&mdash;creatures belonging in the ancient life of the
+world&mdash;would have been overwhelmed.</p>
+
+<p>We have already noted the fact that the uplifting of mountains and of
+the table-lands about them, which appears to have been the basis of
+continental growth, has been due to strains in the rocks sufficiently
+strong to disturb the beds. At each stage of the mountain-building
+movement these compressive strains have had to contend with the very
+great weight of the rocks which they had to move. These lands are not
+to be regarded as firm set or rigid arches, but as highly elastic
+structures, the shapes of which may be determined by any actions which
+put on or take off burden. We see a proof of this fact from numerous
+observations which geologists are now engaged in making. Thus during
+the last ice epoch, when almost all the northern part of this
+continent, as well as the northern part of Europe, was covered by an
+ice sheet several thousand feet thick, the lands sank down under their
+load, and to an extent roughly proportional to the depth of the icy
+covering. While the northern regions were thus tilted down by the
+weight which was upon them, the southern section of this land, the
+region about the Gulf of Mexico, was elevated much above its present
+level; it seems likely, indeed, that the peninsula of Florida rose to
+the height of several hundred feet above its present shore line. After
+<span class='pagenum'><a name="Page_93" id="Page_93">[Pg 93]</a></span>the ice passed away the movements were reversed, the northern region
+rising and the southern sinking down. These movements are attested by
+the position of the old shore lines formed during the later stages of
+the Glacial epoch. Thus around Lake Ontario, as well as the other
+Great Lakes, the beaches which mark the higher positions of those
+inland seas during the closing stages of the ice time, and which, of
+course, were when formed horizontal, now rise to the northward at the
+rate of from two to five feet for each mile of distance. Recent
+studies by Mr. G.K. Gilbert show that this movement is still in
+progress.</p>
+
+<p>Other evidence going to show the extent to which the movements of the
+earth's crust are affected by the weight of materials are found in the
+fact that wherever along the shores thick deposits of sediments are
+accumulated the tendency of the region where they lie is gradually to
+sink downward, so that strata having an aggregate thickness of ten
+thousand feet or more may be accumulated in a sea which was always
+shallow. The ocean floor, in general, is the part of the earth's
+surface where strata are constantly being laid down. In the great
+reservoir of the waters the <i>d&eacute;bris</i> washed from the land, the dust
+from volcanoes, and that from the stellar spaces, along with the vast
+accumulation of organic remains, almost everywhere lead to the
+steadfast accumulation of sedimentary deposits. On the other hand, the
+realms of the surface above the ocean level are constantly being worn
+away by the action of the rivers and glaciers, of the waves which beat
+against the shores, and of the winds which blow over desert regions.
+The result is that the lands are wearing down at the geologically
+rapid average rate of somewhere about one foot in five thousand years.
+All this heavy matter goes to the sea bottoms. Probably to this cause
+we owe in part the fact that in the wrinklings of the crust due to the
+contraction of the interior the lands exhibit a prevailing tendency to
+uprise, while the ocean floors sink down. In this way the continents
+are maintained above the level of the sea de<span class='pagenum'><a name="Page_94" id="Page_94">[Pg 94]</a></span>spite the powerful forces
+which are constantly wearing their substance away, while the seas
+remain deep, although they are continually being burdened with
+imported materials.</p>
+
+<div class="figcenter" style="width: 552px;">
+<img src="images/f8.jpg" width="552" height="480" alt="Fig. 8.&mdash;Diagram showing the effect of the position of
+the fulcrum point in the movement of the land masses. In diagrams I
+and II, the lines a b represent the land before the movement, and
+a&#39; b&#39; its position after the movement; s, s, the position of the
+shore line; p, p, the pivotal points; l, s, the sea line. In
+diagram III, the curved line designates a shore; the line a b,
+connecting the pivotal points p, p, is partly under the land and
+partly under the sea." title="" />
+<span class="figcaption">Fig. 8.&mdash;Diagram showing the effect of the position of
+the fulcrum point in the movement of the land masses. In diagrams I
+and II, the lines a b represent the land before the movement, and
+a&#39; b&#39; its position after the movement; s, s, the position of the
+shore line; p, p, the pivotal points; l, s, the sea line. In
+diagram III, the curved line designates a shore; the line a b,
+connecting the pivotal points p, p, is partly under the land and
+partly under the sea.</span>
+</div>
+
+<p>It is easy to see that if the sea floors tend to sink downward, while
+the continental lands uprise, the movements which take place may be
+compared with those which occur in a lever about a fulcrum point. In
+this case the sea end <span class='pagenum'><a name="Page_95" id="Page_95">[Pg 95]</a></span>of the bar is descending and the land end
+ascending. Now, it is evident that the fulcrum point may fall to the
+seaward or to the landward of the shore; only by chance and here and
+there would it lie exactly at the coast line. By reference to the
+diagram (Fig. 8), it will be seen that, while the point of rotation is
+just at the shore, a considerable movement may take place without
+altering the position of the coast line. Where the point of no
+movement is inland of the coast, the sea will gain on the continent;
+where, however, the point is to seaward, beneath the water, the land
+will gain on the ocean. In this way we can, in part at least, account
+for the endless changes in the attitude of the land along the coastal
+belt without having to suppose that the continents cease to rise or
+the sea floors to sink downward. It is evident that the bar or section
+of the rocks from the interior of the land to the bottoms of the seas
+is not rigid; it is also probable that the matter in the depths of the
+earth, which moves with the motions of this bar, would change the
+position of the fulcrum point from time to time. Thus it may well come
+about that our coast lines are swaying up and down in ceaseless
+variation.</p>
+
+<p>In very recent geological times, probably since the beginning of the
+last Glacial period, the region about the Dismal Swamp in Virginia has
+swayed up and down through four alternating movements to the extent of
+from fifty to one hundred feet. The coast of New Jersey is now sinking
+at the rate of about two feet in a hundred years. The coast of New
+England, though recently elevated to the extent of a hundred feet or
+more, at a yet later time sank down, so that at some score of points
+between New York and Eastport, Me., we find the remains of forests
+with the roots of their trees still standing below high-tide mark in
+positions where the trees could not have grown. Along all the marine
+coasts of the world which have been carefully studied from this point
+of view there are similar evidences of slight or great modern changes
+in the level of the lands. At some points, particularly <span class='pagenum'><a name="Page_96" id="Page_96">[Pg 96]</a></span>on the coast
+of Alaska and along the coast of Peru, these uplifts of the land have
+amounted to a thousand feet or more. In the peninsular district of
+Scandinavia the swayings, sometimes up and sometimes down, which are
+now going on have considerably changed the position of the shore lines
+since the beginning of the historical period.</p>
+
+<p>There are other causes which serve to modify the shapes and sizes of
+the continents which may best be considered in the sequel; for the
+present we may pass from this subject with the statement that our
+great lands are relatively permanent features; their forms change from
+age to age, but they have remained for millions of years habitable to
+the hosts of animals and plants which have adapted their life to the
+conditions which these fields afford them.</p>
+
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_97" id="Page_97">[Pg 97]</a></span></p>
+<h1><a name="CHAPTER_V" id="CHAPTER_V"></a>CHAPTER &nbsp; V.<br/>
+<span class="subtitle smcap">the atmosphere.</span></h1>
+
+
+<p>The firm-set portion of the earth, composed of materials which became
+solid when the heat so far disappeared from the sphere that rocky
+matter could pass from its previous fluid condition to the solid or
+frozen state, is wrapped about by two great envelopes, the atmosphere
+and the waters. Of these we shall first consider the lighter and more
+universal air; in taking account of its peculiarities we shall have to
+make some mention of the water with which it is greatly involved;
+afterward we shall consider the structure and functions of that fluid.</p>
+
+<p>Atmospheric envelopes appear to be common features about the celestial
+spheres. In the sun there is, as we have noted, a very deep envelope
+of this sort which is in part composed of the elements which form our
+own air; but, owing to the high temperature of the sphere, these are
+commingled with many substances which in our earth&mdash;at least in its
+outer parts&mdash;have entered in the solid state. Some of the planets, so
+far as we can discern their conditions, seem also to have gaseous
+wraps; this is certainly the case with the planet Mars, and even the
+little we know of the other like spheres justifies the supposition
+that Jupiter and Saturn, at least, have a like constitution. We may
+regard an atmosphere, in a word, as representing a normal and
+long-continued state in the development of the heavenly orbs. In only
+one of these considerable bodies of the solar system, the moon, do we
+find tolerably clear evidence that there is no atmosphere.</p>
+
+<p><span class='pagenum'><a name="Page_98" id="Page_98">[Pg 98]</a></span></p><p>The atmosphere of the earth is composed mainly of very volatile
+elements, known as nitrogen and argon. This is commingled with oxygen,
+also a volatile element. Into this mass a number of other substances
+enter in varying but always relatively very small proportions. Of
+these the most considerable are watery vapour and carbon dioxide; the
+former of these rarely amounts to one per cent of the weight of the
+air, considering the atmosphere as a whole, and the latter is never
+more than a small fraction of one per cent in amount. As a whole, the
+air envelope of the earth should be regarded as a mass of nitrogen and
+argon, which only rarely, under the influence of conditions which
+exist in the soil, enters into combinations with other elements by
+which it assumes a solid form. The oxygen, though a permanent element
+in the atmosphere, tends constantly to enter into combinations which
+fix it temporarily or permanently in the earth, in which it forms,
+indeed, in its combined state about one half the weight of all the
+mineral substances we know. The carbon dioxide, or carbonic-acid gas,
+as it is commonly termed, is a most important substance, as it affords
+plants all that part of their bodies which disappear on burning. It is
+constantly returned to the atmosphere by the decay of organic matter,
+as well as by volcanic action.</p>
+
+<p>In addition to the above-noted materials composing the air, all of
+which are imperatively necessary to the wonderful work accomplished by
+that envelope, we find a host of other substances which are
+accidentally, variably, and always in small quantities contained in
+this realm. Thus near the seashores, and indeed for a considerable
+distance into the continent, we find the air contains a certain amount
+of salt so finely divided that it floats in the atmosphere. So, too,
+we find the air, even on the mountain tops amid eternal snows, charged
+with small particles of dust, which, though not evident to the
+unassisted eye, become at once visible when we permit a slender ray of
+light to enter a dark chamber.</p>
+
+<p><span class='pagenum'><a name="Page_99" id="Page_99">[Pg 99]</a></span></p><p>It is commonly asserted that the atmosphere does not effectively
+extend above the height of forty-five miles; we know that it is
+densest on the surface of the earth, the most so in those depressions
+which lie below the level of the sea. This is proved to us by the
+weight which the air imposes upon the mercury at the open end of a
+barometric tube. If we could deepen these cavities to the extent of a
+thousand miles, the pressure would become so great that if the pit
+were kept free from the heat of the earth the gaseous materials would
+become liquefied. Upward from the earth's surface at the sea level the
+atoms and molecules of the air become farther apart until, at the
+height of somewhere between forty and fifty miles, the quantity of
+them contained in the ether is so small that we can trace little
+effect from them on the rays of light which at lower levels are
+somewhat bent by their action. At yet higher levels, however, meteors
+appear to inflame by friction against the particles of air, and even
+at the height of eighty miles very faint clouds have at times been
+discerned, which are possibly composed of volcanic dust floating in
+the very rarefied medium, such as must exist at this great elevation.</p>
+
+<p>The air not only exists in the region where we distinctly recognise
+it; it also occupies the waters and the under earth. In the waters it
+occurs as a mechanical mixture which is brought about as the rain
+forms and falls in the air, as the streams flow to the sea, and as the
+waves roll over the deep and beat against the shores. In the realm of
+the waters, as well as on the land, the air is necessary for the
+maintenance of all animal forms; but for its presence such life would
+vanish from the earth.</p>
+
+<p>Owing to certain peculiarities in its constitution, the atmosphere of
+our earth, and that doubtless of myriad other spheres, serves as a
+medium of communication between different regions. It is, as we know,
+in ceaseless motion at rates which may vary from the speed in the
+greatest tempests, which may move at the rate of some<span class='pagenum'><a name="Page_100" id="Page_100">[Pg 100]</a></span>where a hundred
+and fifty miles an hour, to the very slow movements which occur in
+caverns, where the transfer is sometimes effected at an almost
+microscopic rate in the space of a day. The motion of the atmosphere
+is brought about by the action of heat here and there, and in a
+trifling way, by the heat from the interior of the earth escaping
+through hot springs or volcanoes, but almost altogether by the heat of
+the sun. If we can imagine the earth cut off from the solar radiation,
+the air would cease to move. We often note how the variable winds fall
+away in the nighttime. Those who in seeking for the North Pole have
+spent winters in the long-continued dark of that region have noted
+that the winds almost cease to blow, the air being disturbed only when
+a storm originated in the sunlit realm forced its way into the
+circumpolar darkness.</p>
+
+<p>The sun's heat does not directly disturb the atmosphere; if we could
+take the solid sphere of the world away, leaving the air, the rays
+would go straight through, and there would be no winds produced. This
+is due to the fact that the air permits the direct rays of heat, such
+as come from the sun, to pass through it with very slight resistance.
+In an a&euml;rial globe such as we have imagined, the rays impinging upon
+its surface would be slightly thrown out of their path as they are in
+passing through a lens, but they would journey on in space without in
+any considerable measure warming the mass. Coming, however, upon the
+solid earth, the heat rays warm the materials on which they are
+arrested, bringing them to a higher temperature than the air. Then
+these heated materials radiate the energy into the air; it happens,
+however, that this radiant heat can not journey back into space as
+easily as it came in; therefore the particles of air next the surface
+acquire a relatively high temperature. Thus a thermometer next the
+ground may rise to over a hundred degrees Fahrenheit, while at the
+same time the fleecy clouds which we may observe floating at the
+height of five or six miles above the surface are composed of frozen
+water.</p>
+
+<p><span class='pagenum'><a name="Page_101" id="Page_101">[Pg 101]</a></span></p><p>The effect of the heated air which acquires its temperature by
+radiation from the earth's surface is to produce the winds. This it
+brings about in a very simple manner, though the details of the
+process have a certain complication. The best illustration of the mode
+in which the winds are produced is obtained by watching what takes
+place about an ordinary fire at the bottom of a chimney. As soon as
+the fire is lit, we observe that the air about it, so far as it is
+heated, tends upward, drawing the smoke with it. If the air in the
+chimney be cold, it may not draw well at first; but in a few minutes
+the draught is established, or, in other words, the heated lower air
+breaks its way up the shaft, gradually pushing the cooler matter out
+at the top. In still air we may observe the column from the flue
+extending about the chimney-top, sometimes to the height of a hundred
+feet or more before it is broken to pieces. It is well here to note
+the fact that the energy of the draught in a chimney is, with a given
+heat of fire and amount of air which is permitted to enter the shaft,
+directly proportionate to the height; thus in very tall flues, between
+two and three hundred feet high, which are sometimes constructed, the
+uprush is at the speed of a gale.</p>
+
+<p>Whenever the air next the surface is so far heated that it may
+overcome the inertia of the cooler air above, it forces its way up
+through it in the general manner indicated in the chimney flue. When
+such a place of uprush is established, the hot air next the surface
+flows in all directions toward the shaft, joining the expedition to
+the heights of the atmosphere. Owing to the conditions of the earth's
+surface, which we shall now proceed to trace, these ascents of heated
+air belong in two distinct classes&mdash;those which move upward through
+more or less cylindrical chimneys in the atmosphere, shafts which are
+impermanent, which vary in diameter from a few feet to fifty or
+perhaps a hundred miles, and which move over the surface of the earth;
+and another which consists of a broad, beltlike shaft in the
+equatorial regions, which in a way girdles the earth, <span class='pagenum'><a name="Page_102" id="Page_102">[Pg 102]</a></span>remains in
+about the same place, continually endures, and has a width of hundreds
+of miles. Of these two classes of uprushes we shall first consider the
+greatest, which occurs in the central portions of the tropical realm.</p>
+
+<p>Under the equator, owing to the fact that the sun for a considerable
+belt of land and sea maintains the earth at a high temperature, there
+is a general updraught which began many million years ago, probably
+before the origin of life, in the age when our atmosphere assumed its
+present conditions. Into this region the cooler air from the north and
+south necessarily flows, in part pressed in by the weight of the cold
+air which overlies it, but aided in its motion by the fact that the
+particles which ascend leave place for others to occupy. Over the
+surfaces of the land within the tropical region this draught toward
+what we may term the equatorial chimney is perturbed by the
+irregularities of the surface and many local accidents. But on the
+sea, where the conditions are uniform, the air moving toward the point
+of ascent is marked in the trade winds, which blow with a steadfast
+sweep down toward the equator. Many slight actions, such as the
+movement of the hot and cold currents of the sea, the local air
+movements from the lands or from detached islands, somewhat perturb
+the trade winds, but they remain among the most permanent features in
+this changeable world. It is doubtful if anything on this sphere
+except the atoms and molecules of matter have varied as little as the
+trade winds in the centre of the wide ocean. So steadfast and uniform
+are they that it is said that the helm and sails of a ship may be set
+near the west coast of South America and be left unchanged for a
+voyage which will carry the navigator in their belt across the width
+of the Pacific.</p>
+
+<p>Rising up from the earth in the tropical belt, the air attains the
+height of several thousand feet; it then begins to curve off toward
+the north and south, and at the height of somewhere about three to
+five miles above the surface <span class='pagenum'><a name="Page_103" id="Page_103">[Pg 103]</a></span>is again moving horizontally toward
+either pole; attaining a distance on that journey, it gradually
+settles down to the surface of the earth, and ceases to move toward
+higher latitudes. If the earth did not revolve upon its axis the
+course of these winds along the surface toward the equator, and in the
+upper air back toward the poles, would be made in what we may call a
+square manner&mdash;that is, the particles of air would move toward the
+point where they begin to rise upward in due north and south lines,
+according as they came from the southern or northern hemisphere, and
+the upper currents or counter trades would retrace their paths also
+parallel with the meridians or longitude lines. But because the earth
+revolves from west to east, the course of the trade winds is oblique
+to the equator, those in the northern hemisphere blowing from
+northeast to southwest, those in the southern from southeast to
+northwest. The way in which the motion of the earth affects the
+direction of these currents is not difficult to understand. It is as
+follows:</p>
+
+<p>Let us conceive a particle of air situated immediately over the
+earth's polar axis. Such an atom would by the rotation of the sphere
+accomplish no motion except, indeed, that it might turn round on its
+own centre. It would acquire no velocity whatever by virtue of the
+earth's movement. Then let us imagine the particle moving toward the
+equator with the speed of an ordinary wind. At every step of its
+journey toward lower latitudes it would come into regions having a
+greater movement than those which it had just left. Owing to its
+inertia, it would thus tend continually to lag behind the particles of
+matter about it. It would thus fall off to the westward, and, in place
+of moving due south, would in the northern hemisphere drift to the
+southwest, and in the southern hemisphere toward the northwest. A good
+illustration of this action may be obtained from an ordinary
+turn-table such as is used about railway stations to reverse the
+position of a locomotive. If the observer will stand in the centre <span class='pagenum'><a name="Page_104" id="Page_104">[Pg 104]</a></span>of
+such a table while it is being turned round he will perceive that his
+body is not swayed to the right or left. If he will then try to walk
+toward the periphery of the rotating disk, he will readily note that
+it is very difficult, if not impossible, to walk along the radius of
+the circle; he naturally falls behind in the movement, so that his
+path is a curved line exactly such as is followed by the winds which
+move toward the equator in the trades. If now he rests a moment on the
+periphery of the table, so that his body acquires the velocity of the
+disk at that point, and then endeavours to walk toward the centre, he
+will find that again he can not go directly; his path deviates in the
+opposite direction&mdash;in other words, the body continually going to a
+place having a less rate of movement by virtue of the rotation of the
+earth, on account of its momentum is ever moving faster than the
+surface over which it passes. This experiment can readily be tried on
+any small rotating disk, such as a potter's wheel, or by rolling a
+marble or a shot from the centre to the circumference and from the
+circumference to the centre. A little reflection will show the
+inquirer how these illustrations clearly account for the oblique
+though opposite sets of the trade winds in the upper and lower parts
+of the air.</p>
+
+<p>The dominating effect of the tropical heat in controlling the
+movements of the air currents extends, on the ocean surface, in
+general about as far north and south as the parallels of forty
+degrees, considerably exceeding the limits of the tropics, those lines
+where the sun, because of the inclination of the earth's axis, at some
+time of the year comes just overhead. Between these belts of trade
+winds there is a strip or belt under the region where the atmosphere
+is rising from the earth, in which the winds are irregular and have
+little energy. This region of the "doldrums" or frequent calms is one
+of much trouble to sailing ships on their voyages from one hemisphere
+to another. In passing through it their sails are filled only by the
+airs of local storms, or winds which make their way <span class='pagenum'><a name="Page_105" id="Page_105">[Pg 105]</a></span>into that part of
+the sea from the neighbouring continents. Beyond the trade-wind belt,
+toward the poles, the movements of the atmosphere are dependent in
+part on the counter trades which descend to the surface of the earth
+in latitudes higher than that in which the surface or trade winds
+flow. Thus along our Atlantic coast, and even in the body of the
+continent, at times when the air is not controlled by some local
+storm, the counter trade blows with considerable regularity.</p>
+
+<p>The effect of the trade and counter-trade movements of the air on the
+distribution of temperature over the earth's surface is momentous. In
+part their influence is due to the direct heat-carrying power of the
+atmosphere; in larger measure it is brought about by the movement of
+the ocean waters which they induce. Atmospheric air, when deprived of
+the water which it ordinarily contains, has very little
+heat-containing capacity. Practically nearly all the power of
+conveying heat which it possesses is due to the vapour of water which
+it contains. By virtue of this moisture the winds do a good deal to
+transfer heat from the tropical or superheated portion of the earth's
+surface to the circumpolar or underheated realms. At first, the
+relatively cool air which journeys toward the equator along the
+surface of the sea constantly gains in heat, and in that process takes
+up more and more water, for precisely the same reason that causes
+anything to dry more rapidly in air which has been warmed next a fire.
+The result is that before it begins to ascend in the tropical
+updraught, being much moisture-laden, the atmosphere stores a good
+deal of heat. As it rises, rarefies, and cools, the moisture descends
+in the torrential rains which ordinarily fall when the sun is nearly
+vertical in the tropical belt.</p>
+
+<p>Here comes in a very interesting principle which is of importance in
+understanding the nature of great storms, either the continuous storm
+of the tropics or the local and irregular whirlings which occur in
+various parts of the <span class='pagenum'><a name="Page_106" id="Page_106">[Pg 106]</a></span>earth. When the moisture-laden air starts on its
+upward journey from the earth it has, by virtue of the watery vapour
+which it contains, a store of energy which becomes applied to
+promoting the updraught. As it rises, the moisture in the air gathers
+together or condenses, and in so doing parts with the heat which
+caused it to evaporate from the ocean surface. For a given weight of
+water, the amount of heat required to effect the evaporation is very
+great; this we may roughly judge by observing what a continuous fire
+is required to send a pint of water into the state of steam. This
+energy, when it is released by the condensation of water into rain or
+snow, becomes again heat, and tends somewhat, as does the fire in the
+chimney, to accelerate the upward passage of the air. The result is
+that the water which ascends in the equatorial updraught becomes what
+we may term fuel to promote this important element in the earth's
+a&euml;rial circulation. Trades and counter trades would doubtless exist
+but for the efficiency of this updraught, which is caused by the
+condensation of watery vapour, but the movement would be much less
+than it is.</p>
+
+
+<h2 class="subtitle smcap">Whirling Storms.</h2>
+
+<p>In the region near the equator, or near the line of highest
+temperature, which for various reasons does not exactly follow the
+equator, there is, as we have noticed, a somewhat continuous uprushing
+current where the air passes upward through an ascending chimney,
+which in a way girdles the sea-covered part of the earth. In this
+region the movements of the air are to a great extent under the
+control of the great continuous updraught. As we go to the north and
+south we enter realms where the air at the surface of the earth is, by
+the heat which it acquires from contact with that surface, more or
+less impelled upward; but there being no permanent updraught for its
+escape, it from time to time breaks through the roof of cold air which
+overlies it and makes a temporary channel of passage.<span class='pagenum'><a name="Page_107" id="Page_107">[Pg 107]</a></span> Going polarward
+from the equator, we first encounter these local and temporary
+upcastings of the air near the margin of the tropical belt. In these
+districts, at least over the warmer seas, during the time of the year
+when it is midsummer, and in the regions where the trade winds are not
+strong enough to sweep the warm and moisture-laden air down to the
+equatorial belt, the upward tending strain of the atmosphere next the
+earth often becomes so strong that the overlying air is displaced,
+forming a channel through which the air swiftly passes. As the
+moisture condenses in the way before noted, the energy set free serves
+to accelerate the updraught, and a hurricane is begun. At first the
+movement is small and of no great speed, but as the amount of air
+tending upward is likely to be great, as is also the amount of
+moisture which it contains, the a&euml;rial chimney is rapidly enlarged,
+and the speed of the rising air increased. The atmosphere next the
+surface of the sea flows in toward the channel of escape; its passage
+is marked by winds which are blowing toward the centre. On the
+periphery of the movement the particles move slowly, but as they win
+their way toward the centre they travel with accelerating velocity. On
+the principle which determines the whirling movement of the water
+escaping through a hole in the bottom of a basin, the particles of the
+air do not move on straight lines toward the centre, but journey in
+spiral paths, at first along the surface, and then ascending.</p>
+
+<p>We have noted the fact that in a basin of water the direction of the
+whirling is what we may term accidental&mdash;that is, dependent on
+conditions so slight that they elude our observation&mdash;but in
+hurricanes a certain fact determines in an arbitrary way the direction
+in which the spin shall take place. As soon as such a movement of the
+air attains any considerable diameter, although in its beginning it
+may have spun in a direction brought about by local accidents, it will
+be affected by the diverse rates of travel, by virtue of the earth's
+rotation, of the air on its <span class='pagenum'><a name="Page_108" id="Page_108">[Pg 108]</a></span>equatorial and polar sides. On the
+equatorial side this air is moving more rapidly than it is on the
+polar side. By observing the water passing from a basin this
+principle, with a few experiments, can be made plain. The result is to
+cause these great whirlwinds of the hurricanes of higher latitudes to
+whirl round from right to left in the northern hemisphere and in the
+reverse way in the southern. The general system of the air currents
+still further affects these, as other whirling storms, by driving
+their centres or chimneys over the surface of the earth. The principle
+on which this is done may be readily understood by observing how the
+air shaft above a chimney, through which we may observe the smoke to
+rise during a time of calm, is drawn off to one side by the slight
+current which exists even when we feel no wind; it may also be
+discerned in the little dust whirls which form in the streets on a
+summer day when the air is not much disturbed. While they spin they
+move on in the direction of the air drift. In this way a hurricane
+originating in the Gulf of Mexico may gradually journey under the
+influence of the counter trades across the Antilles, or over southern
+Florida, and thence pursue a devious northerly course, generally near
+the Atlantic coast and in the path of the Gulf Stream, until it has
+travelled a thousand miles or more toward the North Atlantic. The
+farther it goes northward the less effectively it is fed with warm and
+moisture-laden air, the feebler its movement becomes, until at length
+it is broken up by the variable winds which it encounters.</p>
+
+<p>A very interesting and, from the point of view of the navigator,
+important peculiarity of these whirls is that at their centre there is
+a calm, similar in origin and nature to the calm under the equator
+between the trade-wind belts. Both these areas are in the field where
+the air is ascending, and therefore at the surface of the earth does
+not affect the sails of ships, though if men ever come to use flying
+machines and sail through the tropics at a good height above the sea
+it will be sensible enough. The dif<span class='pagenum'><a name="Page_109" id="Page_109">[Pg 109]</a></span>ference between the doldrum of the
+equator and that of the hurricane, besides their relative areas, is
+that one is a belt and the other a disk. If the seafarer happens to
+sail on a path which leads him through the hurricane centre, he will
+first discern, as from the untroubled air and sea he approaches the
+periphery of the storm, the horizon toward the disturbance beset by
+troubled clouds, all moving in one direction. Entering beneath this
+pall, he finds a steadily increasing wind, which in twenty miles of
+sailing may, and in a hundred miles surely will, compel him to take in
+all but his storm sails, and is likely to bring his ship into grave
+peril. The most furious winds the mariner knows are those which he
+encounters as he approaches the still centre. These trials are made
+the more appalling by the fact that in the furious part of the whirl
+the rain, condensing from the ascending air, falls in torrents, and
+the electricity generated in the condensation gives rise to vivid
+lightning. If the storm-beset ship can maintain her way, in a score or
+two of miles of journey toward the centre, generally very quickly, it
+passes into the calm disk, where the winds, blowing upward, cease to
+be felt. In this area the ship is not out of danger, for the waves,
+rolling in from the disturbed areas on either side, make a torment of
+cross seas, where it is hard to control the movements of a sailing
+vessel because the impulse of the winds is lost. Passing through this
+disk of calm, the ship re-encounters in reverse order the furious
+portion of the whirl, afterward the lessening winds, until it escapes
+again into the airs which are not involved in the great torment.</p>
+
+<p>In the old days, before Dove's studies of storms had shown the laws of
+hurricane movement, unhappy shipmasters were likely to be caught and
+retained in hurricanes, and to battle with them for weeks until their
+vessels were beaten to pieces. Now the "Sailing Directions," which are
+the mariner's guide, enable him, from the direction of the winds and
+the known laws of motion of the storm centre, to sail out of the
+danger, so that in most <span class='pagenum'><a name="Page_110" id="Page_110">[Pg 110]</a></span>cases he may escape calamity. It is otherwise
+with the people who dwell upon the land over which these atmospheric
+convulsions sweep. Fortunately, where these great whirlwinds trespass
+on the continent, they quickly die out, because of the relative lack
+of moisture which serves to stimulate the uprush which creates them.
+Thus in their more violent forms hurricanes are only felt near the
+sea, and generally on islands and peninsulas. There the hurricane
+winds, by the swiftness of their movement, which often attains a speed
+of a hundred miles or more, apply a great deal of energy to all
+obstacles in their path. The pressure thus produced is only less
+destructive than that which is brought about by the tornadoes, which
+are next to be described.</p>
+
+<p>There is another effect from hurricanes which is even more destructive
+to life than that caused by the direct action of the wind. In these
+whirlings great differences in atmospheric pressure are brought about
+in contiguous areas of sea. The result is a sudden elevation in the
+level of one part of the water. These disturbances, where the shore
+lands are low and thickly peopled, as is the case along the western
+coast of the Bay of Bengal, may produce inundations which are terribly
+destructive to life and property. They are known also in southern
+Florida and along the islands of the Caribbean, but in that region are
+not so often damaging to mankind.</p>
+
+<p>Fortunately, hurricanes are limited to a very small part of the
+tropical district. They occur only in those regions, on the eastern
+faces of tropical lands, where the general westerly set of the winds
+favours the accumulation of great bodies of very warm, moist air next
+the surface of the sea. The western portion of the Gulf of Mexico and
+the Caribbean, the Bay of Bengal, and the southeastern portion of Asia
+are especially liable to their visitations. They sometimes develop,
+though with less fury, in other parts of the tropics. On the western
+coast of South America and Africa, where the oceans are visited by the
+dry land <span class='pagenum'><a name="Page_111" id="Page_111">[Pg 111]</a></span>winds, and where the waters are cooled by currents setting
+in from high latitudes, they are unknown.</p>
+
+<p>Only less in order of magnitude than the hurricanes are the circular
+storms known as cyclones. These occur on the continents, especially
+where they afford broad plains little interrupted by mountain ranges.
+They are particularly well exhibited in that part of North America
+north of Mexico and south of Hudson Bay. Like the hurricanes, they
+appear to be due to the inrush of relatively warm air entering an
+updraught which had been formed in the overlying, cooler portions of
+the atmosphere. They are, however, much less energetic, and often of
+greater size than the hurricane whirl. The lack of energy is probably
+due to the comparative dryness of the air. The greater width of the
+ascending column may perhaps be accounted for by the fact that,
+originating at a considerable height above the sea, they have a less
+thickness of air to break through, and so the upward setting column is
+readily made broad.</p>
+
+<p>The cyclones of North America appear generally to originate in the
+region of the Rocky Mountains, though it is probable that in some
+instances, perhaps in many, the upward set of the air which begins the
+storm originates in the ocean along the Pacific coast. They gather
+energy as they descend the great sloping plain leading eastward from
+the Rocky Mountains to the central portion of the great continental
+valley. Thence they move on across the country to the Atlantic coast.
+Not infrequently they continue on over the ocean to the European
+continent. The eastward passage of the storm centre is due to the
+prevailing eastward movement of the air in its upper part throughout
+that portion of the northern hemisphere. Commonly they incline
+somewhat to the northward of east in their journey. In all cases the
+winds appear to blow spirally into the common storm centre. There is
+the same doldrum area or calm field in the centre of the storm that we
+note between the trade winds and in the middle of a <span class='pagenum'><a name="Page_112" id="Page_112">[Pg 112]</a></span>hurricane disk,
+though this area is less defined than in the other instances, and the
+forward motion of the storm at a considerable speed is in most cases
+characteristic of the disturbance. On the front of one of these storms
+in North America the winds commonly begin in the northeast, thence
+they veer by the east to the southwest. At this stage in the movement
+the storm centre has passed by, the rainfall commonly ceases, and
+cold, dry winds setting to the northwestward set in. This is caused by
+the fact that the ascending air, having attained a height above the
+earth, settles down behind the storm, forming an anticyclone or mass
+of dry air, which presses against the retreating side of the great
+whirlwind.</p>
+
+<p>In front of the storm the warm and generally moist relatively warm
+air, pressing in toward the point of uprise and overlaid by the upper
+cold air, is brought into a condition where it tends to form small
+subordinate shafts up through which it whirls on the same principle,
+but with far greater intensity than the main ascending column. The
+reason for the violence of this movement is that the difference in
+temperature of the air next the surface and that at the height of a
+few thousand feet is great. As might be expected, these local
+spinnings are most apt to occur in the season when the air next the
+earth is relatively warm, and they are aptest to take place in the
+half of the advancing front lying between the east and south, for the
+reason that there the highest temperatures and the greatest humidity
+are likely to coexist. In that part of the field, during the time when
+the storm is advancing from the Rocky Mountains to the Atlantic, a
+dozen or more of these spinning uprushes may be produced, though few
+of them are likely to be of large size or of great intensity.</p>
+
+<p>The secondary storms of cyclones, such as are above noted, receive the
+name of tornadoes. They are frequent and terrible visitations of the
+country from northern Texas, Florida, and Alabama to about the line of
+the Great Lakes; they are rarely developed in the region west <span class='pagenum'><a name="Page_113" id="Page_113">[Pg 113]</a></span>of
+central Kansas, and only occasionally do they exhibit much energy in
+the region east of the plain-lands of the Ohio Valley. Although known
+in other lands, they nowhere, so far as our observations go, exhibit
+the paroxysmal intensity which they show in the central portion of the
+North American continent. There the air which they affect acquires a
+speed of movement and a fury of action unknown in any other
+atmospheric disturbances, even in those of the hurricanes.</p>
+
+<p>The observer who has a chance to note from an advantageous position
+the development of a tornado observes that in a tolerably still air,
+or at least an air unaffected by violent winds&mdash;generally in what is
+termed a "sultry" state of the atmosphere&mdash;the storm clouds in the
+distance begin to form a kind of funnel-shaped dependence, which
+gradually extends until it appears to touch the earth. As the clouds
+are low, this downward-growing column probably in no case is observed
+for the height of more than three or four thousand feet. As the funnel
+descends, the clouds above and about it may be seen to take on a
+whirling movement around the centre, and under favourable
+circumstances an uprush of vapours may be noted in the centre of the
+swaying shaft. As the whirl comes nearer, the roar of the disturbance,
+which at a distance is often compared to the sound made by a threshing
+machine or to that of distant musketry, increases in loudness until it
+becomes overwhelming. When a storm such as this strikes a building, it
+is not only likely to be razed by the force of the wind, but it may be
+exploded, as by the action of gunpowder fired within its walls,
+through the sudden expansion of the air which it contains. In the
+centre of the column, although it rarely has a diameter of more than a
+few hundred feet, the uprush is so swift that it makes a partial
+vacuum. The air, striving to get into the space which it is eager to
+occupy, is whirling about at such a rate that the centrifugal motion
+which it thus acquires restrains its entrance. In this way there may
+be, as the <span class='pagenum'><a name="Page_114" id="Page_114">[Pg 114]</a></span>column rapidly moves by, a difference of pressure
+amounting probably to what the mercury of a barometer would indicate
+by four or five inches of fall. Unless the structure is small and its
+walls strong, its roof and sides are apt to be blown apart by this
+difference of pressure and the consequent expansion of the contained
+air. In some cases where wooden buildings have withstood this curious
+action the outer clapboards have been blown off by the expansion of
+the small amount of air contained in the interspaces between that
+covering and the lath and plaster within (see Fig. 9).</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f9.jpg" width="640" height="455" alt="Fig. 9.&mdash;Showing effect of expansion of air contained
+in a hollow wall during the passage of the storm." title="" />
+<span class="figcaption">Fig. 9.&mdash;Showing effect of expansion of air contained
+in a hollow wall during the passage of the storm.</span>
+</div>
+
+<p>The blow of the air due to its rotative whirling has in several cases
+proved sufficient to throw a heavy locomotive from the track of a
+well-constructed railway. In all cases where it is intense it will
+overturn the strongest trees. The ascending wind in the centre of the
+column may sometimes lift the bodies of men and of animals, as well as
+the branches and trunks of trees and the timber of houses, to the
+height of hundreds of feet above the surface. One of the most striking
+exhibitions of the upsucking <span class='pagenum'><a name="Page_115" id="Page_115">[Pg 115]</a></span>action in a tornado is afforded by the
+effect which it produces when it crosses a small sheet of water. In
+certain cases where, in the Northwestern States of this country, the
+path of the storm lay over the pool, the whole of the water from a
+basin acres in extent has been entirely carried away, leaving the
+surface, as described by an observer, apparently dry enough to plough.</p>
+
+<p>Fortunately for the interests of man, as well as those of the lower
+organic life, the paths of these storms, or at least the portion of
+their track where the violence of the air movement makes them very
+destructive, often does not exceed five hundred feet in width, and is
+rarely as great as half a mile in diameter. In most cases the length
+of the journey of an individual tornado does not exceed thirty miles.
+It rarely if ever amounts to twice that distance.</p>
+
+<p>In every regard except their small size and their violence these
+tornadoes closely resemble hurricanes. There is the same broad disk of
+air next the surface spirally revolving toward the ascending centre,
+where its motion is rapidly changed from a horizontal to a vertical
+direction. The energy of the uprush in both cases is increased by the
+energy set free through the condensation of the water, which tends
+further to heat and thus to expand the air. The smaller size of the
+tornado may be accounted for by the fact that we have in their
+originating conditions a relatively thin layer of warm, moist air next
+the earth and a relatively very cold layer immediately overlying it.
+Thus the tension which serves to start the movement is intense, though
+the masses involved are not very great. The short life of a tornado
+may be explained by the fact that, though it apparently tends to grow
+in width and energy, the central spout is small, and is apt to be
+broken by the movements of the atmosphere, which in the front of a
+cyclone are in all cases irregular.</p>
+
+<p>On the warmer seas, but often beyond the limits of the tropics,
+another class of spinning storms, known as waterspouts, may often be
+observed. In general appearance <span class='pagenum'><a name="Page_116" id="Page_116">[Pg 116]</a></span>these air whirls resemble tornadoes,
+except that they are in all cases smaller than that group of
+whirlings. As in the tornadoes, the waterspout begins with a funnel,
+which descends from the sky to the surface of the sea. Up the tube
+vapours may be seen ascending at great speed, the whole appearing like
+a gigantic pillar of swiftly revolving smoke. When the whirl reaches
+the water, it is said that the fluid leaps up into the tube in the
+form of dense spray, an assertion which, in view of the fact of the
+action of a tornado on a lake as before described, may well be
+believed. Like the tornadoes and dust whirls, the life of a waterspout
+appears to be brief. They rarely endure for more than a few minutes,
+or journey over the sea for more than two or three miles before the
+column appears to be broken by some swaying of the atmosphere. As
+these peculiar storms are likely to damage ships, the old-fashioned
+sailors were accustomed to fire at them with cannon. It has been
+claimed that a shot would break the tube and end the little
+convulsion. This, in view of the fact that they appear to be easily
+broken up by relatively trifling air currents, may readily be
+believed. The danger which these disturbances bring to ships is
+probably not very serious.</p>
+
+<p>The special atmospheric conditions which bring about the formation of
+waterspouts are not well known; they doubtless include, however, warm,
+moist air next the surface of the sea and cold air above. Just why
+these storms never attain greater size or endurance is not yet known.
+These disturbances have been seen for centuries, but as yet they have
+not been, in the scientific sense, observed. Their picturesqueness
+attracts all beholders; it is interesting to note the fact that
+perhaps the earliest description of their phenomena&mdash;one which takes
+account in the scientific spirit of all the features which they
+present&mdash;was written by the poet Camo&euml;ns in the Lusiad, in which he
+strangely mingles fancy and observation in his account of the great
+voyage of Vasco da Gama. The poet even <span class='pagenum'><a name="Page_117" id="Page_117">[Pg 117]</a></span>notes that the water which
+falls when the spout is broken is not salt, but fresh&mdash;a point which
+clearly proves that not much of the water which the tube contains is
+derived from the sea. It is, in fact, watery vapour drawn from the air
+next the surface of the ocean, and condensed in its ascent through the
+tube. In this and other descriptions of Nature Camo&euml;ns shows more of
+the scientific spirit than any other poet of his time. He was in this
+regard the first of modern writers to combine a spiritual admiration
+for Nature with some sense of its scientific meaning.</p>
+
+<p>In treating of the atmosphere, meteorologists base their studies
+largely on changes in the weight of that medium, which they determine
+by barometric observations. In fact, the science of the air had its
+beginning in Pascal's admirable observation on the changes in the
+height of a column of mercury contained in a bent tube as he ascended
+the volcanic peak known as Puy de Dome, in central France. As before
+noted, it is to the disturbances in the weight of the air, brought
+about mainly by variations in temperature, that we owe all its
+currents, and it is upon these winds that the features we term climate
+in largest measure depend. Every movement of the winds is not only
+brought about by changes in the relative weight of the air at certain
+points, but the winds themselves, owing to the momentum which the air
+attains by them, serve to bring about alterations in the quantity of
+air over different parts of the earth, which are marked most
+distinctly by barometric variations. These changes are exceedingly
+complicated; a full account of them would demand the space of this
+volume. A few of the facts, however, should be presented here. In the
+first place, we note that each day there is normally a range in the
+pressure which causes the barometer to be at the lowest at about four
+o'clock in the morning and four o'clock in the afternoon, and highest
+at about ten o'clock in those divisions of the day. This change is
+supposed to be due to the fact that the motes of dust in the
+atmosphere in the night, becoming cooled, <span class='pagenum'><a name="Page_118" id="Page_118">[Pg 118]</a></span>condense the water vapour
+upon their surfaces, thus diminishing the volume of the air. When the
+sun rises the water evaporated by the heat returns from these little
+storehouses into the body of the atmosphere. Again in the evening the
+condensation sets in; at the same time the air tends to drift in from
+the region to the westward, where the sun is still high, toward the
+field where the barometer has been thus lowered; the current gradually
+attains a certain volume, and so brings about the rise of the
+barometer about ten o'clock at night.</p>
+
+<p>In the winter time, particularly on the well-detached continent of
+North America, we find a prevailing high barometer in the interior of
+the country and a corresponding low state of pressure on the Atlantic
+Ocean. In the summer season these conditions are on the whole
+reversed.</p>
+
+<p>Under the tropics, in the doldrum belt, there is a zone of low
+barometer connected to the ascending currents which take place along
+that line. This is a continuous manifestation of the same action which
+gives a large area of a disklike form in the centre or eye of the
+hurricane and in the middle portion of the tornado's whirl. In
+general, it may be said that the weight of the air is greatest in the
+regions from which it is blowing toward the points of upward escape,
+and least in and about those places where the superincumbent air is
+rising through a temporary or permanent line of escape. In other
+words, ascending air means generally a relatively low barometer, while
+descending air is accompanied by greater pressure in the field upon
+which it falls.</p>
+
+<p>In almost every part of the earth which is affected by a particular
+physiography we find that the movements of the atmosphere next the
+surface are qualified by the condition which it encounters. In fact,
+if a person were possessed of all the knowledge which could be
+obtained concerning winds, he could probably determine as by a map the
+place where he might chance to find himself, provided he could extend
+his observations over a term of years.<span class='pagenum'><a name="Page_119" id="Page_119">[Pg 119]</a></span> In other words, the regimen of
+the winds&mdash;at least those of a superficial nature&mdash;is almost as
+characteristic of the field over which they go as is a map of the
+country. Of these special winds a number of the more important have
+been noted, only a few of which we can advert to. First among these
+may well come the land and sea breezes which are remarked about all
+islands which are not continuously swept by permanent winds. One of
+the most characteristic instances of these alternate winds is perhaps
+that afforded on the island of Jamaica.</p>
+
+<p>The island of Jamaica is so situated within the basin of the Caribbean
+that it does not feel the full influence of the trades. It has a range
+of high mountains through its middle part. In the daytime the surface
+of the land, which has the sun overhead twice each year, and is always
+exposed to nearly vertical radiation, becomes intensely hot, so that
+an upcurrent is formed. The formation of this current is favoured by
+the mountains, which apply a part of the heat at the height of about a
+mile above the surface of the sea. This action is parallel to that we
+notice when, in order to create a draught in the air of a chimney, we
+put a torch some distance up above the fireplace, thus diminishing the
+height of the column of air which has to be set in motion. It is
+further shown by the fact that when miners sought to make an upcurrent
+in a shaft, in order to lead pure air into the workings through other
+openings, they found after much experience that it was better to have
+the fire near the top of the shaft rather than at the bottom.</p>
+
+<p>The ascending current being induced up the mountain sides of Jamaica,
+the air is forced in from the sea to the relatively free space. Before
+noon the current, aided in its speed by a certain amount of the
+condensation of the watery vapour before described, attains the
+proportions of a strong wind. As the sun begins to sink, the earth's
+surface pours forth its heat; the radiation being assisted by the
+extended surfaces of the plants, cooling rapidly takes <span class='pagenum'><a name="Page_120" id="Page_120">[Pg 120]</a></span>place.
+Meanwhile the sea, because of the great heat-storing power of water,
+is very little cooled, the ascent of the air ceases, the temporary
+chimney with its updraught is replaced by a downward current, and the
+winds blow from the land until the sun comes again to reverse the
+current. In many cases these movements of the daily winds flowing into
+and from islands induce a certain precipitation of moisture in the
+form of rain. Generally, however, their effect is merely to ameliorate
+the heat by bringing alternately currents from the relatively cool sea
+and from the upper atmosphere to lessen the otherwise excessive
+temperature of the fields which they traverse.</p>
+
+<p>Although characteristic sea and land winds are limited to regions
+where the sun's heat is great, they are traceable even in high
+latitudes during the periods of long-continued calm attended with
+clear skies. Thus on the island of Martha's Vineyard, in
+Massachusetts, the writer has noted, when the atmosphere was in such a
+state, distinct night and day, or sea and land, breezes coming in
+their regular alternation. During the night when these alternate winds
+prevail the central portion of the island, at the distance of three
+miles from the sea, is remarkably cold, the low temperature being due
+to the descending air current. To the same physical cause may be
+attributed the frequent insets of the sea winds toward midday along
+the continental shores of various countries. Thus along the coast of
+New England in the summer season a clear, still, hot day is certain to
+lead to the creation of an ingoing tide of air, which reaches some
+miles into the interior. This stream from the sea enters as a thin
+wedge, it often being possible to note next the shore when the
+movement begins a difference of ten degrees of temperature between the
+surface of the ground to which the point of the wedge has attained,
+and a position twenty feet higher in the air. This is a beautiful
+example to show at once how the relative weight of the atmosphere,
+even when the differences are slight, may bring about motion, and also
+how masses of the <span class='pagenum'><a name="Page_121" id="Page_121">[Pg 121]</a></span>atmosphere may move by or through the rest of the
+medium in a way which we do not readily conceive from our observations
+on the transparent mass. Very few people have any idea how general is
+the truth that the air, even in continuous winds, tends to move in
+more or less individualized masses. This, however, is made very
+evident by watching the gusts of a storm or the wandering patches of
+wind which disturb the surface of an otherwise smooth sea.</p>
+
+
+<div class="figcenter" style="width: 640px;">
+<a name="img05"></a>
+<img src="images/p5.jpg" width="640" height="360" alt="South shore, Martha&#39;s Vineyard, Massachusetts, showing
+a characteristic sand beach with long slope and low dunes. Note the
+three lines of breakers and the splash flows cutting little bays in
+the sand." title="" />
+<span class="caption">South shore, Martha&#39;s Vineyard, Massachusetts, showing
+a characteristic sand beach with long slope and low dunes. Note the
+three lines of breakers and the splash flows cutting little bays in
+the sand.</span>
+</div>
+
+<p>Among the notable local winds are those which from their likeness to
+the F&ouml;hn of the Swiss valleys receive that name. F&ouml;hns are produced
+where a body of air blowing against the slope of a continuous mountain
+range is lifted to a considerable height, and, on passing over the
+crest, falls again to a low position. In its ascent the air is cooled,
+rarefied, and to a great extent deprived of its moisture. In
+descending it is recondensed, and by the process by which its atoms
+are brought together its latent heat is made sensible. There being but
+little watery vapour in the mass, this heat is not much called for by
+that heat-storing fluid, and so the air is warmed. So far F&ouml;hn winds
+have only been remarked as conspicuous features in Switzerland and on
+the eastern face of the Rocky Mountains. In the region about the head
+waters of the Missouri and to the northward their influence in what
+are called the Chinook winds is distinctly to ameliorate the severe
+winter climate of the country.</p>
+
+<p>In almost all great desert regions, particularly in the typical
+Sahara, we find a variety of storm belonging to the whirlwind group,
+which, owing to the nature of the country, take on special
+characteristics. These desert storms take up from the verdureless
+earth great quantities of sand and other fine <i>d&eacute;bris</i>, which often so
+clouds the air as to bring the darkness of night at midday. Their
+whirlings appear in size to be greater than those which produce
+tornadoes or waterspouts, but less than hurricanes or cyclones.
+Little, however, is known about them. They <span class="pagenum"><a name="Page_122" id="Page_122">[Pg 122]</a></span>have not been well
+observed by meteorologists. In some ways they are important, for the
+reason that they serve to carry the desert sand into regions
+previously verdure-clad, and thus to extend the bounds of the desolate
+fields in which they originate. Where they blow off to the seaward,
+they convey large quantities of dust into the ocean, and thus serve to
+wear down the surface of the land in regions where there are no rivers
+to effect that action in the normal way.</p>
+
+<p>Notwithstanding its swift motion when impelled by differences in
+weight, the movements of the air have had but little direct and
+immediate influence on the surface of the earth. The greater part of
+the work which it does, as we shall see hereafter, is done through the
+waters which it impels and bears about. Yet where winds blow over
+verdureless surfaces the effect of the sand which they sweep before
+them is often considerable. In regions of arid mountains the winds
+often drive trains of sand through the valleys, where the sharp
+particles cut the rocks almost as effectively as torrents of water
+would, distributing the wearing over the width of the valley. The dust
+thus blown, from a desert region may, when it attains a country
+covered with vegetation, gradually accumulate on its surface, forming
+very thick deposits. Thus in northwestern China there is a wide area
+where dust accumulations blown from the arid districts of central Asia
+have gradually heaped up in the course of ages to the depth of
+thousands of feet, and this although much of the <i>d&eacute;bris</i> is
+continually being borne away by the action of the rain waters as they
+journey toward the sea. Such dust accumulations occur in other parts
+of the world, particularly in the districts about the upper
+Mississippi and in the valleys of the Rocky Mountains, but nowhere are
+they so conspicuous as in the region first mentioned.</p>
+
+<p>Where prevailing winds from the sea, from great lakes, and even from
+considerable rivers, blow against sandy shores or cliffs of the same
+nature, large quantities of sand <span class='pagenum'><a name="Page_123" id="Page_123">[Pg 123]</a></span>and dust are often driven inland
+from the coast line. In most cases these wind-borne materials take on
+the form of dunes, or heaps of sand, varying from a few feet to
+several hundred feet in height. It is characteristic of these hills of
+blown sand that they move across the face of the country. Under
+favourable conditions they may journey scores of miles from the shore.
+The marching of a dune is effected through the rolling up of the sand
+on the windward side of the elevation, when it is impelled by the
+current of air to the crest where it falls into the lee or shelter
+which the hill makes to the wind. In this way in the course of a day
+the centre of the dune, if the wind be blowing furiously, may advance
+a measurable distance from the place it occupied before. By fits and
+starts this ongoing may be indefinitely continued. A notable and
+picturesque instance of the march of a great dune may be had from the
+case in which one of them overwhelmed in the last century the village
+of Eccles in southeastern England. The advancing sand gradually crept
+into the hamlet, and in the course of a decade dispossessed the people
+by burying their houses. In time the summit of the church spire
+disappeared from view, and for many years thereafter all trace of the
+hamlet was lost. Of late years, however, the onward march of the sands
+has disclosed the church spire, and in the course of another century
+the place may be revealed on its original site, unchanged except that
+the marching hill will be on its other side.</p>
+
+<p>In the region about the head of the Bay of Biscay the quantity of
+these marching sands is so great that at one time they jeopardized the
+agriculture of a large district. The French Government has now
+succeeded, by carefully planting the surface of the country with
+grasses and other herbs which will grow in such places, in checking
+the movement of the wind-blown materials. By so doing they have merely
+hastened the process by which Nature arrests the march of dunes. As
+these heaps creep <span class='pagenum'><a name="Page_124" id="Page_124">[Pg 124]</a></span>away from the sea, they generally come into regions
+where a greater variety of plants flourish; moreover, their sand
+grains become decayed, so that they afford a better soil. Gradually
+the mat of vegetation binds them down, and in time covers them over so
+that only the expert eye can recognise their true nature. Only in
+desert regions can the march of these heaps be maintained for great
+distances.</p>
+
+<p>Characteristic dunes occur from point to point all along the Atlantic
+coast from the State of Maine to the northern coast of Florida. They
+also occur along the coasts of our Great Lakes, being particularly
+well developed at the southern end of Lake Michigan, where they form,
+perhaps, the most notable accumulations within the limits of the
+United States.</p>
+
+<p>When blown sands invade a forest and the deposit is rapidly
+accumulated, the trees are often buried in an undecayed condition. In
+this state, with certain chemical reactions which may take place in
+the mass, the woody matter is apt to become replaced by silex
+dissolved from the sand, which penetrates the tissues of the plants.
+In this way salicified forests are produced, such as are found in the
+region of the Rocky Mountains, where the trunks of the trees, now very
+hard stone, so perfectly preserve their original structure that when
+cut and polished they may be used for decorative purposes. Conspicuous
+as is this work of the dunes, it is in a geological way much less
+important than that accomplished by the finer dust which drifts from
+one region of land to another or into the sea. Because of their
+weight, the sand grains journey over the surface of the earth, except,
+indeed, where they are uplifted by whirl storms. They thus can not
+travel very fast or far. Dust, however, rises into the air, and
+journeys for indefinite distances. We thus see how slight differences
+in the weight of substances may profoundly affect the conditions of
+their deportation.</p>
+
+<p><span class='pagenum'><a name="Page_125" id="Page_125">[Pg 125]</a></span></p>
+<h2 class="subtitle smcap">The System of Waters.</h2>
+
+<p>The envelope of air wraps the earth completely about, and, though
+varying in thickness, is everywhere present over its surface. That of
+the waters is much less equally distributed. Because of its weight, it
+is mainly gathered in the depths of the earth, where it lies in the
+interstices of the rocks and in the great realm of the seas. Only a
+very small portion of the fluid is in the atmosphere or on the land.
+Perhaps less than a ten thousandth part of the whole is at any one
+time on this round from the seas through the air to the land and back
+to the great reservoir.</p>
+
+<p>The great water store of the earth is contained in two distinct
+realms&mdash;in the oceans, where the fluid is concentrated in a quantity
+which fills something like nine tenths of the hollows formed by the
+corrugations of the earth's surface; and in the rocks, where it is
+stored in a finely divided form, partly between the grains of the
+stony matter and partly in the substance of its crystals, where it
+exists in a combination, the precise nature of which is not well
+known, but is called water of crystallization. On the average, it
+seems likely that the materials of the earth, whether under the sea or
+on the land, have several per cent of their mass of the fluid.</p>
+
+<p>It is not yet known to what depth the water-bearing section of the
+earth extends; but, as we shall see more particularly hereafter when
+we come to consider volcanoes, the lavas which they send up to the
+surface are full of contained water, which passes from them in the
+form of steam. The very high temperature of these volcanic ejections
+makes it necessary for us to suppose that they come from a great
+depth. It is difficult to believe that they originate at less than a
+hundred miles below the earth's surface. If, then, the rocks contain
+an average of even five per cent of water to the depth of one hundred
+miles, the quantity of the fluid stored within the earth is greater
+than that which is contained in the reservoir of the ocean.<span class='pagenum'><a name="Page_126" id="Page_126">[Pg 126]</a></span> The
+oceans, on the average, are not more than three miles deep; spread
+evenly over the surface of the whole earth, their depth would be less
+than two miles, while the water in the rocks, if it could be added to
+the seas, would make the total depth seven miles or more. As we shall
+note hereafter, the processes of formation of strata tend to imprison
+water in the beds, which in time is returned to the earth's surface by
+the forces which operate within the crust.</p>
+
+<p>Although the water in the seas is, as we have seen, probably less than
+one half of the store which the earth possesses, the part it plays in
+the economy of the planet is in the highest measure important. The
+underground water operates solely to promote certain changes which
+take place in the mineral realm. Its effect, except in volcanic
+processes, are brought about but slowly, and are limited in their
+action. The movements of this buried water are exceedingly gradual;
+the forces which impel it about and which bring it to do its work
+originate in the earth. In the seas the fluid has an exceeding freedom
+of motion; it can obey the varied impulses which the solar energy
+imposes upon it. The r&ocirc;le of these wonderful actions which we are
+about to trace includes almost everything which goes on upon the
+surface of the planet&mdash;that which relates to the development of animal
+and vegetable life, as well as to the vast geological changes which
+the earth is undergoing.</p>
+
+<p>If the surface of the earth were uniformly covered with water to the
+depth of ten thousand feet or more, every particle of fluid would, in
+a measure, obey the attraction of the sun, of the moon, and,
+theoretically, also of all the other bodies in space, on the principle
+that every particle of matter in the universe exercises a gravitative
+effect on every other. As it is, owing to the divided condition of the
+water on the earth's surface, only that which is in the ocean and
+larger seas exhibits any measurable influence from these distant
+attractions. In fact, only the tides produced by the moon and sun are
+of determinable magnitude, <span class='pagenum'><a name="Page_127" id="Page_127">[Pg 127]</a></span>and of these the lunar is of greater
+importance, the reason being the near position of our satellite to our
+own sphere. The solar tide is four tenths as great as the lunar. The
+water doubtless obeys in a slight way the attraction of the other
+celestial bodies, but the motions thus imparted are too small to be
+discerned; they are lost in the great variety of influences which
+affect all the matter on the earth.</p>
+
+<p>Although the tides are due to the attraction of the solar bodies,
+mainly to that of the moon, the mode in which the result is brought
+about is somewhat complicated. It may briefly and somewhat
+incompletely be stated as follows: Owing to the fact that the
+attracting power of the earth is about eighty times greater than that
+of the moon, the centre of gravity of the two bodies lies within the
+earth. About this centre the spheres revolve, each in a way swinging
+around the other. At this point there is no centrifugal motion arising
+from the revolution of the pair of spheres, but on the side of the
+earth opposite the moon, some six thousand miles away, the centrifugal
+force is considerable, becoming constantly greater as we pass away
+from the turning point. At the same time the attraction of the moon on
+the water becomes less. Thus the tide opposite the satellite is
+formed. On the side toward the moon the same centrifugal action
+operates, though less effectively than in the other case, for the
+reason that the turning point is nearer the surface; but this action
+is re-enforced by the greater attraction of the moon, due to the fact
+that the water is much nearer that body.</p>
+
+<p>In the existing conditions of the earth, what we may call the normal
+run of the tides is greatly interrupted. Only in the southern ocean
+can the waters obey the lunar and solar attraction in anything like a
+normal way. In that part of the earth two sets of tides are
+discernible, the one and greater due to the moon, the other, much
+smaller, to the sun. As these tides travel round at different rates,
+the movements which they produce are some<span class='pagenum'><a name="Page_128" id="Page_128">[Pg 128]</a></span>times added to each other
+and sometimes subtracted&mdash;that is, at times they come together, while
+again the elevation of one falls in the hollow of the other. Once
+again supposing the earth to be all ocean covered, computation shows
+that the tides in such a sea would be very broad waves, having,
+indeed, a diameter of half the earth's circumference. Those produced
+by the moon would have an altitude of about one foot, and those by the
+sun of about three inches. The geological effects of these swayings
+would be very slight; the water would pass over the bottom to and fro
+twice each day, with a maximum journey of a hundred or two feet each
+way from a fixed point. This movement would be so slow that it could
+not stir the fine sediment; its only influence would perhaps be to
+help feed the animals which were fixed upon the bottom by drawing the
+nurture-bringing water by their mouths.</p>
+
+<p>Although the divided condition of the ocean perturbs the action of the
+tides, so that except by chance their waves are rarely with their
+centres where the attracting bodies tend to make them, the influence
+of these divisions is greatly to increase the geological or
+change-bringing influences arising from these movements. When from the
+southern ocean the tides start to the northward up the bays of the
+Atlantic, the Pacific, or the Indian Ocean, they have, as before
+noted, a height of perhaps less than two feet. As they pass up the
+narrowing spaces the waves become compressed&mdash;that is, an equal volume
+of moving water has less horizontal room for its passage, and is
+forced to rise higher. We see a tolerably good illustration of the
+same principle when we observe a wind-made wave enter a small recess
+of the shore, the sides of which converge in the direction of the
+motion. With the diminished room, the wave gains in height. It thus
+comes about that the tide throughout the Atlantic basin is much higher
+than in the southern ocean. On the same principle, when the tide rolls
+in against the shores every embayment of a distinct kind, whose sides
+converge toward the head, packs <span class='pagenum'><a name="Page_129" id="Page_129">[Pg 129]</a></span>up the tidal wave, often increasing
+its height in a remarkable way. When these bays are wide-mouthed and
+of elongate triangular form, with deep bottoms, the tides which on
+their outer parts have a height of ten or fifteen feet may attain an
+altitude of forty or fifty feet at the apex of the triangle.</p>
+
+<p>We have already noted the fact that the tide, such as runs in the
+southern ocean, exercises little or no influence upon the bottom of
+the sea over which it moves. As the height of the confined waters
+increases, the range of their journey over the bottom as the wave
+comes and goes rapidly increases. When they have an elevation of ten
+feet they can probably stir the finer mud on the ocean floor, and in
+shallow water move yet heavier particles. In the embayments of the
+land, where a great body of water journeys like an alternating river
+into extensive basins, the tidal action becomes intense; the current
+may be able to sweep along large stones quite as effectively as a
+mountain torrent. Thus near Eastport, Me., where the tides have a
+maximum rise and fall of over twenty feet, the waters rush in places
+so swiftly that at certain stages of the movement they are as much
+troubled as those at the rapids of the St. Lawrence. In such portions
+of the shore the tides do important work in carving channels into the
+lands.</p>
+
+<p>Along the shores of the continents about the North Atlantic, where the
+tides act in a vigorous manner, we almost everywhere find an
+underwater shelf extending from the shore with a declivity of only
+five to ten feet to the mile toward the centre of the sea, until the
+depth of about five hundred feet is attained; from this point the
+bottom descends more steeply into the ocean's depth. It is probable
+that the larger part of the material composing these continental
+shelves has been brought to its position by tidal action. Each time
+the tidal wave sweeps in toward the shore it urges the finer particles
+of sediment along with it. When it moves out it drags them on the
+<span class='pagenum'><a name="Page_130" id="Page_130">[Pg 130]</a></span>return journey toward the depths of the sea. If this shelf were
+perfectly horizontal, the two journeys of the sand and mud grains
+would be of the same length; but as the movement takes place up and
+down a slope, the bits will travel farther under the impulse which
+leads them downward than under that which impels them up. The result
+will be that the particles will travel a little farther out from the
+shore each time it is swung to and fro in the alternating movement of
+the tide.</p>
+
+<p>The effect of tidal movement in nurturing marine life is very great.
+It aids the animals fixed on the bottoms of the deep seas to obtain
+their provision of food and their share of oxygen by drawing the water
+by their bodies. All regions which are visited by strong tides
+commonly have in the shallows near the shores a thick growth of
+seaweed which furnishes an ample provision of food for the fishes and
+other forms of animal life.</p>
+
+<p>A peculiar effect arising from tidal action is believed by students of
+the phenomena to be found in the slowing of the earth's rotation on
+its axis. The tides rotate around the earth from east to west, or
+rather, we should say, the solid mass of the earth rubs against them
+as it spins from west to east. As they move over the bottom and as
+they strike against the shores this push of the great waves tends in a
+slight measure to use up the original spinning impulse which causes
+the earth's rotation. Computation shows that the amount of this action
+should be great enough gradually to lengthen the day, or the time
+occupied by the earth in making a complete revolution on the polar
+axis. The effect ought to be great enough to be measurable by
+astronomers in the course of a thousand years. On the other hand, the
+records of ancient eclipses appear pretty clearly to show that the
+length of the day has not changed by as much as a second in the course
+of three thousand years. This evidence does not require us to abandon
+the supposition that the tides tend to diminish the earth's rate of
+rotation. It is more likely that the <span class='pagenum'><a name="Page_131" id="Page_131">[Pg 131]</a></span>effect of the reduction in the
+earth's diameter due to the loss of heat which is continually going on
+counterbalances the influence of the tidal friction. As the diameter
+of a rotating body diminishes, the tendency is for the mass to spin
+more rapidly; if it expands, to turn more slowly, provided in each
+case the amount of the impulse which leads to the turning remains the
+same. This can be directly observed by whirling a small weight
+attached to a string in such a manner that the cord winds around the
+finger with each revolution; it will be noted that as the line
+shortens the revolution is more quickly accomplished. We can readily
+conceive that the earth is made up of weights essentially like that
+used in the experiment, each being drawn toward the centre by the
+gravitative stress, which is like that applied to the weight by the
+cord.</p>
+
+<p>The fact that the days remain of the same length through vast periods
+of time is probably due to this balance between the effects of tidal
+action and those arising from the loss of heat&mdash;in other words, we
+have here one of those delicate arrangements in the way of
+counterpoise which serve to maintain the balanced conditions of the
+earth's surface amid the great conflicts of diverse energies which are
+at work in and upon the sphere.</p>
+
+<p>It should be understood that the effects of the attraction which
+produces tides are much more extensive than they are seen to be in the
+movements of the sea. So long as the solar and planetary spheres
+remain fluid, the whole of their masses partake of the movement. It is
+a consequence of this action, as the computations of Prof. George
+Darwin has shown, that the moon, once nearer the earth than it is at
+present, has by a curious action of the tidal force been pushed away
+from the centre of our sphere, or rather the two bodies have repelled
+each other. An American student of the problem, Mr. T.J.J. See, has
+shown that the same action has served to give to the double stars the
+exceeding eccentricity of their orbits.</p>
+
+<p>Although these recent studies of tidal action in the <span class='pagenum'><a name="Page_132" id="Page_132">[Pg 132]</a></span>celestial sphere
+are of the utmost importance to the theory of the universe, for they
+may lead to changes in the nebular hypotheses, they are as yet too
+incomplete and are, moreover, too mathematical to be presented in an
+elementary treatise such as this.</p>
+
+<hr style='width: 45%;' />
+
+<p>We now turn to another class of waves which are of even more
+importance than those of the tides&mdash;to the undulations which are
+produced by the action of the wind on the surface of the water. While
+the tide waves are limited to the open ocean, and to the seas and bays
+which afford them free entrance, wind waves are produced everywhere
+where water is subjected to the friction of air which flows over it.
+While tidal waves come upon the shores but twice each day, the wind
+waves of ordinary size which roll in from the ocean deliver their
+blows at intervals of from three to ten seconds. Although the tidal
+waves sometimes, by a packing-up process, attain the height of fifty
+feet, their average altitude where they come in contact with the shore
+probably does not much exceed four feet; usually they come in gently.
+It is likely that in a general way the ocean surges which beat against
+the coast are of greater altitude.</p>
+
+<p>Wind waves are produced and perform their work in a manner which we
+shall now describe. When the air blows over any resisting surface, it
+tends, in a way which we can hardly afford here to describe, to
+produce motions. If the particle is free to move under the impulse
+which it communicates, it bears it along; if it is linked together in
+the manner of large masses, which the wind can not transport, it tends
+to set it in motion in an alternating way. The sounds of our musical
+instruments which act by wind are due to these alternating vibrations,
+such as all air currents tend to produce. An &AElig;olian harp illustrates
+the action which we are considering. Moving over matter which has the
+qualities that we denote by the term fluid, the swayings which the air
+produces are of a peculiar sort, though they much resemble those of
+the fiddle string.<span class='pagenum'><a name="Page_133" id="Page_133">[Pg 133]</a></span> The surface of the liquid rises and falls in what
+we term waves, the size of which is determined by the measure of
+fluidity, and by the energy of the wind. Thus, because fresh water is
+considerably lighter than salt, a given wind will produce in a given
+distance for the run of the waves heavier surges in a lake than it
+will in the sea. For this reason the surges in a great storm which
+roll on the ocean shore, because of the wide water over which they
+have gathered their impetus, are in size very much greater than those
+of the largest lakes, which do not afford room for the development of
+great undulations.</p>
+
+<p>To the eye, a wave in the water appears to indicate that the fluid is
+borne on before the wind. Examination, however, shows that the amount
+of motion in the direction in which the wind is blowing is very
+slight. We may say, indeed, that the essential feature of a wave is
+found in the transmission of impulse rather than in the movement of
+the fluid matter. A strip of carpet when shaken sends through its
+length undulations which are almost exactly like water waves. If we
+imagine ourselves placed in a particle of water, moving in the
+swayings of a wave in the open and deep sea, we may conceive ourselves
+carried around in an ellipse, in each revolution returning through
+nearly the same orbit. Now and then, when the particle came to the
+surface, it would experience the slight drift which the continual
+friction of the wind imposes on the water. If the wave in which the
+journey was made lay in the trade winds, where the long-continued,
+steadfast blowing had set the water in motion to great depths, the
+orbit traversed would be moving forward with some rapidity; where also
+the wind was strong enough to blow the tops of the waves over, forming
+white-caps, the advance of the particle very near the surface would be
+speedy. Notwithstanding these corrections, waves are to be regarded
+each as a store of energy, urging the water to sway much in the manner
+of a carpet strip, and by the swaying conveying the energy in the
+direction of the wave movement.</p>
+
+<p><span class='pagenum'><a name="Page_134" id="Page_134">[Pg 134]</a></span></p><p>The rate of movement of wind waves increases with their height.
+Slight undulations go forward at the rate of less than half a mile an
+hour. The greater surges of the deeps when swept by the strongest
+winds move with the speed which, though not accurately determined, has
+been estimated by the present writer as exceeding forty miles an hour.
+As these surges often have a length transverse to the wind of a mile
+or more, a width of about an eighth of a mile, and a height of from
+thirty-five to forty-five feet, the amount of energy which they
+transmit is very great. If it could be effectively applied to the
+shores in the manner in which the energy of exploding gunpowder is
+applied by cannon shot, it is doubtful whether the lands could have
+maintained their position against the assaults of the sea. But there
+are reasons stated below why the ocean waves can use only a very small
+part of their energy in rending the rocks against which they strike on
+the coast line.</p>
+
+<p>In the first place, we should note that wind waves have very little
+influence on the bottom of the deep sea. If an observer could stand on
+the sea floor at the depth of a mile below a point over which the
+greatest waves were rolling, he could not with his unaided senses
+discern that the water was troubled. He would, indeed, require
+instruments of some delicacy to find out that it moved at all. Making
+the same observations at the depth of a thousand feet, it is possible
+that he would note a slight swaying motion in the water, enough
+sensibly to affect his body. At five hundred feet in depth the
+movement would probably be sufficient to disturb fine mud. At two
+hundred feet, the rasping of the surge on the bottom would doubtless
+be sufficient to push particles of coarse sand to and fro. At one
+hundred feet in depth, the passage of the surge would be strong enough
+to urge considerable pebbles before it. Thence up the slope the
+driving action would become more and more intense until we attained
+the point where the wave broke. It should furthermore be noted <span class='pagenum'><a name="Page_135" id="Page_135">[Pg 135]</a></span>that,
+while the movement of the water on the floor of the deep sea as the
+wave passes overhead would be to and fro, with every advance in the
+shallowing and consequent increased friction on the bottom, the
+forward element in the movement would rapidly increase. Near the coast
+line the effect of the waves is continually to shove the detritus up
+the slopes of the continental shelf. Here we should note the fact that
+on this shelf the waves play a part exactly the opposite of that
+effected by the tides. The tides, as we have noted, tend to drag the
+particles down the slope, while the waves operate to roll them up the
+declivity.</p>
+
+<p>As the wave in advancing toward the shore ordinarily comes into
+continually shallowing water, the friction on the bottom is
+ever-increasing, and serves to diminish the energy the surge contains,
+and therefore to reduce its proportions. If this action operated
+alone, the subtraction which the friction makes would cause the surf
+waves which roll in over a continental shelf to be very low, probably
+in height less than half that which they now attain. In fact, however,
+there is an influence at work to increase the height of the waves at
+the expense of its width. Noting that the friction rapidly increases
+with the shallowing, it is easy to see that this resistance is
+greatest on the advancing front of the wave, and least on its seaward
+side. The result is that the front moves more slowly than the rear, so
+that the wave is forced to gain in height; but for the fact that the
+total friction which the wave encounters takes away most of its
+impetus, we might have combers a hundred feet high rolling upon the
+shelving shores which almost everywhere face the seas.</p>
+
+<p>As the wave shortens its width and gains in relative height, though
+not in actual elevation, another action is introduced which has
+momentous consequences. The water in the bottom of the wave is greatly
+retarded in its ongoing by its friction over the sea floor, while the
+upper part of the surge is much less affected in this way. The result
+is that at a certain point in the advance, the place of which <span class='pagenum'><a name="Page_136" id="Page_136">[Pg 136]</a></span>is
+determined by the depth, the size, and the speed of the undulation,
+the front swiftly steepens until it is vertical, and the top shoots
+forward to a point where it is no longer supported by underlying
+water, when it plunges down in what is called the surf or breaker. In
+this part of the wave's work the application of the energy which it
+transmits differs strikingly from the work previously done. Before the
+wave breaks, the only geological task which it accomplishes is
+effected by forcing materials up the slope, in which movement they are
+slightly ground over each other until they come within the battering
+zone of the shore, where they may be further divided by the action of
+the mill which is there in operation.</p>
+
+<p>When the wave breaks on the shore it operates in the following manner:
+First, the overturning of its crest sends a great mass of water, it
+may be from the height of ten or more feet, down upon the shore. Thus
+falling water has not only the force due to its drop from the summit
+of the wave, but it has a share of the impulse due to the velocity
+with which the surge moved against the shore. It acts, in a word, like
+a hammer swung down by a strong arm, where the blow represents not
+only the force with which the weight would fall of itself, but the
+impelling power of the man's muscles. Any one who will expose his body
+to this blow of the surf will recognise how violent it is; he may, if
+the beach be pebbly, note how it drives the stones about; fragments
+the size of a man's head may be hurled by the stroke to the distance
+of twenty feet or more; those as large as the fist may be thrown clear
+beyond the limits of the wave. So vigorous is this stroke that the
+sound of it may sometimes be heard ten miles inland from the coast
+where it is delivered.</p>
+
+<p>Moving forward up the slope of a gently inclined beach, the fragments
+of the wave are likely to be of sufficient volume to permit them to
+regather into a secondary surge, which, like the first, though much
+smaller, again rises into a wall, forming another breaker. Under
+favour<span class='pagenum'><a name="Page_137" id="Page_137">[Pg 137]</a></span>able conditions as many as four or five of these successive
+diminishing surf lines may be seen. The present writer has seen in
+certain cases as many as a dozen in the great procession, the lowest
+and innermost only a few inches high, the outer of all with a height
+of perhaps twenty feet.</p>
+
+<p>Along with the direct bearing action of the surf goes a to-and-fro
+movement, due to the rushing up and down of the water on the beach.
+This swashing affects not only the broken part of the waves, but all
+the water between the outer breaker and the shore. These swayings in
+the surf belt often swing the <i>d&eacute;bris</i> on the inner margin over a
+range of a hundred feet or more, the movement taking place with great
+swiftness, affecting the pebbles to the depth of several inches, and
+grinding the bits together in a violent way. Listening to the turmoil
+of a storm, we can on a pebbly beach distinctly hear the sound of the
+downward stroke, a crashing tone, and the roar of the rolling stones.</p>
+
+<p>As waves are among the interesting things in the world, partly on
+account of their living quality and partly because of their immediate
+and often exceeding interest to man, we may here note one or two
+peculiar features in their action. In the first place, as the reader
+who has gained a sense of the changes in form of action may readily
+perceive, the beating of waves on the shore converts the energy which
+they possess into heat. This probably warms the water during great
+storms, so that by the hand we may note the difference in temperature
+next the coast line and in the open waters. This relative warmth of
+the surf water is perhaps a matter of some importance in limiting the
+development of ice along the shore line; it may also favour the
+protection of the coast life against the severe cold of the winter
+season.</p>
+
+<p>The waves which successively come against the shore in any given time,
+particularly if a violent wind is blowing on to the coast, are usually
+of about the same size. When, however, in times of calm an old sea, as
+it is called, is roll<span class='pagenum'><a name="Page_138" id="Page_138">[Pg 138]</a></span>ing in, the surges may occasionally undergo very
+great variations in magnitude. Not infrequently these occasional waves
+are great enough to overwhelm persons who are upon the rocks next the
+shore. These greater surges are probably to be accounted for by the
+fact that in the open sea waves produced by winds blowing in different
+directions may run on with their diverse courses and varied intervals
+until they come near the shore. Running in together, it very well
+happens that two of the surges belonging to different sets may combine
+their forces, thus doubling the swell. The danger which these
+conjoined waves bring is obviously greatest on cliff shores, where, on
+account of the depth of water, the waves do not break until they
+strike the steep.</p>
+
+<hr style='width: 45%;' />
+
+<p>Having considered in a general way the action of waves as they roll in
+to the shore, bearing with them the solar energy which was contributed
+to them by the winds, we shall now take up in some detail the work
+which goes on along the coast line&mdash;work which is mainly accomplished
+by wave action.</p>
+
+<p>On most coast lines the observer readily notes that the shore is
+divided into two different kinds of faces&mdash;those where the inner
+margin of the wave-swept belt comes against rocky steeps, and those
+bordered by a strand altogether composed of materials which the surges
+have thrown up. These may be termed for convenience cliff shores and
+wall-beach shores. We shall begin our inquiry with cliff shores, for
+in those sections of the coast line the sea is doing its most
+characteristic and important work of assaulting the land. If the
+student has an opportunity to approach a set of cliffs of hard rock in
+time of heavy storm, when the waves have somewhere their maximum
+height, he should seek some headland which may offer him safe foothold
+whence he can behold the movements which are taking place. If he is so
+fortunate as to have in view, as well may be the case, cliffs which
+extend down <span class='pagenum'><a name="Page_139" id="Page_139">[Pg 139]</a></span>into deep water, and others which are bordered by rude
+and generally steeply sloping beaches covered with large stones, he
+may perceive that the waves come in against the cliffs which plunge
+into deep water without taking on the breaker form. In this case the
+undulation strikes but a moderate blow; the wave is not greatly
+broken. The part next the rock may shoot up as a thin sheet to a
+considerable height; it is evident that while the ongoing wave applies
+a good deal of pressure to the steep, it does not deliver its energy
+in the effective form of a blow as when the wave overturns, or in the
+consequent rush of the water up a beach slope. It is easy to perceive
+that firm-set rock cliffs, with no beaches at their bases, can almost
+indefinitely withstand the assaults. On the steep and stony beach,
+because of its relatively great declivity, the breaker or surf forms
+far in, and even in its first plunge often attains the base of the
+precipice. The blow of the overfalling as well as that of the inrush
+moves about stones of great size; those three feet or more in diameter
+are often hurled by the action against the base of the steep, striking
+blows, the sharp note of which can often be heard above the general
+roar which the commotion produces. The needlelike crags forming isles
+standing at a distance from the shore, such as are often found along
+hard rock coasts, are singularly protected from the action of
+effective waves. The surges which strike against them are unarmed with
+stones, and the water at their bases is so deep that it does not sway
+with the motion with sufficient energy to move them on the bottom.
+Where a cliff is in this condition, it may endure until an elevation
+of the coast line brings its base near the level of the sea, or until
+the process of decay has detached a sufficient quantity of stone to
+form a talus or inclined plane reaching near to the water level.</p>
+
+<p>As before noted, it is the presence of a sloping beach reaching to
+about the base of the cliff which makes it possible for the waves to
+strike at with a hammer instead of with a soft hand. Battering at the
+base of the cliff, <span class='pagenum'><a name="Page_140" id="Page_140">[Pg 140]</a></span>the surges cut a crease along the strip on which
+they strike, which gradually enters so far that the overhanging rock
+falls of its own weight. The fragments thus delivered to the sea are
+in turn broken up and used as battering instruments until they are
+worn to pieces. We may note that in a few months of heavy weather the
+stones of such a fall have all been reduced to rudely spherical forms.
+Observations made on the eastern face of Cape Ann, Mass., where the
+seas are only moderately heavy, show that the storms of a single
+winter reduce the fragments thrown into the sea from the granite
+quarries to spheroidal shapes, more than half of their weight commonly
+being removed in the form of sand and small pebbles which have been
+worn from their surfaces.</p>
+
+<p>We can best perceive the effect of battering action which the sea
+applies to the cliffs by noting the points where, owing to some chance
+features in the structure in the rock, it has proved most effective.
+Where a joint or a dike, or perhaps a softer layer, if the rocks be
+bedded, causes the wear to go on more rapidly, the waves soon excavate
+a recess in which the pebbles are retained, except in stormy weather,
+in an unmoved condition. When the surges are heavy, these stones are
+kept in continuous motion, receding as the wave goes back, and rushing
+forward with its impulse until they strike against the firm-set rock
+at the end of the chasm. In this way they may drive in a cut having
+the length of a hundred feet or more from the face of the precipice.
+In most cases the roofs over these sea caves fall in, so that the
+structure is known as a chasm. Occasionally these roofs remain, in
+which case, for the reason that the floor of the cutting inclines
+upward, an opening is made to the surface at their upper end, forming
+what is called in New England a "spouting horn"; from the inland end
+of the tunnel the spray may be thrown far into the air. As long as the
+cave is closed at this inner end, and is not so high but that it may
+be buried beneath a heavy wave, the inrushing water com<span class='pagenum'><a name="Page_141" id="Page_141">[Pg 141]</a></span>presses the
+air in the rear parts of the opening. When the wave begins to retreat
+this air blows out, sending a gust of spray before it, the action
+resembling the discharge of a great gun from the face of a
+fortification. It often happens that two chasms converging separate a
+rock from the cliff. Then a lowering of the coast may bring the mass
+to the state of a columnar island, such as abound in the Hebrides and
+along various other shores.</p>
+
+<p>If a cliff shore retreats rapidly, it may be driven back into the
+shore, and its face assumes the curve of a small bay. With every step
+in this change the bottom is sure to become shallower, so that the
+waves lose more and more of their energy in friction over the bottom.
+Moreover, in entering a bay the friction which the waves encounter in
+running along the sides is greater than that which they meet in
+coming in upon a headland or a straight shore. The result is, with the
+inward retreat of the steep it enters on conditions which diminish the
+effectiveness of the wave stroke. The embayment also is apt to hold
+detritus, and so forms in time a beach at the foot of the cliff, over
+which the waves rarely are able to mount with such energy as will
+enable them to strike the wall in an effective manner. With this
+sketch of the conditions of a cliff shore, we will now consider the
+fate of the broken-tip rock which the waves have produced on that
+section of the coast land.</p>
+
+<p>By observation of sea-beaten cliffs the student readily perceives that
+a great amount of rocky matter has been removed from most cliff-faced
+shores. Not uncommonly it can be shown that such sea faces have
+retreated for several miles. The question now arises, What becomes of
+the matter which has been broken up by the wave action? In some part
+the rock, when pulverized by the pounding to which it is subjected,
+has dissolved in the water. Probably ninety per cent of it, however,
+retains the visible state, and has a fate determined by the size of
+the fragments of which it is composed. If these be as fine as mud, <span class='pagenum'><a name="Page_142" id="Page_142">[Pg 142]</a></span>so
+that they may float in the water, they are readily borne away by the
+currents which are always created along a storm-swept shore,
+particularly by the undertow or bottom outcurrent&mdash;the "sea-puss," as
+it is sometimes called&mdash;that sweeps along the bottom from every shore,
+against which the waves form a surf. If as coarse as sand grains, or
+even very small pebbles, they are likely to be drawn out, rolling over
+the bottom to an indefinite distance from the sea margin. The coarser
+stones, however, either remain at the foot of the cliff until they are
+beaten to pieces, or are driven along the shore until they find some
+embayment into which they enter. The journey of such fragments may,
+when the wind strikes obliquely to the shore, continue for many miles;
+the waves, running with the wind, drive the fragments in oscillating
+journeys up and down the beach, sometimes at the rate of a mile or
+more a day. The effect of this action can often be seen where a vessel
+loaded with brick or coal is wrecked on the coast. In a month
+fragments of the materials may be stretched along for the distance of
+many miles on either side of the point where the cargo came ashore.
+Entering an embayment deep enough to restrain their further journey,
+the fragments of rock form a boulder beach, where the bits roll to and
+fro whenever they are struck by heavy surges. The greater portion of
+them remain in this mill until they are ground to the state of sand
+and mud. Now and then one of the fragments is tossed up beyond the
+reach of the waves, and is contributed to the wall of the beach. In
+very heavy storms these pebbles which are thrown inland may amount in
+weight to many tons for each mile of shore.</p>
+
+<p>The study of a pebbly beach, drawn from crest to the deep water
+outside, will give an idea as to the history of its work. On either
+horn of the crescent by which the pebbles are imported into the pocket
+we find the largest fragments. If the shore of the bay be long, the
+innermost part of the recess may show even only very small pebbles, or
+perhaps only fine sand, the coarser material having <span class='pagenum'><a name="Page_143" id="Page_143">[Pg 143]</a></span>been worn out in
+the journey. On the bottom of the bay, near low tide, we begin to find
+some sand produced by the grinding action. Yet farther out, below
+high-tide mark, there is commonly a layer of mud which represents the
+finer products of the mill.</p>
+
+<p>Boulder beaches are so quick in answering to every slight change in
+the conditions which affect them that they seem almost alive. If by
+any chance the supply of detritus is increased, they fill in between
+the horns, diminish the incurve of the bay, and so cause its beach to
+be more exposed to heavy waves. If, on the other hand, the supply of
+grist to the mill is diminished, the beach becomes more deeply
+incurved, and the wave action is proportionately reduced. We may say,
+in general, that the curve of these beaches represents a balance
+between the consumption and supply of the pebbles which they grind up.
+The supply of pebbles brought along the shore by the waves is in many
+cases greatly added to by a curious action of seaweeds. If the bottom
+of the water off the coast is covered by these fragments, as is the
+case along many coast lines within the old glaciated districts, the
+spores of alg&aelig; are prone to take root upon them. Fastening themselves
+in those positions, and growing upward, the seaweeds may attain
+considerable size. Being provided with floats, the plant exercises a
+certain lifting power on the stone, and finally the tugging action of
+the waves on the fronds may detach the fragments from the bottom,
+making them free to journey toward the shore. Observing from near at
+hand the straight wall of the wave in times of heavy storm, the
+present writer has seen in one view as many as a dozen of these
+plant-borne stones, sometimes six inches in diameter, hanging in the
+walls of water as it was about to topple over. As soon as they strike
+the wave-beaten part of the shore these stones are apt to become
+separated from the plants, though we can often notice the remains or
+prints of the attachments adhering to the surface of the rock. Where
+the pebbles off the shore are plenty, a rocky beach <span class='pagenum'><a name="Page_144" id="Page_144">[Pg 144]</a></span>may be produced
+by this process of importation through the agency of seaweeds without
+any supply being brought by the waves along the coast line.</p>
+
+<p>Returning to sand beaches, we enter the most interesting field of
+contact between seas and lands. Probably nine tenths of all the coast
+lines of the open ocean are formed of arenaceous material. In general,
+sand consists of finely broken crystals of silica or quartz. These
+bits are commonly distinctly faceted; they rarely have a spherical
+form. Not only do accumulations of sand border most of the shore line,
+but they protect the land against the assaults of the sea, and this in
+the following curious manner: When shore waves beat pebbles against
+each other, they rapidly wear to bits; we can hear the sound of the
+wearing action as the wave goes to and fro. We can often see that the
+water is discoloured by the mud or powdered rock. When, however, the
+waves tumble on a sandy coast, they make but a muffled sound, and
+produce no mud. In fact, the particles of sand do not touch each other
+when they receive the blow. Between them there lies a thin film of
+water, drawn in by the attraction known as capillarity, which sucks
+the fluid into a sponge or between plates of glass placed near
+together. The stroke of the waves slightly compresses this capillary
+water, but the faces of the grains are kept apart as sheets of glass
+may be observed to be restrained from contact when water is between
+them. If the reader would convince himself as to the condition of the
+sand grains and the water which is between them, he may do so by
+pressing his foot on the wet beach which the wave has just left. He
+will observe that it whitens and sinks a little under the pressure,
+but returns in good part to its original form when the foot is lifted.
+In the experiment he has pushed a part of the contained water aside,
+but he has not brought the grains together; they do not make the sound
+which he will often hear when the sand is dry. The result is that the
+sand on the seashore may wear more in going the dis<span class='pagenum'><a name="Page_145" id="Page_145">[Pg 145]</a></span>tance of a mile in
+the dry sand dune than in travelling for hundreds along the wet shore.</p>
+
+<p>If the rock matter in the state of sand wore as rapidly under the
+heating of the waves as it does in the state of pebbles, the
+continents would doubtless be much smaller than they are. Those coasts
+which have no other protection than is afforded by a low sand beach
+are often better guarded against the inroads of the sea than the
+rock-girt parts of the continents. It is on account of this remarkable
+endurance of sand of the action of the waves that the stratified rocks
+which make up the crust of the earth are so thick and are to such an
+extent composed of sand grains.</p>
+
+<p>The tendency of the <i>d&eacute;bris</i>-making influences along the coast line is
+to fill in the irregularities which normally exist there; to batter
+off the headlands, close up the bays and harbours, and generally to
+reduce the shores to straight lines. Where the tide has access to
+these inlets, it is constantly at work in dragging out the detritus
+which the waves make and thrust into the recesses. These two actions
+contend with each other, and determine the conditions of the coast
+line, whether they afford ports for commerce or are sealed in by sand
+bars, as are many coast lines which are not tide-swept, as that of
+northern Africa, which faces the Mediterranean, a nearly tideless sea.
+The same is the case with the fresh-water lakes; even the greater of
+them are often singularly destitute of shelters which can serve the
+use of ships, and this because there are no tides to keep the bays and
+harbours open.</p>
+
+
+<h2 class="subtitle smcap">The Ocean Currents.</h2>
+
+<p>The system of ocean currents, though it exhibits much complication in
+detail, is in the main and primarily dependent on the action of the
+constant air streams known as the trade winds. With the breath from
+the lips over a basin of water we can readily make an experiment which
+<span class='pagenum'><a name="Page_146" id="Page_146">[Pg 146]</a></span>shows in a general way the method in which the winds operate in
+producing the circulation of the sea. Blowing upon the surface of the
+water in the basin, we find that even this slight impulse at once sets
+the upper part in motion, the movement being of two kinds&mdash;pulsating
+movements or waves are produced, and at the same time the friction of
+the air on the surface causes its upper part to slide over the under.
+With little floats we can shortly note that the stream which forms
+passes to the farther side of the vessel, there divides, and returns
+to the point of beginning, forming a double circle, or rather two
+ellipses, the longer sides of which are parallel with the line of the
+air current. Watching more closely, aiding the sight by the particles
+which float at various distances below the surface, we note the fact
+that the motion which was at first imparted to the surface gradually
+extends downward until it affects the water to the depth of some
+inches.</p>
+
+<p>In the trade-wind belt the ocean waters to the depth of some hundreds
+of feet acquire a continuous movement in the direction in which they
+are impelled by those winds. This motion is most rapid at the surface
+and near the tropics. It diminishes downwardly in the water, and also
+toward the polar sides of the trade-wind districts. Thus the trades
+produce in the sea two broad, slow-moving, deep currents, flowing in
+the northern hemisphere toward the southwest, and in the southern
+hemisphere toward the northwest. Coming down upon each other
+obliquely, these broad streams meet about the middle of the tropical
+belt. Here, as before noted, the air of the trade winds leaves the
+surface and rises upward. The waters being retained on their level,
+form a current which moves toward the west. If the earth within the
+tropics were covered by a universal sea, the result of this movement
+would be the institution of a current which, flowing under the
+equator, would girdle the sphere.</p>
+
+<p>With a girdling equatorial current, because of the intense heat of the
+tropics and the extreme cold of the <span class='pagenum'><a name="Page_147" id="Page_147">[Pg 147]</a></span>parallels beyond the fortieth
+degree of latitude, the earth would be essentially uninhabitable to
+man, and hardly so to any forms of life. Its surface would be visited
+by fierce winds induced by the very great differences of temperature
+which would then prevail. Owing, however, to the barriers which the
+continents interpose to the motions of these windward-setting tropical
+currents, all the water which they bear, when it strikes the opposing
+shores, is diverted to the right and left, as was the stream in the
+experiment with the basin and the breath, the divided currents seeking
+ways toward high latitudes, conveying their store of heat to the
+circumpolar lands. So effective is this transfer of temperature that a
+very large part of the heat which enters the waters in the tropical
+region is taken out of that division of the earth's surface and
+distributed over the realms of sea and land which lie beyond the
+limits of the vertical sun. Thus the Gulf Stream, the northern branch
+of the Atlantic tropical current, by flowing into the North Atlantic,
+contributes to the temperature of the region within the Arctic Circle
+more heat than actually comes to that district by the direct influx
+from the sun.</p>
+
+<p>The above statements as to the climatal effect of the ocean streams
+show us how important it is to obtain a sufficient conception as to
+the way in which these currents now move and what we can of their
+history during the geologic ages. This task can not yet be adequately
+done. The fields of the sea are yet too imperfectly explored to afford
+us all the facts required to make out the whole story. Only in the
+case of our Gulf Stream can we form a full conception as to the
+journey which the waters undergo and the consequence of their motion.
+In the case of this current, observations clearly show that it arises
+from the junction near the equatorial line of the broad stream created
+by the two trade-wind belts. Uniting at the equator, these produce a
+westerly setting current, having the width of some hundred miles and a
+depth of several hundred feet. Its velocity is somewhat greater than a
+<span class='pagenum'><a name="Page_148" id="Page_148">[Pg 148]</a></span>mile an hour. The centre of the current, because of the greater
+strength of the northern as compared with the southern trades, is
+considerably south of the equator. When this great slow-moving stream
+comes against the coast of South America, it encounters the projecting
+shoulder of that land which terminates at Cape St. Roque. There it
+divides, as does a current on the bows of an anchored ship, a
+part&mdash;rather more than one half&mdash;of the stream turning to the
+northward, the remainder passing toward the southern pole; this
+northerly portion becomes what is afterward known as the Gulf Stream,
+the history of which we shall now briefly follow.</p>
+
+<p>Flowing by the northwesterly coast of South America, the northern
+share of the tropical current, being pressed in against the land by
+the trade winds, is narrowed, and therefore acquires at once a swifter
+flow, the increased speed being due to conditions like those which add
+to the velocity of the water flowing through a hose when it comes to
+the constriction of the nozzle. Attaining the line of the southeastern
+or Lesser Antilles, often known as the Windward Islands, a part of
+this current slips through the interspaces between these isles and
+enters the Gulf of Mexico. Another portion, failing to find sufficient
+room through these passages, skirts the Antilles on their eastern and
+northern sides, passes by and among the Bahama Islands, there to
+rejoin the part of the stream which entered the Caribbean. This
+Caribbean portion of the tide spreads widely in that broad sea, is
+constricted again between Cuba and Yucatan, again expands in the Gulf
+of Mexico, and is finally poured forth through the Straits of Florida
+as a stream having the width of forty or fifty miles, a depth of a
+thousand feet or more, and a speed of from three to five miles an
+hour, exceeding in its rate of flow the average of the greatest
+rivers, and conveying more water than do all the land streams of the
+earth. In this part of its course the deep and swift stream from the
+Gulf of Mexico, afterward to be named the Gulf Stream, <span class='pagenum'><a name="Page_149" id="Page_149">[Pg 149]</a></span>receives the
+contribution of slower moving and shallower currents which skirted the
+Antilles on their eastern verge. The conjoined waters then move
+northward, veering toward the east, at first as a swift river of the
+sea having a width of less than a hundred miles and of great depth;
+with each step toward the pole this stream widens, diminishing
+proportionately in depth; the speed of its current decreases as the
+original impetus is lost, and the baffling winds set its surface
+waters to and fro in an irregular way. Where it passes Cape Hatteras
+it has already lost a large share of its momentum and much of its
+heat, and is greatly widened.</p>
+
+<p>Although the current of the Gulf Stream becomes more languid as we go
+northward, it for a very long time retains its distinction from the
+waters of the sea through which it flows. Sailing eastward from the
+mouth of the Chesapeake, the navigator can often observe the moment
+when he enters the waters of this current. This is notable not only in
+the temperature, but in the hue of the sea. North of that line the
+sharpness of the parting wall becomes less distinct, the stream
+spreads out broadly over the surface of the Atlantic, yet its
+thermometric effects are distinctly traceable to Iceland and Nova
+Zembla, and the tropical driftwood which it carries affords the
+principal timber supply of the inhabitants of the first-named isle.
+Attaining this circumpolar realm, and finally losing the impulse which
+bore it on, the water of the Gulf Stream partly returns to the
+southward in a relatively slight current which bears the fluid along
+the coast of Europe until it re-enters the system of tropical winds
+and the currents which they produce. A larger portion stagnates in the
+circumpolar region, in time slowly to return to the tropical district
+in a manner afterward to be described. Although the Gulf Stream in the
+region north of Cape Hatteras is so indistinct that its presence was
+not distinctly recognised until the facts were subjected to the keen
+eye of Benjamin Franklin, its effects in the way of climate are so
+great that <span class='pagenum'><a name="Page_150" id="Page_150">[Pg 150]</a></span>we must attribute the fitness of northern Europe for the
+uses of civilized man to its action. But for the heat which this
+stream brings to the realm of the North Atlantic, Great Britain would
+be as sterile as Labrador, and the Scandinavian region, the
+cradle-land of our race, as uninhabitable as the bleakest parts of
+Siberia.</p>
+
+<p>It is a noteworthy fact that when the equatorial current divides on
+the continents against which it flows, the separate streams, although
+they may follow the shores for a certain distance toward the poles,
+soon diverge from them, just as the Gulf Stream passes to the seaward
+from the eastern coast of the United States. The reason for this
+movement is readily found in the same principle which explains the
+oblique flow of the trades and counter trades in their passage to and
+from the equatorial belt. The particle of water under the equator,
+though it flows to the west, has, by virtue of the earth's rotation,
+an eastward-setting velocity of a thousand miles an hour. Starting
+toward the poles, the particle is ever coming into regions of the sea
+where the fluid has a less easterly movement, due to the earth's
+rotation on its axis. Consequently the journeying water by its
+momentum tends to move off in an easterly course. Attaining high
+latitudes and losing its momentum, it abides in the realm long enough
+to become cooled.</p>
+
+<p>We have already noted the fact that only a portion of the waters sent
+northward in the Gulf Stream and the other currents which flow from
+the equator to the poles is returned by the surface flow which sets
+toward the equator along the eastern side of the basins. The largest
+share of the tide effects its return journey in other ways. Some
+portion of this remainder sets equatorward in local cold streams, such
+as that which pours forth through Davis Strait into Baffin Bay,
+flowing under the Gulf Stream waters for an unknown distance toward
+the tropics. There are several of these local as yet little known
+streams, which doubtless bring about a certain amount of circula<span class='pagenum'><a name="Page_151" id="Page_151">[Pg 151]</a></span>tion
+between the polar regions and the tropical districts. Their effect is,
+however, probably small as compared with that massive drift which we
+have now to note.</p>
+
+<p>The tropical waters when they attain high latitudes are constantly
+cooled, and are overlaid by the warmer contributions of that tide, and
+are thus brought lower and lower in the sea. When they start downward
+they have, as observations show, a temperature not much above the
+freezing point of salt water. They do not congeal for the reason that
+the salt of the ocean lowers the point at which the water solidifies
+to near 28&deg; Fahr. The effect of this action is gradually to press down
+the surface cold water until it attains the very bottom in all the
+circumpolar regions. At the same time this descending water drifts
+along the bottom of the ocean troughs toward the equatorial realm. As
+this cold water is heavier than that which is of higher temperature
+and nearer the surface, it has no tendency to rise. Being below the
+disturbing influences of any current save its own, it does not tend,
+except in a very small measure, to mingle with the warmer overlying
+fluid. The result is that it continues its journey until it may come
+within the tropics without having gained a temperature of more than
+35&deg; Fahr., the increase in heat being due in small measure to that
+which it receives from the earth's interior and that which it acquires
+from the overlying warmer water. Attaining the region of the tropical
+current, this drift water from the poles gradually rises, to take the
+place of that which goes poleward, becomes warm, and again starts on
+its surface journey toward the arctic and antarctic regions.</p>
+
+<p>Nothing is known as to the rate of this bottom drift from the polar
+districts toward the equator, but, from some computation which he has
+made, the writer is of the opinion that several centuries is doubtless
+required for the journey from the Arctic Circle to the tropics. The
+speed of the movement probably varies; it may at times require some
+thousand years for its accomplishment. The effect of the <span class='pagenum'><a name="Page_152" id="Page_152">[Pg 152]</a></span>bottom drift
+is to withdraw from seas in high latitudes the very cold water which
+there forms, and to convey it beneath the seas of middle latitudes to
+a realm where it is well placed for the reheating process. If all the
+cold water of circumpolar regions had to journey over the surface to
+the equator, the perturbing effect of its flow on the climates of
+various lands would be far greater than it is at present. Where such
+cold currents exist the effect is to chill the air without adding much
+to the rainfall; while the currents setting northward not only warm
+the regions near which they flow, but by so doing send from the water
+surfaces large quantities of moisture which fall as snow or rain. Thus
+the Gulf Stream, directly and indirectly, probably contributes more
+than half the rainfall about the Atlantic basin. The lack of this
+influence on the northern part of North America and Asia causes those
+lands to be sterilized by cold, although destitute of permanent ice
+and snow upon their surfaces.</p>
+
+<p>We readily perceive that the effect of the oceanic circulation upon
+the temperatures of different regions is not only great but widely
+contrasted. By taking from the equatorial belt a large part of the
+heat which falls within that realm, it lowers the temperature to the
+point which makes the district fit for the occupancy of man, perhaps,
+indeed, tenable to all the higher forms of life. This same heat
+removed to high latitudes tempers the winter's cold, and thus makes a
+vast realm inhabitable which otherwise would be locked in almost
+enduring frosts. Furthermore, this distribution of temperatures tends
+to reduce the total wind energy by diminishing the trades and counter
+trades which are due to the variations of heat which are encountered
+in passing polarward from the equator. Still further, but for this
+circulation of water in the sea, the oceans about the poles would be
+frozen to their very bottom, and this vast sheet of ice might be
+extended southward to within the parallels of fifty degrees north and
+south latitude, although the waters under the equator might at the
+<span class='pagenum'><a name="Page_153" id="Page_153">[Pg 153]</a></span>same time be unendurably hot and unfit for the occupancy of living
+beings.</p>
+
+<p>A large part of the difficulties which geologists encounter in
+endeavouring to account for the changes of the past arise from the
+evidences of great climatal revolutions which the earth has undergone.
+In some chapters of the great stone book, whose leaves are the strata
+of the earth, we find it plainly written in the impressions made by
+fossils that all the lands beyond the equatorial belt have undergone
+changes which can only be explained by the supposition that the heat
+and moisture of the countries have been subjected to sudden and
+remarkable changes. Thus in relatively recent times thick-leaved
+plants which retained their vegetation in a rather tender state
+throughout the year have flourished near to the poles, while shortly
+afterward an ice sheet, such as now covers the greater part of
+Greenland, extended down to the line of the Ohio River at Cincinnati.
+Although these changes of climate are, as we shall hereafter note,
+probably due to entangled causes, we must look upon the modifications
+of the ocean streams as one of the most important elements in the
+causation. We can the more readily imagine such changes to be due to
+the alterations in the course and volume of the ocean current when we
+note how trifling peculiarities in the geography of the
+shores&mdash;features which are likely to be altered by the endless changes
+which occur in the form of a continent&mdash;affect the run of these
+currents. Thus the growth of coral reefs in southern Florida, and, in
+general, the formation of that peninsula, by narrowing the exit of the
+great current from the Gulf of Mexico, has probably increased its
+velocity. If Florida should again sink down, that current would go
+forth into the North Atlantic with the speed of about a mile an hour,
+and would not have momentum enough to carry its waters over half the
+vast region which they now traverse. If the lands about the western
+border of the Caribbean Sea, particularly the Isthmus of Darien,
+should be depressed to a consider<span class='pagenum'><a name="Page_154" id="Page_154">[Pg 154]</a></span>able depth below the ocean level,
+the tropical current would enter the Pacific Ocean, adding to the
+temperature of its waters all the precious heat which now vitalizes
+the North Atlantic region. Such a geographic accident would not only
+profoundly alter the life conditions of that part of the world, but it
+would make an end of European civilization.</p>
+
+<p>In the chapter on climatal changes further attention will be given to
+the action of ocean currents from the point of view of their influence
+on the heat and moisture of different parts of the world. We now have
+to consider the last important influence of ocean currents&mdash;that which
+they directly exercise on the development of organic life. The most
+striking effect of this nature which the sea streams bring about is
+caused by the ceaseless transportation to which they subject the eggs
+and seeds of animals and plants, as well as the bodies of the mature
+form which are moved about by the flowing waters. But for the
+existence of these north and south flowing currents, due to the
+presence of the continental barriers, the living tenants of the seas
+would be borne along around the earth, always in the same latitude,
+and therefore exposed to the same conditions of temperature. In this
+state of affairs the influences which now make for change in organic
+species would be far less than they are. Journeying in the great
+whirlpools which the continental barriers make out of the westward
+setting tropical currents, these organic species are ever being
+exposed to alterations in their temperature conditions which we know
+to be favourable to the creation of those variations on which the
+advance of organic life so intimately depends. Thus the ocean currents
+not only help to vary the earth by producing changes in the climate of
+both sea and land, breaking up the uniformity which would otherwise
+characterize regions at the same distance from the equator, but they
+induce, by the consequences of the migrations which they enforce,
+changes in the organic tenants of the sea.</p>
+
+<p><span class='pagenum'><a name="Page_155" id="Page_155">[Pg 155]</a></span></p><p>Another immediate effect of ocean streams arises where their currents
+of warm water come against shores or shallows of the sea. At these
+points, if the water have a tropical temperature, we invariably find a
+vast and rapid development of marine animals and plants, of which the
+coral-making polyps are the most important. In such positions the
+growth of forms which secrete solid skeletons is so rapid that great
+walls of their remains accumulate next the shore, the mass being built
+outwardly by successive growths until the realm of the land may be
+extended for scores of miles into the deep. In other cases vast mounds
+of this organic <i>d&eacute;bris</i> may be accumulated in mid ocean until its
+surface is interspersed with myriads of islands, all of which mark the
+work due to the combined action of currents and the marine life which
+they nourish. Probably more than four fifths of all the islands in the
+tropical belt are due in this way to the life-sustaining action of the
+currents which the trade winds create.</p>
+
+<p>There are many secondary influences of a less important nature which
+are due to the ocean streams. The reader will find on most wall-maps
+of the world certain areas in the central part of the oceans which are
+noted as Sargassum seas, of which that of the North Atlantic, west and
+south of the Azore Islands, is one of the most conspicuous. In these
+tracts, which in extent may almost be compared with the continents, we
+find great quantities of floating seaweed, the entangled fronds of
+which often form a mass sufficiently dense to slightly restrain the
+speed of ships. When the men on the caravels of Columbus entered this
+tangle, they were alarmed lest they should be unable to escape from
+its toils. It is a curious fact that these weeds of the sea while
+floating do not reproduce by spores the structures which answer to the
+seeds of higher plants, but grow only by budding. It seems certain
+that they could not maintain their place in the ocean but for the
+action of the currents which convey the bits rent off from the shores
+where the plant is truly at home. This vast <span class='pagenum'><a name="Page_156" id="Page_156">[Pg 156]</a></span>growth of plant life in
+the Sargassum basins doubtless contributed considerable and important
+deposits of sediment to the sea floors beneath the waters which it
+inhabits. Certain ancient strata, known as the Devonian black shale,
+occupying the Ohio valley and the neighbouring parts of North America
+to the east and north of that basin, appear to be accumulations which
+were made beneath an ancient Sargassum sea.</p>
+
+<p>The ocean currents have greatly favoured and in many instances
+determined the migrations not only of marine forms, but of land
+creatures as well. Floating timber may bear the eggs and seeds of many
+forms of life to great distances until the rafts are cast ashore in a
+realm where, if the conditions favour, the creatures may find a new
+seat for their life. Seeds of plants incased in their often dense
+envelopes may, because they float, be independently carried great
+distances. So it comes about that no sooner does a coral or other
+island rise above the waters of the sea than it becomes occupied by a
+varied array of plants. The migrations of people, even down to the
+time of the voyages which discovered America, have in large measure
+been controlled by the run of the ocean streams. The tropical set of
+the waters to the westward helped Columbus on his way, and enabled him
+to make a journey which but for their assistance could hardly have
+been accomplished. This same current in the northern part of the Gulf
+Stream opposed the passage of ships from northern Europe to the
+westward, and to this day affects the speed with which their voyages
+are made.</p>
+
+
+<h2 class="subtitle smcap">The Circuit of the Rain.</h2>
+
+<p>We have now to consider those movements of the water which depend upon
+the fact that at ordinary temperatures the sea yields to the air a
+continued and large supply of vapour, a contribution which is made in
+lessened proportion by water in all stages of coldness, and even by
+ice <span class='pagenum'><a name="Page_157" id="Page_157">[Pg 157]</a></span>when it is exposed to dry air. This evaporation of the sea water
+is proportional to the temperature and to the dryness of the air where
+it rests upon the ocean. It probably amounts on the average to
+somewhere about three feet per annum; in regions favourably situated
+for the process, as on the west coast of northern Africa, it may be
+three or four times as much, while in the cold and humid air about the
+poles it may be as little as one foot. When contributed to the air,
+the water enters on the state of vapour, in which state it tends to
+diffuse itself freely through the atmosphere by virtue of the motion
+which is developed in particles when in the vaporous or gaseous state.</p>
+
+<p>The greater part of the water evaporated from the seas probably finds
+its way as rain at once back into the deep, yet a considerable portion
+is borne away horizontally until it encounters the land. The
+precipitation of the water from the air is primarily due to the
+cooling to which it is subjected as it rises in the atmosphere. Over
+the sea the ascent is accomplished by the simple diffusion of the
+vapour or by the uprise through the a&euml;rial shaft, such as that near
+the equator or over the centres of the whirling storms. It is when the
+air strikes the slopes of the land that we find it brought into a
+condition which most decidedly tends to precipitate its moisture.
+Lifted upward, the air as it ascends the slopes is brought into cooler
+and more rarefied conditions. Losing temperature and expanding, it
+parts with its water for the same reason that it does in the ascending
+current in the equatorial belt or in the chimneys of the whirl storms.
+A general consequence of this is that wherever moisture-laden winds
+from the sea impinge upon a continent they lay down a considerable
+part of the water which they contain.</p>
+
+<p>If all the lands were of the same height, the rain would generally
+come in largest proportion upon their coastal belt, or those portions
+of the shore-line districts over which the sea winds swept. But as
+these winds vary in the <span class='pagenum'><a name="Page_158" id="Page_158">[Pg 158]</a></span>amount of the watery vapour which they
+contain, and as the surface of the land is very irregular, the
+rainfall is the most variable feature in the climatal conditions of
+our sphere. Near the coasts it ranges from two or three inches in arid
+regions&mdash;such as the western part of the Sahara and portions of the
+coast regions of Chili and Peru&mdash;to eight hundred inches about the
+head waters of the Brahmapootra River in northern India, where the
+high mountains are swept over by the moisture-laden airs from the
+neighbouring sea. Here and there detached mountainous masses produce a
+singular local increase in the amount of the rainfall. Thus in the
+lake district in northwestern England the rainfall on the seaward side
+of mountains, not over four thousand feet high, is very much greater
+than it is on the other slope, less than a score of miles away. These
+local variations are common all over the world, though they are but
+little observed.</p>
+
+<p>In general, the central parts of continents are likely to receive much
+less rainfall than their peripheral portions. Thus the central
+districts of North America, Asia, and Australia&mdash;three out of the five
+continental masses&mdash;have what we may call interior deserts. Africa has
+one such, though it is north of the centre, and extends to the shores
+of the Mediterranean and the Atlantic. The only continent without this
+central nearly rainless field is South America, where the sole
+characteristic arid district is situated on the western slope of the
+Cordilleran range. In this case the peculiarity is due to the fact
+that the strong westerly setting winds which sweep over the country
+encounter no high mountains until they strike the Andean chain. They
+journey up a long and rather gradual slope, where the precipitation is
+gradually induced, the process being completed when they strike the
+mountain wall. Passing over its summit, they appear as dry winds on
+the Pacific coast.</p>
+
+<p>Even while the winds frequently blow in from the sea, as along the
+western coast of the Americas, they may come <span class='pagenum'><a name="Page_159" id="Page_159">[Pg 159]</a></span>over water which is
+prevailingly colder than the land. This is characteristically the case
+on the western faces of the American continent, where the sea is
+cooled by the currents setting toward the equator from high latitudes.
+Such cool sea air encountering the warm land has its temperature
+raised, and therefore does not tend to lay down its burden of
+moisture, but seeks to take up more. On this account the rainfall in
+countries placed under such conditions is commonly small.</p>
+
+<p>By no means all the moisture which comes upon the earth from the
+atmosphere descends in the form of rain or snow. A variable, large,
+though yet undetermined amount falls in the form of dew. Dew is a
+precipitation of moisture which has not entered the peculiar state
+which we term fog or cloud, but has remained invisible in the air. It
+is brought to the earth through the radiation of heat which
+continually takes place, but which is most effective during the
+darkened half of the day, when the action is not counterbalanced by
+the sun's rays. While the sun is high and the air is warm there is a
+constant absorption of moisture in large part from the ground or from
+the neighbouring water areas, probably in some part from those
+suspended stores of water, the clouds, if such there be in the
+neighbourhood. We can readily notice how clouds drifting in from the
+sea often melt into the dry air which they encounter. Late in the
+afternoon, even before the sun has sunk, the radiation of heat from
+the earth, which has been going on all the while, but has been less
+considerable than the incurrent of temperature, in a way overtakes
+that influx. The air next the surface becomes cooled from its contact
+with the refrigerating earth, and parts with its moisture, forming a
+coating of water over everything it touches. At the same time the
+moisture escaping from the warmed under earth likewise drops back upon
+its cooled surface almost as soon as it has escaped. The thin sheet of
+water precipitated by this method is quickly returned to the air when
+it becomes <span class='pagenum'><a name="Page_160" id="Page_160">[Pg 160]</a></span>warmed by the morning sunshine, but during the night
+quantities of it are absorbed by the plants; very often, indeed, with
+the lowlier vegetation it trickles down the leaves and enters the
+earth about the base of the stem, so that the roots may appropriate
+it. Our maize, or Indian corn, affords an excellent example of a plant
+which, having developed in a land of droughts, is well contrived,
+through its capacities for gathering dew, to protect itself against
+arid conditions. In an ordinary dew-making night the leaves of a
+single stem may gather as much as half a pint of water, which flows
+down their surfaces to the roots. So efficient is this dew supply,
+this nocturnal cloudless rain, that on the western coast of South
+America and elsewhere, where the ordinary supply of moisture is almost
+wanting, many important plants are able to obtain from it much of the
+water which they need. The effect is particularly striking along
+seashores, where the air, although it may not have the humidity
+necessary for the formation of rain, still contains enough to form
+dew.</p>
+
+<p>It is interesting to note that the quantity of dew which falls upon an
+area is generally proportioned to the amount of living vegetation
+which it bears. The surfaces of leaves are very efficient agents of
+radiation, and the tangle which they make offers an amount of
+heat-radiating area many times as great as that afforded by a surface
+of bared earth. Moreover, the ground itself can not well cool down to
+the point where it will wring the moisture out of the air, while the
+thin membranes of the plants readily become so cooled. Thus vegetation
+by its own structure provides itself with means whereby it may be in a
+measure independent of the accidental rainfall. We should also note
+the fact that the dewfall is a concomitant of cloudless skies. The
+quantity which is precipitated in a cloudy night is very small, and
+this for the reason that when the heavens are covered the heat from
+the earth can not readily fly off into space. Under these conditions
+the temperature of the air rarely descends low enough to favour the
+precipitation of dew.</p>
+
+<p><span class='pagenum'><a name="Page_161" id="Page_161">[Pg 161]</a></span></p><p>Having noted the process by which in the rain circuit the water
+leaves the sea and the conditions of distribution when it returns to
+the earth, we may now trace in more detail the steps in this great
+round. First, we should take note of the fact that the water after it
+enters the air may come back to the surface of the earth in either of
+two ways&mdash;directly in the manner of dewfall, or in a longer circuit
+which leads it through the state of clouds. As yet we are not very
+well informed as to the law of the cloud-making, but certain features
+in this picturesque and most important process have been tolerably
+well ascertained.</p>
+
+<p>Rising upward from the sea, the vapour of water commonly remains
+transparent and invisible until it attains a considerable height above
+the surface, where the cooling tends to make it assume again the
+visible state of cloud particles. The formation of these cloud
+particles is now believed to depend on the fact that the air is full
+of small dust motes, exceedingly small bits of matter derived from the
+many actions which tend to bring comminuted solid matter into the air,
+as, for instance, the combustion of meteoric stones, which are greatly
+heated by friction in their swift course through the air, the
+ejections of volcanoes, the smoke of forest and other fires, etc.
+These tiny bits, floating in the air, because of their solid nature
+radiate their heat, cool the air which lies against them, and thereby
+precipitate the water in the manner of dew, exactly as do the leaves
+and other structures on the surface of the earth. In fact, dew
+formation is essentially like cloud formation, except that in the one
+case the water is gathered on fixed bodies, and in the other on
+floating objects. Each little dust raft with its cargo of condensed
+water tends, of course, to fall downward toward the earth's surface,
+and, except for the winds which may blow upward, does so fall, though
+with exceeding slowness. Its rate of descent may be only a few feet a
+day. It was falling before it took on the load of water; it will fall
+a little more rapidly <span class='pagenum'><a name="Page_162" id="Page_162">[Pg 162]</a></span>with the added burden, but even in a still air
+it might be months or years before it would come to the ground. The
+reason for this slow descent may not at first sight be plain, though a
+little consideration will make it so.</p>
+
+<p>If we take a shot of small size and a feather of the same weight, we
+readily note that their rate of falling through the air may vary in
+the proportion of ten to one or more. It is easy to conceive that this
+difference is due to the very much less friction which the smaller
+body encounters in its motion by the particles of air. With this point
+in mind, the student should observe that the surface presented by
+solid bodies in relation to their solid contents is the greater the
+smaller the diameter. A rough, though not very satisfactory, instance
+of this principle may be had by comparing the surface and interior
+contents of two boxes, one ten feet square and the other one foot
+square. The larger has six hundred feet of surface to one thousand
+cubic feet of interior, or about half a square foot of outer surface
+to the cubic foot of contents; while the smaller box has six feet of
+surface for the single cubic foot of interior, or about ten times the
+proportion of exterior to contents. The result is that the smaller
+particles encounter more friction in moving toward the earth, until,
+in the case of finely divided matter, such as the particles of carbon
+in the smoke from an ordinary fire, the rate of down-falling may be so
+small as to have little effect in the turbulent conditions of
+atmospheric motion.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a name="img06"></a>
+<img src="images/p6.jpg" width="640" height="410" alt="Pocket Creek, Cape Ann, Massachusetts. Note the
+relatively even size of the pebbles, and the splash wave which sets
+them in motion." title="" />
+<span class="caption">Pocket Creek, Cape Ann, Massachusetts. Note the
+relatively even size of the pebbles, and the splash wave which sets
+them in motion.</span>
+</div>
+
+<p>The little drops of water which gather round dust motes, falling but
+slowly toward the earth, are free to obey the attractions which they
+exercise upon each other&mdash;impulses which are partly gravitative and
+partly electrical. We have no precise knowledge concerning these
+movements, further than that they serve to aggregate the myriad little
+floats into cloud forms, in which the rafts are brought near together,
+but do not actually touch each other. They are possibly kept apart by
+electrical repulsion. In this state of association without union the
+divided water may under<span class='pagenum'><a name="Page_163" id="Page_163">[Pg 163]</a></span>go the curiously modified aggregations which
+give us the varied forms of clouds. As yet we know little as to the
+cause of cloud shapes. We remark the fact that in the higher of these
+agglomerations of condensed vapour, the clouds which float at an
+elevation of from twenty to thirty thousand feet or more, the masses
+are generally thin, and arranged more or less in a leaflike form,
+though even here a tendency to produce spherical clouds is apparent.
+In this high realm floating water is probably in the frozen state,
+answering to the form of dew, which we call hoar frost. The lower
+clouds, gathering in the still air, show very plainly the tendency to
+agglomerate into spheres, which appears to be characteristic of all
+vaporous material which is free to move by its own impulses. It is
+probable that the spherical shape of clouds is more or less due to the
+same conditions as gathered the stellar matter from the ancient
+nebular chaos into the celestial spheres. Upon these spherical
+aggregations of the clouds the winds act in extremely varied ways. The
+cloud may be rubbed between opposite currents, and so flattened out
+into a long streamer; it may take the same form by being carried off
+by a current in the manner of smoke from a fire; the spheres may be
+kept together, so as to form the patchwork which we call "mackerel"
+sky; or they may be actually confounded with each other in a vast
+common cloud-heap. In general, where the process of aggregation of two
+cloud bodies occurs, changes of temperature are induced in the masses
+which are mixed together. If the temperature resulting from this
+association of cloud masses is an average increase, the cloud may
+become lighter, and in the manner of a balloon move upward. Each of
+the motes in the cloud with its charge of vapour may be compared with
+the ballast of the balloon; if they are warmed, they send forth a part
+of their load of condensed water again to the state of invisible
+vapour. Rising to a point where it cools, the vapour gathers back on
+the rafts and tends again to weight the cloud downward. The ballast of
+an ordinary <span class='pagenum'><a name="Page_164" id="Page_164">[Pg 164]</a></span>balloon has to be thrown away from its car; but if some
+arrangement for condensing the moisture from the air could be
+contrived, a balloon might be brought into the adjustable state of a
+cloud, going up or down according as it was heated or cooled.</p>
+
+<p>When the formation of the drop of water or snowflake begins, the mass
+is very small. If in descending it encounters great thickness of
+cloud, the bit may grow by further condensation until it becomes
+relatively large. Generally in this way we may account for the
+diversities in the size of raindrops or snowflakes. It often happens
+that the particles after taking on the form of snowflakes encounter in
+their descent air so warm that they melt into raindrops, or, if only
+partly melted, reach the surface as sleet. Or, starting as raindrops,
+they may freeze, and in this simple state may reach the earth, or
+after freezing they may gather other frozen water about them, so that
+the hailstone has a complicated structure which, from the point of
+view of classification, is between a raindrop and a snowflake.</p>
+
+<p>In the process of condensation&mdash;indeed, in the steps which precede the
+formation of rain and snow&mdash;there is often more or less trace of
+electrical action; in fact, a part of the energy which was involved in
+the vapourization of water, on its condensation, even on the dust
+motes appears to be converted into electrical action, which probably
+operates in part to keep the little aggregates of water asunder. When
+they coalesce in drops or flakes, this electricity often assumes the
+form of lightning, which represents the swift passage of the electric
+store from a region where it is most abundant to one where it is less
+so. The variations in this process of conveying the electricity are
+probably great. In general, it probably passes, much as an electric
+current is conveyed, through a wire from the battery which produces
+the force. In other cases, where the tension is high, or, in other
+words, where the discharge has to be hastened, we have the phenomena
+of lightning <span class='pagenum'><a name="Page_165" id="Page_165">[Pg 165]</a></span>in which the current burns its way along its path, as it
+may traverse a slender wire, vapourizing it as it goes. In general,
+the lightning flash expends its force on the air conductors, or lines
+of the moist atmosphere along which it breaks its path, its energy
+returning into the vapour which it forms or the heat which it produces
+in the other parts of the air. In some cases, probably not one in the
+thousand of the flashes, the charge is so heavy that it is not used up
+in its descent toward the earth, and so electrifies, or, as we say,
+strikes, some object attached to the earth, through which it passes to
+the underlying moisture, where it finds a convenient place to take on
+a quiet form. Almost all these hurried movements of electrical energy
+which intensely heat and light the air which they traverse fly from
+one part of a cloud to another, or cross from cloud sphere to cloud
+sphere; of those which start toward the earth, many are exhausted
+before they reach its surface, and even those that strike convey but a
+portion of their original impulse to the ground.</p>
+
+<p>The wearing-out effect of lightning in its journey along the air
+conductors in its flaming passages is well illustrated by what happens
+when the charge strikes a wire which is not large enough freely to
+convey it. The wire is heated, generally made white hot, often melted,
+and perhaps scattered in the form of vapour. In doing this work the
+electricity may, and often is, utterly dissipated&mdash;that is, changed
+into heat. It has been proposed to take advantage of this principle in
+protecting buildings from lightning by placing in them many thin
+wires, along which the current will try to make its way, being
+exhausted in melting or vaporizing the metal through which it passes.</p>
+
+<p>There are certain other forms of lightning, or at least of electrical
+discharges, which produce light and which may best be described in
+this connection. It occasionally happens that the earth becomes so
+charged that the current proceeds from its surface to the clouds. More
+rarely, and <span class='pagenum'><a name="Page_166" id="Page_166">[Pg 166]</a></span>under conditions which we do not understand, the electric
+energy is gathered into a ball-like form, which may move slowly along
+the surface until it suddenly explodes. It is a common feature of all
+these forms of lightning which we have noted that they ordinarily make
+in their movement considerable noise. This is due to the sudden
+displacement of the air which they traverse&mdash;displacement due to the
+action of heat in separating the particles. It is in all essential
+regards similar to the sounds made by projectiles, such as meteors or
+swift cannon shots, as they fly through the air. It is even more
+comparable to the sound produced by exploding gunpowder. The first
+sound effect from the lightning stroke is a single rending note, which
+endures no longer&mdash;indeed, not as long&mdash;as the explosion of a cannon.
+Heard near by, this note is very sharp, reminding one of the sound
+made by the breaking of glass. The rolling, continuous sound which we
+commonly hear in thunder is, as in the case of the noise produced by
+cannon, due to echo from the clouds and the earth. Thunder is
+ordinarily much more prolonged and impressive in a mountainous country
+than in a region of plains, because the steeps about the hearer
+reverberate the original single crash.</p>
+
+<p>The distribution of thunderstorms is as yet not well understood, but
+it appears in many cases that they are attendants on the advancing
+face of cyclones and hurricanes, the area in front of these great
+whirlstorms being subjected to the condensation and irregular air
+movements which lead to the development of much electrical energy.
+There are, however, certain parts of the earth which are particularly
+subjected to lightning flashes. They are common in the region near the
+equator, where the ascending currents bring about heavy rains, which
+mean a rapid condensation and consequent liberation of electrical
+energy. They diminish in frequency toward the arctic regions. An
+observer at the pole would probably fail ever to perceive strong
+flashes. For the same reason thunder<span class='pagenum'><a name="Page_167" id="Page_167">[Pg 167]</a></span>storms are more frequent in
+summer, the time when the difference in temperature between the
+surface and the upper air is greatest, when, therefore, the uprushes
+of air are likely to be most violent. They appear to be more common in
+the night than in the daytime, for the reason that condensation is
+favoured by the cooling which occurs in the dark half of the day. It
+is rare, indeed, that a thunderstorm occurs near midday, a period when
+the air is in most cases taking up moisture on account of the swiftly
+increasing heat.</p>
+
+<p>There are other forms of electrical discharges not distinctly
+connected with the then existing condensation of moisture. What the
+sailors call St. Elmo's fire&mdash;a brush of electric light from the mast
+tops and other projections of the ship&mdash;indicates the passage of
+electrical energy between the vessel and the atmosphere. Similar
+lights are said sometimes to be seen rising from the surface of the
+water. Such phenomena are at present not satisfactorily explained.
+Perhaps in the same group of actions comes the so-called
+"Jack-o'-lantern" or "Will-o'-the-wisp" fires flashing from the earth
+in marshy places, which are often described by the common people, but
+have never been observed by a naturalist. If this class of
+illuminations really exists, we have to afford them some other
+explanation than that they are emanations of self-inflamed
+phosphoretted hydrogen, a method of accounting for them which
+illogically finds a place in many treatises on atmospheric phenomena.
+A gas of any kind would disperse itself in the air; it could not dance
+about as these lights are said to do, and there is no chemical means
+known whereby it could be produced in sufficient purity and quantity
+from the earth to produce the effects which are described.<a name="FNanchor_3_3" id="FNanchor_3_3"></a><a href="#Footnote_3_3" class="fnanchor">[3]</a></p>
+
+
+<p><span class='pagenum'><a name="Page_168" id="Page_168">[Pg 168]</a></span></p><p>In the upper air, or perhaps even beyond the limits of the field
+which deserves the name, in the regions extending from the poles to
+near the tropics, there occur electric glowings commonly known as the
+aurora borealis. This phenomenon occurs in both hemispheres. These
+illuminations, though in some way akin to those of lightning, and
+though doubtless due to some form of electrical action, are peculiar
+in that they are often attended by glows as if from clouds, and by
+pulsations which indicate movements not at electric speed. As yet but
+little is known as to the precise nature of these curious storms. It
+has been claimed, however, that they are related to the sun spots;
+those periods when the solar spots are plenty, at intervals of about
+eleven years, are the times of auroral discharges. Still further, it
+seems probable that the magnetic currents of the earth, that circling
+energy which encompasses the sphere, moving round in a general way
+parallel to the equator, are intensified during these illuminations of
+the circumpolar skies.</p>
+
+
+<h2 class="subtitle smcap">Geological Work of Water.</h2>
+
+<p>We turn now to the geological work which is performed by falling
+water. Where the rain or snow returns from the clouds to the sea, the
+energy of position given to the water by its elevation above the earth
+through the heat which it acquired from the sun is returned to the air
+through which it falls or to the ocean surface on which it strikes. In
+this case the circuit of the rain is short and <span class='pagenum'><a name="Page_169" id="Page_169">[Pg 169]</a></span>without geological
+consequence which it is worth while to consider, except to note that
+the heat thus returned is likely to be delivered in another realm than
+that in which the falling water acquired the store, thus in a small
+way modifying the climate. When, however, the precipitation occurs on
+the surface of the land, the drops of frozen or fluid water apply a
+part of their energy in important geological work, the like of which
+is not done where they return at once to the sea.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f10.jpg" width="640" height="285" alt="Fig. 10.&mdash;Showing the diverse action of rain on wooded
+and cleared fields, a, wooded area; b, tilled ground." title="" />
+<span class="figcaption">Fig. 10.&mdash;Showing the diverse action of rain on wooded
+and cleared fields, a, wooded area; b, tilled ground.</span>
+</div>
+
+<p>We shall first consider what takes place when the water in the form of
+drops of rain comes to the surface of the land. Descending as they do
+with a considerable speed, these raindrops apply a certain amount of
+energy to the surface on which they fall. Although the beat of a
+raindrop is proverbially light, the stroke is not ineffective.
+Observing what happens where the action takes place on the surface of
+bare rock, we may notice that the grains of sand or small pebbles
+which generally abound on such surfaces, if they be not too steeply
+inclined, dance about under the blows which they receive. If we could
+cover hard plate glass, a much firmer material than ordinary stone,
+with such bits, we should soon find that its <span class='pagenum'><a name="Page_170" id="Page_170">[Pg 170]</a></span>surface would become
+scratched all over by the friction. Moreover, the raindrops
+perceptibly urge the small detached bits of stone down the slopes
+toward the streams.</p>
+
+<p>If all the earth's surface were bare rocks, the blow of the raindrops
+would deserve to be reckoned among the important influences which lead
+to the wearing of land. As it is, when a country is in a state of
+Nature, only a small part of its surface is exposed to this kind of
+wearing. Where there is rain enough to effect any damage, there is
+sure to be sufficient vegetation to interpose a living and
+self-renewed covering between the rocks and the rain. Even the lichens
+which coat what at first sight often seems to be bare rock afford an
+ample covering for this purpose. It is only where man bares the field
+by stripping away and overturning this protecting vegetation that the
+raindrops cut away the earth. The effect of their action can often be
+noted by observing how on ploughed ground a flat stone or a potsherd
+comes after a rain to cap a little column. The geologist sometimes
+finds in soft sandstones that the same action is repeated in a larger
+way where a thin fragment of hard rock has protected a column many
+feet in height against the rain work which has shorn down the
+surrounding rock.</p>
+
+<p>When water strikes the moistened surface it at once loses the droplike
+form which all fluids assume when they fall through the air.<a name="FNanchor_4_4" id="FNanchor_4_4"></a><a href="#Footnote_4_4" class="fnanchor">[4]</a></p>
+
+<p>When the raindrops coalesce on the surface of the earth, the r&ocirc;le of
+what we may call land water begins.<span class='pagenum'><a name="Page_171" id="Page_171">[Pg 171]</a></span> Thenceforward until the fluid
+arrives at the surface of the sea it is continually at work in
+effecting a great range of geological changes, only a few of which can
+well be traced by the general student. The work of land water is due
+to three classes of properties&mdash;to the energy with which it is endowed
+by virtue of its height above the sea, a power due to the heat of the
+sun; to the capacity it has for taking substances into solution; and
+to its property of giving some part of its own substance to other
+materials with which it comes in contact. The first of these groups of
+properties may be called dynamical; the others, chemical.</p>
+
+<p>The dynamic value of water when it falls upon the land is the amount
+of energy it can apply in going down the slope which separates it from
+the sea. A ton of the fluid, such as may gather in an ordinary rain on
+a thousand square feet of ground in the highlands of a country&mdash;say at
+an elevation of a thousand feet above the sea&mdash;expends before it comes
+to rest in the great reservoir as much energy as would be required to
+lift that weight from the ocean's surface to the same height. The ways
+in which this energy may be expended we shall now proceed in a general
+way to trace.</p>
+
+<p>As soon as the water has been gathered, from its drop to its sheet
+state&mdash;a process which takes place as soon as it falls&mdash;the fluid
+begins its downward journey. On this way it is at once parted into two
+distinct divisions, the surface water and the ground water: the former
+courses more or less swiftly, generally at the rate of a mile or more
+an hour, in the light of day; the latter enters the interstices of the
+earth, slowly descends therein to a greater or less depth, and
+finally, journeying perhaps at the rate of a mile a year, rejoins the
+surface water, escaping through the springs. The proportion of these
+two classes, the surface and the ground water, varies greatly, and an
+intermixture of them is continually going on. Thus on the surface of
+bare rock or frozen earth all the rain may go away without entering
+the ground. On very <span class='pagenum'><a name="Page_172" id="Page_172">[Pg 172]</a></span>sandy fields the heaviest rainfall may be taken
+up by the porous earth, so that no streams are found. On such surfaces
+the present writer has observed that a rainfall amounting to six
+inches in depth in two hours produced no streams whatever. We shall
+first follow the history of the surface water, afterward considering
+the work which the underground movements effect.</p>
+
+<p>If the student will observe what takes place on a level ploughed
+field&mdash;which, after all, will not be perfectly level, for all fields
+are more or less undulating&mdash;he will note that, though the surface may
+have been smoothed by a roller until it appears like a floor, the
+first rain, where the fall takes place rapidly enough to produce
+surface streams, will create a series of little channels which grow
+larger as they conjoin, the whole appearing to the eye like a very
+detailed map, or rather model, of a river system; it is, indeed, such
+a system in miniature. If he will watch the process by which these
+streamlet beds are carved, he will obtain a tolerably clear idea as to
+that most important work which the greater streams do in carving the
+face of the lands. The water is no sooner gathered into a sheet than,
+guided by the slightest irregularities which it encounters, it begins
+to flow. At first the motion is so slow that it does not disturb its
+bed, but at some points in the bottom of the sheet the movement soon
+becomes swift enough to drag the grains of sand and clay from their
+adhesions, bearing them onward. As soon as this beginning of a channel
+is formed the water moves more swiftly in the clearer way; it
+therefore cuts more rapidly, deepening and enlarging its channel, and
+making its motion yet more free. The tiny rills join the greater, all
+their channels sway to and fro as directed this way and that by chance
+irregularities, until something like river basins are carved out,
+those gentle slopes which form broad valleys where the carving has
+been due to the wanderings of many streams. If the field be large,
+considerable though temporary brooks may be created, which cut
+channels perhaps a foot in depth.<span class='pagenum'><a name="Page_173" id="Page_173">[Pg 173]</a></span> At the end of this miniature stream
+system we always find some part of the waste which has been carved
+out. If the streamlet discharges into a pool, we find the tiny
+representative of deltas, which form such an important feature on the
+coast line where large rivers enter seas or lakes. Along the lines of
+the stream we may observe here and there little benches, which are the
+equivalent in all save size of the terraces that are generally to be
+observed along the greater streams. In fact, these accidents of an
+acre help in a most effective way the student to understand the
+greater and more complicated processes of continental erosion.</p>
+
+<p>A normal river&mdash;in fact, all the greater streams of the
+earth&mdash;originates in high country, generally in a region of mountains.
+Here, because of the elevation of the region, the streams have cut
+deep gorges or extensive valleys, all of which have slopes leading
+steeply downward to torrent beds. Down these inclined surfaces the
+particles worn off from the hard rock by frost and by chemical decay
+gradually work their way until they attain the bed of the stream. The
+agents which assist gravitation in bearing this detritus downward are
+many, but they all work together for the same end. The stroke of the
+raindrop accomplishes something, though but little; the direct washing
+action of the brooklets which form during times of heavy rain, but dry
+out at the close of the storm, do a good deal of the work; thawing and
+freezing of the water contained in the mass of detritus help the
+movement, for, although the thrust is in both directions, it is most
+effective downhill; the wedges of tree roots, which often penetrate
+between and under the stones, and there expand in their process of
+growth, likewise assist the downward motion. The result is that on
+ordinary mountain slopes the layer of fragments constituting the rude
+soil is often creeping at the rate of from some inches to some feet a
+year toward the torrent bed. If there be cliffs at the top of the
+slope, as is often the case, very extensive falls of rock may take
+<span class='pagenum'><a name="Page_174" id="Page_174">[Pg 174]</a></span>place from it, the masses descending with such speed that they
+directly attain the stream. If the steeps be low and the rock divided
+into vertical joints, especially where there is a soft layer at the
+base of the steep, detached masses from the precipice may move slowly
+and steadfastly down the slope, so little disturbed in their journey
+that trees growing upon their summits may continue to develop for the
+thousands of years before the mass enters the stream bed.</p>
+
+<p>Although the fall of rocks from precipices does not often take place
+in a conspicuously large way, all great mountain regions which have
+long been inhabited by man abound in traditions and histories of such
+accidents. Within a century or two there have been a dozen or more
+catastrophes of this nature in the inhabited valleys of the Alps. As
+these accidents are at once instructive and picturesque, it is well to
+note certain of them in some detail. At Yvorgne, a little parish on
+the north shore of the Rh&ocirc;ne, just above the lake of Geneva, tradition
+tells that an ancient village of the name was overwhelmed by the fall
+of a great cliff. The vast <i>d&eacute;bris</i> forming the steep slope which was
+thus produced now bears famous vineyards, but the vintners fancy that
+they from time to time hear deep in the earth the ringing of the bells
+which belonged to the overwhelmed church. In 1806 the district of
+Goldau, just north of Lake Lucerne, was buried beneath the ruins of a
+peak which, resting upon a layer of clay, slipped away like a
+launching ship on the surface of the soft material. The <i>d&eacute;bris</i>
+overwhelmed a village and many detached houses, and partly filled a
+considerable lake. The wind produced by this vast rush of falling rock
+was so great that people were blown away by it; some, indeed, were
+killed in this singular manner.</p>
+
+<p>The most interesting field of these Swiss mountain falls is a high
+mountain valley of amphitheatrical form, known as the Diablerets, or
+the devil's own district. This great circus, which lies at the height
+of about four thousand feet above the sea, is walled around on its
+northern <span class='pagenum'><a name="Page_175" id="Page_175">[Pg 175]</a></span>side by a precipice, above which rest, or rather once
+rested, a number of mountain peaks of great bulk. The region has long
+been valued for the excellent pasturage which the head of the valley
+affords. Two costly roads, indeed, have been built into it to afford
+footpaths for the flocks and herds and their keepers in the summer
+season. Through this human experience with the valley, we have a
+record of what has gone on in this part of the mountain wilderness.
+Within the period of history and tradition, three very great mountain
+falls have occurred in this field, each having made its memory good by
+widespread disaster which it brought to the people of the <i>chalets</i>.
+The last of these was brought about by the fall of a great peak which
+spread itself out in a vast field of ruins in the valley below. The
+belt of destruction was about half a mile wide and three miles long.
+When the present writer last saw it, a quarter of a century ago, it
+was still a wilderness of great rocks, but here and there the process
+of their decay was giving a foothold for herbage, and in a few
+centuries the field will doubtless be so verdure-clad that its story
+will not be told on its face. It is likely, however, to be preserved
+in the memory of the people, and this through a singular and pathetic
+tradition which has grown up about the place, one which, if not true,
+comes at least among the legends which we should like to believe.</p>
+
+<p>As told the present writer by a native of the district, it happened
+when, in the nighttime the mountain came down, the herdsmen and their
+cows gathered in the <i>chalets</i>&mdash;stout buildings which are prepared to
+resist avalanches of snow. In one of these, which was protected from
+crushing by the position of the stones which covered it, a solitary
+herdsman found himself alive in his unharmed dwelling. With him in the
+darkness were the cows, a store of food and water, and his provisions
+for the long summer season. With nothing but hope to animate him, he
+set to work burrowing upward among the rocks, storing the <i>d&eacute;bris</i> in
+the room of the <i>chalet</i>. He toiled for some months, but <span class='pagenum'><a name="Page_176" id="Page_176">[Pg 176]</a></span>finally
+emerged to the light of day, blanched by his long imprisonment in the
+darkness, but with the strength to bear him to his home. In place of
+the expected warm welcome, the unhappy man found himself received as a
+ghost. He was exorcised by the priest and driven away to the distance.
+It was only when long afterward his path of escape was discovered that
+his history became known.</p>
+
+<p>Returning to the account of the <i>d&eacute;bris</i> which descends at varied
+speed into the torrents, we find that when the detritus encounters the
+action of these vigorous streams it is rapidly ground to pieces while
+it is pushed down the steep channels to the lower country. Where the
+stones are of such size that the stream can urge them on, they move
+rapidly; at least in times when the torrent is raging. They beat over
+each other and against the firm-set rocks; the more they wear, the
+smaller they become, and the more readily they are urged forward.
+Where the masses are too large to be stirred by the violent current,
+they lie unmoved until the pounding of the rolling stones reduces them
+to the proportions where they may join the great procession.
+Ordinarily those who visit mountains behold their torrents only in
+their shrunken state, when the waters stir no stones, and fail even to
+bear a charge of mud, all detachable materials having been swept away
+when the streams course with more vigour. In storm seasons the
+conditions are quite otherwise; then the swollen torrents, their
+waters filled with clay and sand, bear with them great quantities of
+boulders, the collisions of which are audible above the muffled roar
+of the waters, attesting the very great energy of the action.</p>
+
+<p>When the waste on a mountain slope lies at a steep angle, particularly
+where the accumulation is due to the action of ancient glaciers, it
+not infrequently happens that when the ground is softened with frost
+great masses of the material rush down the slope in the manner of
+landslides. The observer readily notes that in many mountain regions,
+as, for instance, in the White Mountains of New<span class='pagenum'><a name="Page_177" id="Page_177">[Pg 177]</a></span> Hampshire, the steep
+slopes are often seamed by the paths of these great landslides. Their
+movement, indeed, is often begun by sliding snow, which gives an
+impulse to the rocks and earth which it encounters in its descent. At
+a place known as the Wylie Notch, in the White Mountains, in the early
+part of this century, a family of that name was buried beneath a mass
+of glacial waste which had hung on the mountain slope from the ancient
+days until a heavy rain, following on a period of thaw, impelled the
+mass down the slope. Although there have been few such catastrophes
+noted in this country, it is because our mountains have not been much
+dwelt in. As they become thickly inhabited as the Alps are, men are
+sure to suffer from these accidents.</p>
+
+<p>As the volume of a mountain torrent increases through the junction of
+many tributaries, the energy of its moving waters becomes sufficient
+to sweep away the fragments which come to its bed. Before this stage
+is attained the stream rarely touches the solid under rock of the
+mountain, the base of the current resting upon the larger loose stones
+which it was unable to stir. In this pebble-paved section, because the
+stream could not attack the foundation rock, we find no gorges&mdash;in
+fact, the whole of this upper section of the torrent system is
+peculiarly conditioned by the fact that the streams are dealing not
+with bed-rock, but with boulders or smaller loose fragments. If they
+cut a little channel, the materials from either side slip the faster,
+and soon repave the bed. But when the streams have by a junction
+gained strength, and can keep their beds clear, they soon carve down a
+gorge through which they descend from the upper mountain realm to the
+larger valleys, where their conjoined waters take on a riverlike
+aspect. It should be noted here that the cutting power of the water
+moving in the torrent or in the wave, the capacity it has for abrading
+rock, resides altogether in the bits of stone or cutting tools with
+which it is armed. Pure water, because of its fluidity, may move over
+or against <span class='pagenum'><a name="Page_178" id="Page_178">[Pg 178]</a></span>firm-set stones for ages without wearing them; but in
+proportion as it moves rocky particles of any size, the larger they
+are, the more effective the work, it wears the rock over which it
+flows. A capital instance of this may be found where a stream from a
+hose is used in washing windows. If the water be pure, there is no
+effect upon the glass; but if it be turbid, containing bits of sand,
+in a little while the surface will appear cloudy from the multitude of
+line scratches which the hard bits impelled by the water have
+inflicted upon it. A somewhat similar case occurs where the wind bears
+sand against window panes or a bottle which has long lain on the
+shore. The glass will soon be deeply carved by the action, assuming
+the appearance which we term "ground." This principle is made use of
+in the arts. Glass vessels or sheets are prepared for carving by
+pasting paper cut into figures on their surfaces. The material is then
+exposed to a jet of air or steam-impelling sand grains; in a short
+time all the surface which has not been protected by paper has its
+polish destroyed and is no longer translucent.</p>
+
+<p>The passage from the torrent to the river, though not in a
+geographical way distinct, is indicated to the observant eye by a
+simple feature&mdash;namely, the appearance of alluvial terraces, those
+more or less level heaps of water-borne <i>d&eacute;bris</i> which accumulate
+along the banks of rivers, which, indeed, constitute the difference
+between those streams and torrents. Where the mountain waters move
+swiftly, they manage to bear onward the waste which they receive. Even
+where the blocks of stone cling in the bed, it is only a short time
+before they are again set in motion or ground to pieces. If by chance
+the detritus accumulates rapidly, the slope is steepened and the work
+of the torrent made more efficient. As the torrent comes toward the
+base of the mountains, where it neither finds nor can create steep
+slopes over which to flow, its speed necessarily diminishes. With each
+reduction in this feature its carrying power very rapidly diminishes.
+Thus water flowing at the rate of ten <span class='pagenum'><a name="Page_179" id="Page_179">[Pg 179]</a></span>miles an hour can urge stones
+four times the mass that it can move when its speed is reduced to half
+that rate. The result is that on the lowlands, with their relatively
+gentle slopes, the combined torrents, despite the increase in the
+volume of the stream arising from their confluence, have to lay down a
+large part of their load of detritus.</p>
+
+<p>If we watch where a torrent enters a mountain river, we observe that
+the main stream in a way sorts over the waste contributed to it,
+bearing on only those portions which its rate of flow will permit it
+to carry, leaving the remainder to be built into the bank in the form
+of a rude terrace. This accumulation may not extend far below the
+point where the torrent which imported the <i>d&eacute;bris</i> joins the main
+stream; a little farther down, however, we are sure to find another
+such junction and a second accumulation of terrace material. As these
+contributions increase, the terrace accumulations soon become
+continuous, lying on one side or the other of the river, sometimes
+bordering both banks of the stream. In general, it can be said that so
+long as the rate of fall of the torrent exceeds one hundred feet to
+the mile it does not usually exhibit these shelves of detritus. Below
+that rate of descent they are apt to be formed. Much, however, depends
+upon the amount of detritus which the stream bears and the coarseness
+of it; moreover, where the water goes through a gorge in the manner of
+a flume with steep rocky sides, it can urge a larger amount before it
+than when it traverses a wide valley, through which it passes, it may
+be, in a winding way.</p>
+
+<p>At first sight it may seem rather a fine distinction to separate
+torrents from rivers by the presence or absence of terraces. As we
+follow down the stream, however, and study its action in relation to
+these terraces, and the peculiar history of the detritus of which they
+are composed, we perceive that these latter accumulations are very
+important features. Beginning at first with small and imperfect
+alluvial plains, the river, as it descends toward the sea, <span class='pagenum'><a name="Page_180" id="Page_180">[Pg 180]</a></span>gaining in
+store of water and in the amount of <i>d&eacute;bris</i> which comes with that
+water from the hills, while the rate of fall and consequent speed of
+the current are diminished, soon comes to a stage where it is engaged
+in an endless struggle with the terrace materials. In times of flood,
+the walls of the terraces compel the tide to flow over the tops of
+these accumulations. Owing to the relative thinness of the water
+beyond the bed, and to the growth of vegetation there, the current
+moves more slowly, and therefore lays down a considerable deposit of
+the silt and sand which it contains. This may result during a single
+flood in lifting the level of the terrace by some inches in height,
+still further serving to restrict the channel. Along the banks of the
+Mississippi and other large rivers the most of this detritus falls
+near the stream; a little of it penetrates to the farther side of the
+plains, which often have a width of ten miles or more. The result is
+that a broad elevation is constructed, a sort of natural mole or
+levee, in a measure damming the flood waters, which can now only enter
+the "back swamps" through the channels of the tributary streams. Each
+of these back swamps normally discharges into the main stream through
+a little river of its own, along the banks of which the natural levees
+do not develop.</p>
+
+<p>We have now to note a curious swinging movement of rivers which was
+first well observed by the skilful engineers of British India. This
+movement can best be illustrated by its effects. If on any river which
+winds through alluvial plains a jetty is so constructed as to deflect
+the stream at any point, the course which it follows will be altered
+during its subsequent flow, it may be, for the distance of hundreds of
+miles. It will be perceived that in its movements a river normally
+strikes first against one shore and then against the other. Its water
+in a general way moves as does a billiard ball when it flies from one
+cushion to another. It is true that in a torrent we have the same
+conditions of motion; but there the banks are either of hard rock or,
+if of detritus, they are continually moving <span class='pagenum'><a name="Page_181" id="Page_181">[Pg 181]</a></span>into the stream in the
+manner before described. In the case of the river, however, its points
+of collision are often on soft banks, which are readily undermined by
+the washing action of the stream. In the ordinary course of events,
+the river beginning, we may imagine, with a straight channel, had its
+current deflected by some obstacle, it may be even by the slight
+pressure of a tributary stream, is driven against one bank; thence it
+rebounds and strikes the other. At each point of impinge it cuts the
+alluvium away. It can bear on only a small portion of that which it
+thus obtains; the greater part of the material is deposited on the
+opposite side of the stream, but a little lower down, where it makes a
+shallow. On these shallows water-loving plants and even certain trees,
+such as the willows and poplars, find a foothold. When the stream
+rises, the sediment settles in this tangle, and soon extends the
+alluvial plain from the neighbouring bank, or in rarer cases the river
+comes to flow on either side of an island of its own construction. The
+natural result of this billiard-ball movement of the waters is that
+the path of the stream is sinuous. The less its rate of fall and the
+greater the amount of silt it obtains from its tributaries, the more
+winding its course becomes. This gain in those parts of the river's
+curvings where deposition tends to take place may be accelerated by
+tree-planting. Thus a skilful owner of a tract of land on the south
+bank of the Ohio River, by assiduously planting willow trees on the
+front of his property, gained in the course of thirty years more than
+an acre in the width of his arable land. When told by the present
+writer that he was robbing his neighbours on the other side of the
+stream, he claimed that their ignorance of the laws of river motion
+was sufficient evidence that they did not deserve to own land.</p>
+
+<p>In the primitive state of a country the water-loving plants,
+particularly the trees which flourish in excessively humid conditions,
+generally make a certain defence against these incursions of the
+streams. But when a river has <span class='pagenum'><a name="Page_182" id="Page_182">[Pg 182]</a></span>gained an opening in the bank it can,
+during a flood, extend its width often to the distance of hundreds of
+feet. During the inundations of the Mississippi the river may at times
+be seen to eat away acres of land in a single day along one of the
+outcurves of its banks. The undermined forests falling into the flood
+join the great procession of drift timber, composed of trees which
+have been similarly uprooted, which occupies the middle part of the
+stream. This driftwood belt often has a width of three or four hundred
+feet, the entangled stems and branches making it difficult for a boat
+to pass from one side of the river to the other.</p>
+
+<div class="figright" style="width: 356px;">
+<img src="images/f11.jpg" width="356" height="480" alt="Fig. 11.&mdash;Oxbows and cut-off. Showing the changes in
+the course of a river in its alluvial plain." title="" />
+<span class="figcaption">Fig. 11.&mdash;Oxbows and cut-off. Showing the changes in
+the course of a river in its alluvial plain.</span>
+</div>
+
+<p>When the curves of a river have been developed to a certain point (see
+Fig. 11), when they have attained what <span class='pagenum'><a name="Page_183" id="Page_183">[Pg 183]</a></span>is called the "oxbow" form, it
+often happens that the stream breaks through the isthmus which
+connects one of the peninsulas with the mainland. Where, as is not
+infrequently the case, the bend has a length of ten miles or more, the
+water just above and below the new-made opening is apt to differ in
+height by some feet. Plunging down the declivity, the stream, flowing
+with great velocity, soon enlarges the channel so that its whole tide
+may take the easier way. When this result is accomplished, the old
+curve is deserted, sand bars are formed across their mouths, which may
+gradually grow to broad alluvial plains, so that the long-surviving,
+crescent-shaped lake, the remnant of the river bed, may be seen far
+from the present course of the ever-changing stream. Gradually the
+accumulations of vegetable matter and the silt brought in by floods
+efface this moat or oxbow cut-off, as it is so commonly termed.</p>
+
+<p>As soon as the river breaks through the neck of a peninsula in the
+manner above described, the current of the stream becomes much swifter
+for many miles below and above the opening. Slowly, however, the
+slopes are rearranged throughout its whole course, yet for a time the
+stream near the seat of the change becomes straighter than before, and
+this for the reason that its swifter current is better able to dispose
+of the <i>d&eacute;bris</i> which is supplied to it. The effect of a change in the
+current produced by such new channels as we have described as forming
+across the isthmuses of bends is to perturb the course of the stream
+in all its subsequent downward length. Thus an oxbow cut-off formed
+near the junction of the Ohio and Mississippi may tend more or less to
+alter the swings of the Mississippi all the way to the Gulf of Mexico.</p>
+
+<p>Although the swayings of the streams to and fro in their alluvial
+plains will give the reader some idea as to the struggle which the
+greater rivers have with the <i>d&eacute;bris</i> which is committed to them, the
+full measure of the work and its consequences can only be appreciated
+by those who have studied the phenomena on the ground. A river <span class='pagenum'><a name="Page_184" id="Page_184">[Pg 184]</a></span>such
+as the Mississippi is endlessly endeavouring to bear its burden to the
+sea. If its slope were a uniform inclined plane, the task might
+readily be accomplished; but in this, as in almost all other large
+water ways, the slope of the bed is ever diminishing with its onward
+course. The same water which in the mountain torrent of the
+Appalachians or Cordilleras rolled along stones several feet in
+diameter down slopes of a hundred feet or more to the mile can in the
+lower reaches of the stream move no pebbles which are more than one
+fourth of an inch in diameter over slopes which descend on the average
+about half a foot in a mile. Thus at every stage from the torrent to
+the sea the detritus has from time to time to rest within the alluvial
+banks, there awaiting the decay which slowly comes, and which may
+bring it to the state where it may be dissolved in the water, or
+divided into fragments so small that the stream may bear them on. A
+computation which the present writer has made shows that, on the
+average, it requires about forty thousand years for a particle of
+stone to make its way down the Mississippi to the sea after it has
+been detached from its original bed. Of course, some bits may make the
+journey straightforwardly; others may require a far greater time to
+accomplish the course which the water itself makes at most in a few
+weeks. This long delay in the journey of the detritus&mdash;a delay caused
+by its frequent rests in the alluvial plain&mdash;brings about important
+consequences which we will now consider.</p>
+
+<p>As an alluvial plain is constructed, we generally find at the base
+pebbly material which fell to the bottom in the current of the main
+stream as the shores grew outward. Above this level we find the
+deposits laid down by the flood waters containing no pebbles, and this
+for the reason that those weightier bits remained in the stream bed
+when the tide flowed over the plain. As the alluvial deposit is laid
+down, a good deal of vegetable matter was built into it. Generally
+this has decayed and disappeared. On the surface of the plain there
+has always been growing abun<span class='pagenum'><a name="Page_185" id="Page_185">[Pg 185]</a></span>dant vegetation, the remains of which
+decayed on the surface in the manner which we may observe at the
+present day. This decomposing vegetable matter within and upon the
+porous alluvial material produces large quantities of carbonic acid, a
+gas which readily enters the rain water, and gives it a peculiar power
+of breaking up rock matter. Acting on the <i>d&eacute;bris</i>, this gas-charged
+water rapidly brings about a decay of the fragments. Much of the
+material passes at once into solution in this water, and drains away
+through the multitudinous springs which border the river. As this
+matter is completely dissolved, as is sugar in water, it goes straight
+away to the sea without ever again entering the alluvium. In many, if
+not most, cases this dissolving work which is going on in alluvial
+terraces is sufficient to render a large part of the materials which
+they contain into the state where it disappears in an unseen manner;
+thus while the annual floods are constantly laying down accumulations
+on the surface of these plains, the springs are bearing it away from
+below.</p>
+
+<p>In this way, through the decomposition which takes place in them, all
+those river terraces where much vegetable matter is mingled with the
+mineral substances, become laboratories in which substances are
+brought into solution and committed to the seas. We find in the water
+of the ocean a great array of dissolved mineral substances; it,
+indeed, seems probable that the sea water contains some share, though
+usually small, of all the materials which rivers encounter in their
+journey over and under the lands. As the waters of the sea obtain but
+little of this dissolved matter along the coast, it seems likely that
+the greater share of it is brought into the state of solution in the
+natural laboratories of the alluvial plains.</p>
+
+<p>Here and there along the sides of the valleys in which the rivers flow
+we commonly find the remains of ancient plains lying at more or less
+considerable heights above the level of the streams. Generally these
+deposits, which from their form are called terraces, represent the
+stages of <span class='pagenum'><a name="Page_186" id="Page_186">[Pg 186]</a></span>down-wearing by which the stream has carved out its way
+through the rocks. The greater part of these ancient alluvial plains
+has been removed through the ceaseless swinging of the stream to and
+fro in the valley which it has excavated.</p>
+
+<p>In all the states of alluvial plains, whether they be the fertile
+deposits near the level of the streams which built them, or the poorer
+and ruder surfaced higher terraces, they have a great value to
+mankind. Men early learned that these lands were of singularly uniform
+goodness for agricultural use. They are so light that they were easily
+delved with the ancient pointed sticks or stone hoes, or turned by the
+olden, wooden plough. They not only give a rich return when first
+subjugated, but, owing to the depth of the soil and the frequency with
+which they are visited by fertilizing inundations, they yield rich
+harvests without fertilizing for thousands of years. It is therefore
+not surprising that we find the peoples who depended upon tillage for
+subsistence first developed on the great river plains. There, indeed,
+were laid the foundations of our higher civilization; there alone
+could the state which demands of its citizens fixed abodes and
+continuous labour take rise. In the conditions which these fields of
+abundance afforded, dense populations were possible, and all the arts
+which lead toward culture were greatly favoured. Thus it is that the
+civilization of China, India, Persia, and Egypt, the beginnings of
+man's higher development, began near the mouths of the great river
+valleys. These fields were, moreover, most favourably placed for the
+institution of commerce, in that the arts of navigation, originating
+in the sheltered reaches of the streams, readily found its way through
+the estuaries to the open sea.</p>
+
+<p>Passing down the reaches of a great river as it approaches the sea, we
+find that the alluvial plains usually widen and become lower. At
+length we attain a point where the flood waters cover the surface for
+so large a part of the year that the ground is swampy and untillable
+unless <span class='pagenum'><a name="Page_187" id="Page_187">[Pg 187]</a></span>it is artificially and at great expense of labour won to
+agriculture in the manner in which this task has been effected in the
+lower portion of the Rhine Valley. Still farther toward the sea, the
+plain gradually dips downward until it passes below the level of the
+waters. Through this mud-flat section the stream continues to cut
+channels, but with the ever-progressive slowing of its motion the
+burden of fine mud which it carries drops to the bottom, and
+constantly closes the paths through which the water escapes. Every few
+years they tend to break a new way on one side or the other of their
+former path. Some of the greatest engineering work done in modern
+times has been accomplished by the engineers engaged in controlling
+the exits of large rivers to the sea. The outbreak of the Yellow River
+in 1887, in which the stream, hindered by its own accumulations,
+forced a new path across its alluvial plains, destroyed a vast deal of
+life and property, and made the new exit seventy miles from the path
+which it abandoned.</p>
+
+<p>Below the surface of the open water the alluvial deposits spread out
+into a broad fan, which slopes gradually to a point where, in the
+manner of the continental shelf, the bottom descends steeply into deep
+water.</p>
+
+<p>It is the custom of naturalists to divide the lower section of river
+deposits&mdash;that part of the accumulation which is near the sea&mdash;from
+the other alluvial plains, terming the lower portion the delta. The
+word originally came into use to describe that part of the alluvium
+accumulated by the Nile near its mouth, which forms a fertile
+territory shaped somewhat like the fourth letter of the Greek
+alphabet. Although the definition is good in the Egyptian instance,
+and has a certain use elsewhere, we best regard all the detritus in a
+river valley which is in the state of repose along the stream to its
+utmost branches as forming one great whole. It is, indeed, one of the
+most united of the large features which the earth exhibits. The
+student should consider it as a continuous inclined plane of
+diminishing slope, extending from the base of the torrents to <span class='pagenum'><a name="Page_188" id="Page_188">[Pg 188]</a></span>the
+sea, and of course ramifying into the several branches of the river
+system. He should further bear in mind the fact that it is a vast
+laboratory where rock material is brought into the soluble state for
+delivery to the seas.</p>
+
+<p>The diversity in the form of river valleys is exceedingly great.
+Almost all the variety of the landscape is due to this impress of
+water action which has operated on the surface in past ages. When
+first elevated above the sea, the surface of the land is but little
+varied; at this stage in the development the rivers have but shallow
+valleys, which generally cut rather straight away over the plain
+toward the sea. It is when the surface has been uplifted to a
+considerable height, and especially when, as is usually the case, this
+uplifting action has been associated with mountain-building, that
+valleys take on their accented and picturesque form. The reason for
+this is easily perceived: it lies in the fact that the rocks over
+which the stream flows are guided in the cutting which they effect by
+the diversities of hardness in the strata that they encounter. The
+work which it does is performed by the hard substances that are
+impelled by the current, principally by the sand and pebbles. These
+materials, driven along by the stream, become eroding tools of very
+considerable energy. As will be seen when we shortly come to describe
+waterfalls, the potholes formed at those points afford excellent
+evidence as to the capacity of stream-impelled bits of stone to cut
+away the firmest bed rocks. Naturally the ease with which this carving
+work is done is proportionate to the energy of the currents, and also
+to the relative hardness of the moving bits and the rocks over which
+they are driven.</p>
+
+<p>So long as the rocks lie horizontally in their natural construction
+attitude the course of the stream is not much influenced by the
+variations in hardness which the bed exhibits. Where the strata are
+very firm there is likely to be a narrow gorge, the steeps of which
+rise on either side with but slight alluvial plains; where the beds
+are soft the valley widens, perhaps again to contract where in the
+<span class='pagenum'><a name="Page_189" id="Page_189">[Pg 189]</a></span>course of its descent it encounters another hard layer. Where,
+however, the beds have been subjected to mountain-building, and have
+been thrown into very varied attitudes by folding and faulting, the
+stream now here and now there encounters beds which either restrain
+its flow or give it freedom. The stream is then forced to cut its way
+according to the positions of the various underlying strata. This
+effect upon its course is not only due to the peculiarities of
+uplifted rocks, but to manifold accidents of other nature: veins and
+dikes, which often interlace the beds with harder or softer partitions
+than the country rock; local hardenings in the materials, due to
+crystallization and other chemical processes, often create
+indescribable variations which are more or less completely expressed
+in the path of the stream.</p>
+
+<p>When a land has been newly elevated above the sea there is often&mdash;we
+may say, indeed, generally&mdash;a very great difference between the height
+of its head waters and the ocean level. In this condition of a country
+the rivers have what we may call a new aspect; their valleys are
+commonly narrow and rather steep, waterfalls are apt to abound, and
+the alluvial terraces are relatively small in extent. Stage by stage
+the torrents cut deeper; the waste which they make embarrasses the
+course of the lower waters, where no great amount of down-cutting is
+possible for the reason that the bed of the stream is near sea level.
+At the same time the alluvial materials, building out to sea, thus
+diminish the slope of the stream. In the extreme old age of the river
+system the mountains are eaten down so that the torrent section
+disappears, and the stream becomes of something like a uniform slope;
+the higher alluvial plains gradually waste away, until in the end the
+valley has no salient features. At this stage in the process, or even
+before it is attained, the valley is likely to be submerged beneath
+the sea, where it is buried beneath the deposits formed on the floor;
+or a further uplift of the land may occur with the result that the
+stream is rejuvenated; or once more en<span class='pagenum'><a name="Page_190" id="Page_190">[Pg 190]</a></span>dowed with the power to create
+torrents, build alluvial plains, and do the other interesting work of
+a normal river.</p>
+
+<p>It rarely, if ever, happens that a river valley attains old age before
+it has sunk beneath the sea or been refreshed by further upliftings.
+In the unstable conditions of the continents, one or the other of
+these processes, sometimes in different places both together, is apt
+to be going on. Thus if we take the case of the Mississippi and its
+principal tributaries, the Ohio and Missouri, we find that for many
+geological ages the mountains about their sources have frequently, if
+not constantly, grown upward, so that their torrent sections, though
+they have worn down tens of thousands of feet, are still high above
+the sea level, perhaps on the average as high as they have ever been.
+At the same time the slight up-and-down swayings of the shore lands,
+amounting in general to less than five hundred feet, have greatly
+affected the channels of the main river and its tributaries in their
+lower parts. Not long ago the Mississippi between Cairo and the Gulf
+flowed in a rather steep-sided valley probably some hundreds of feet
+in depth, which had a width of many miles. Then at the close of the
+last Glacial period the region sank down so that the sea flooded the
+valley to a point above the present junction of the Ohio River with
+the main stream. Since then alluvial plains have filled this estuary
+to even beyond the original mouth. In many other of our Southern
+rivers, as along the shore from the Mississippi to the Hudson, the
+streams have not brought in enough detritus to fill their drowned
+valleys, which have now the name of bays, of which the Delaware and
+Chesapeake on the Atlantic coast, and Mobile Bay on the Gulf of
+Mexico, are good examples. The failure of Chesapeake and Delaware Bays
+to fill with <i>d&eacute;bris</i> in the measure exhibited by the more southern
+valleys is due to the fact that the streams which flow into them to a
+great extent drain from a region thickly covered with glacial waste, a
+mass which holds the flood waters, yielding the <span class='pagenum'><a name="Page_191" id="Page_191">[Pg 191]</a></span>supply but slowly to
+the torrents, which there have but a slight cutting power.</p>
+
+<p>In our sketch of river valleys no attention has been given to the
+phenomena of waterfalls, those accidents of the flow which, as we have
+noted, are particularly apt to characterize rivers which have not yet
+cut down to near the sea level. Where the normal uniform descent which
+is characteristic of a river's bed is interrupted by a sudden steep,
+the fact always indicates the occurrence of one of a number of
+geological actions. The commonest cause of waterfalls is due to a
+sudden change in the character of horizontal or at least nearly level
+beds over which the stream may flow. Where after coursing for a
+distance over a hard layer the stream comes to its edge and drops on a
+soft or easily eroded stratum, it will cut this latter bed away, and
+create a more or less characteristic waterfall. Tumbling down the face
+of the hard layer, the stream acquires velocity; the <i>d&eacute;bris</i> which it
+conveys is hurled against the bottom, and therefore cuts powerfully,
+while before, being only rubbed over the stone as it moved along, it
+cut but slightly. Masses of ice have the same effect as stones. Bits
+dropping from the ledge are often swept round and round by the eddies,
+so that they excavate an opening which prevents their chance escape.
+In these confined spaces they work like augers, boring a deep,
+well-like cavity. As the bits of stone wear out they are replaced by
+others, which fall in from above. Working in this way, the fragments
+often develop regular well-like depressions, the cavities of which
+work back under the cliffs, and by the undermining process deprive the
+face of the wall of its support, so that it tumbles in ruin to the
+base, there to supply more material for the potholing action.</p>
+
+<p>Waterfalls of the type above described are by far the commonest of
+those which occur out of the torrent districts of a great river
+system. That of Niagara is an excellent specimen of the type, which,
+though rarely manifested in anything like the dignity of the great
+fall, is <span class='pagenum'><a name="Page_192" id="Page_192">[Pg 192]</a></span>plentifully shown throughout the Mississippi Valley and the
+basin of the Great Lakes. Within a hundred miles of Niagara there are
+at least a hundred small waterfalls of the same type. Probably three
+quarters of all the larger accidents of this nature are due to the
+conditions of a hard bed overlying softer strata.</p>
+
+<p>Falls are also produced in very many instances by dikes which cross
+the stream. So, too, though rarely, only one striking instance being
+known, an ancient coral reef which has become buried in strata may
+afford rock of such hardness that when the river comes to cross it it
+forms a cascade, as at the Falls of the Ohio, at Louisville, Ky. It is
+a characteristic of all other falls, except those first mentioned,
+that they rarely plunge with a clean downward leap over the face of a
+precipice which recedes at its base, but move downward over an
+irregular sloping surface.</p>
+
+<p>In the torrent district of rivers waterfalls are commonly very
+numerous, and are generally due to the varying hardness in the rocks
+which the streams encounter. Here, where the cutting action is going
+on with great rapidity, slight differences in the resistance which the
+rocks make to the work will lead to great variations in the form of
+the bed over which they flow, while on the more gently sloping bottoms
+of the rivers, where the <i>d&eacute;bris</i> moves slowly, such variations would
+be unimportant in their effect. When the torrents escape into the main
+river valleys, in regions where the great streams have cut deep
+gorges, they often descend from a great vertical height, forming
+wonderful waterfalls, such as those which occur in the famous
+Lauterbrunnen Valley of Switzerland or in that of the Yosemite in
+California. This group of cascades is peculiar in that the steep of
+the fall is made not by the stream itself, but by the action of a
+greater river or of a glacier which may have some time taken its
+place.</p>
+
+<p>Waterfalls have an economic as well as a picturesque interest in that
+they afford sources of power which may be a very great advantage to
+manufacturers. Thus along <span class='pagenum'><a name="Page_193" id="Page_193">[Pg 193]</a></span>the Atlantic coast the streams which come
+from the Appalachian highlands, and which have hardly escaped from
+their torrent section before they attain the sea, afford numerous
+cataracts which have been developed so that they afford a vast amount
+of power. Between the James on the south and the Ste. Croix on the
+north more than a hundred of these Appalachian rivers have been turned
+to economic use. The industrial arts of this part of the country
+depend much upon them for the power which drives their machinery. The
+whole of the United States, because of the considerable size of its
+rivers and their relatively rapid fall, is richly endowed with this
+source of energy, which, originating in the sun's heat and conveyed
+through the rain, may be made to serve the needs of man. In view of
+the fact that recent inventions have made it possible to convert this
+energy of falling water into the form of electricity, which may be
+conveyed to great distances, it seems likely that our rivers will in
+the future be a great source of national wealth.</p>
+
+<p>We must turn again to river valleys, there to trace certain actions
+less evident than those already noted, but of great importance in
+determining these features of the land. First, we have to note that in
+the valley or region drained by a river there is another degrading or
+down-wearing action than that which is accomplished by the direct work
+of the visible stream. All over such a valley the underground waters,
+soaking through the soil and penetrating through the underlying rock,
+are constantly removing a portion of the mineral matter which they
+take into solution and bear away to the sea. In this way, deprived of
+a part of their substance, the rocks are continually settling down by
+underwear throughout the whole basin, while they are locally being cut
+down by the action of the stream. Hence in part it comes about that in
+a river basin we find two contrasted features&mdash;the general and often
+slight slope of a country toward the main stream and its greater
+tributaries, and the sharp indentation of the gorge <span class='pagenum'><a name="Page_194" id="Page_194">[Pg 194]</a></span>in which the
+streams flow, these latter caused by the immediate and recent action
+of the streams.</p>
+
+<p>If now the reader will conceive himself standing at any point in a
+river basin, preferably beyond the realms of the torrents, he may with
+the guidance of the facts previously noted, with a little use of the
+imagination, behold the vast perceptive which the history of the river
+valley may unfold to him. He stands on the surface of the soil, that
+<i>d&eacute;bris</i> of the rocks which is just entering on its way to the ocean.
+In the same region ten thousand years ago he would have stood upon a
+surface from one to ten feet higher than the present soil covering. A
+million years ago his station would have been perhaps five hundred
+feet higher than the surface. Ten million years in the past, a period
+less than the lifetime of certain rivers, such as the French Broad
+River in North Carolina, the soil was probably five thousand feet or
+more above its present plane. There are, indeed, cases where river
+valleys appear to have worked down without interruption from the
+subsidence of the land beneath the sea to the depth of at least two
+miles. Looking upward through the space which the rocks once occupied,
+we can conceive the action of the forces in their harmonious
+co-operation which have brought the surface slowly downward. We can
+imagine the ceaseless corrosion due to the ground water, bringing
+about a constant though slow descent of the whole surface. Again and
+again the streams, swinging to and fro under the guidance of the
+underlying rock, or from the obstacles which the <i>d&eacute;bris</i> they carried
+imposed upon them, have crossed the surface. Now and then perhaps the
+wearing was intensified by glacial action, for an ice sheet often cuts
+with a speed many times as great as that which fluid water can
+accomplish. On the whole, this exercise of the constructive
+imagination in conceiving the history of a river valley is one of the
+most enlarging tasks which the geologist can undertake.</p>
+
+<p>Where in a river valley there are many lateral streams, and especially
+where the process of solution carried on by <span class='pagenum'><a name="Page_195" id="Page_195">[Pg 195]</a></span>the underground waters is
+most effective, as compared with erosive work done in the bed of the
+main river, we commonly find the valley sloping gently toward its
+centre, the rivers having but slight steeps near their banks. On the
+other hand, where, as occasionally happens, a considerable stream fed
+by the rain and snow fall in its torrent section courses for a great
+distance over high, arid plains, on which the ground water and the
+tributaries do but little work, the basin may slope with very slight
+declivity to the river margins, and there descend to great depths,
+forming very deep gorges, of which the Colorado Ca&ntilde;on is the most
+perfect type. As instances of these contrasted conditions, we may
+take, on the one hand, the upper Mississippi, where the grades toward
+the main stream are gentle and the valley gorge but slightly
+exhibited; on the other, the above-mentioned Colorado, which bears a
+great tide of waters drawn from the high and relatively rainy region
+of the Rocky Mountains across the vast plateau lying in an almost
+rainless country. In this section nearly all the down-wearing has been
+brought about in the direct path of the stream, which has worn the
+elevated plain into a deep gorge during the slow uprising of the
+table-land to its present height. In this way a defile nearly a mile
+in depth has been created in a prevailingly rather flat country. This
+gorge has embranchments where the few great tributaries have done like
+work, but, on the whole, this river flows in an almost unbroken
+channel, the excavation of which has been due to its swift,
+pebble-bearing waters.</p>
+
+<p>The tendency of a newly formed river is to cut a more or less distinct
+ca&ntilde;on. As the basin becomes ancient, this element of the gorge tends
+to disappear, the reason for this being that, while the river bed is
+high above the sea, the current is swift and the down-cutting rapid,
+while the slow subsidence of the country on either side&mdash;a process
+which goes on at a uniform rate&mdash;causes the surface of that region to
+be left behind in the race for the sea level. As the stream bed comes
+nearer the sea level its rate of descent <span class='pagenum'><a name="Page_196" id="Page_196">[Pg 196]</a></span>is diminished, and so the
+outlying country gradually overtakes it.</p>
+
+<p>In regions where the winters are very cold the effect of ice on the
+development of the stream beds both in the torrent and river sections
+of the valley is important. This work is accomplished in several
+diverse ways. In the first place, where the stream is clear and the
+current does not flow too swiftly, the stones on the bottom radiate
+their heat through the water, and thus form ice on their surfaces,
+which may attain considerable thickness. As ice is considerably
+lighter than water, the effect is often to lift up the stones of the
+bed if they be not too large; when thus detached from the bottom, they
+are easily floated down stream until the ice melts away. The ice which
+forms on the surface of the water likewise imprisons the pebbles along
+the banks, and during the subsequent thaw may carry them hundreds of
+miles toward the sea. It seems likely, from certain observations made
+by the writer, that considerable stones may thus be carried from the
+Alleghany River to the main Mississippi.</p>
+
+<p>Perhaps the most important effect of ice on river channels is
+accomplished when in a time of flood the ice field which covered the
+stream, perhaps to the depth of some feet, is broken up into vast
+floes, which drift downward with the current. When, as on the Ohio,
+these fields sometimes have the area of several hundred acres, they
+often collide with the shores, especially where the stream makes a
+sharp bend. Urged by their momentum, these ice floes pack into the
+semblance of a dam, which may have a thickness of twenty, thirty, or
+even fifty feet. Beginning on the shore, where the collision takes
+place, the dam may swiftly develop clear across the stream, so that in
+a few minutes the way of the waters is completely blocked. The
+on-coming ice shoots up upon the accumulation, increases its height,
+and extends it up stream, so that in an hour the mass completely bars
+the current. The waters then heap up until they break their way over
+the obstacle, wash<span class='pagenum'><a name="Page_197" id="Page_197">[Pg 197]</a></span>ing its top away, until the whole is light enough
+to be forced down the stream, where, by the friction it encounters on
+the bottom and sides of the channel, it is broken to pieces. It is
+easy to see that such moving dams of ice may sweep the bed of a river
+as with a great broom.</p>
+
+<p>Sometimes where the gorges do not form a stationary dam large cakes of
+ice become turned on edge and pack together so that they roll down the
+stream like great wheels, grinding the bed rock as they go.</p>
+
+<p>In high northern countries, as in Siberia, the rivers, even the
+deepest, often become so far frozen that their channels are entirely
+obstructed. Where, as in the case of these Siberian rivers, the flow
+is from south to north, it often happens that the spring thaw sets in
+before the more northern beds of the main stream are released from
+their bondage of frost. In this case the inundations have to find new
+paths on either side of the obstructed way. The result is a type of
+valleys characterized by very irregular and changeable stream beds,
+the rivers having no chance to organize themselves into the shapely
+curves which they ordinarily follow.</p>
+
+<p>The supply which finds its way to a river is composed, as has been
+already incidentally noted, in part of the water which courses
+underground for a greater or less distance before it emerges to the
+surface, and in part of that which moves directly over the ground.
+These two shares of water have somewhat different histories. On the
+share of these two depends the stability of the flow. Where, as in New
+England and other glaciated countries, the surface of the earth is
+covered with a thick layer of sand and gravel, which, except when
+frozen, readily admits the water; the rainfall is to a very great
+extent absorbed by the earth, and only yielded slowly to the streams.
+In these cases floods are rare and of no great destructive power.
+Again, where also the river basin is covered by a dense mantle of
+forests, the ground beneath which is coated, as is the case in
+primeval woods, with a layer of decomposing vegetation a foot or <span class='pagenum'><a name="Page_198" id="Page_198">[Pg 198]</a></span>more
+in depth, this spongy mass retains the water even more effectively
+than the open-textured glacial deposits above referred to. When the
+woods, however, are removed from such an area, the rain may descend to
+the streams almost as speedily as it finds its way to the gutters from
+the house roofs. It thus comes about that all regions, when reduced to
+tillage, and where the rainfall is enough to maintain a good
+agriculture, are, except when they have a coating of glacial waste,
+exceedingly liable to destructive inundations.</p>
+
+<p>Unhappily, the risk of river floods is peculiarly great in all the
+regions of the United States lying much to the east of the Rocky
+Mountains, except in the basin of the Great Lakes and in the district
+of New England, where the prevalence of glacial sands and gravels
+affords the protection which we have noted. Throughout this region the
+rainfall is heavy, and the larger part of it is apt to come after the
+ground has become deeply snow-covered. The result is a succession of
+devastating floods which already are very damaging to the works of
+man, and promise to become more destructive as time goes on. More than
+in any other country, we need the protection which forests can give us
+against these disastrous outgoings of our streams.</p>
+
+
+<h2 class="subtitle smcap">Lakes.</h2>
+
+<p>In considering the journey of water from the hilltops to the sea, we
+should take some account of those pauses which it makes on its way
+when for a time it falls into the basin of a lake. These arrests in
+the downward motion of water, which we term lakes, are exceedingly
+numerous; their proper discussion would, indeed, require a
+considerable volume. We shall here note only the more important of
+their features, those which are of interest to the general student.</p>
+
+<p>The first and most noteworthy difference in lakes is that which
+separates the group of dead seas from the living <span class='pagenum'><a name="Page_199" id="Page_199">[Pg 199]</a></span>basins of fresh
+water. When a stream attains a place where its waters have to expand
+into the lakelike form, the current moves in a slow manner, and the
+broad surface exposed to the air permits a large amount of
+evaporation. If the basin be large in proportion to the amount of the
+incurrent water, this evaporation may exceed the supply, and produce a
+sea with no outlet, such as we find in the Dead Sea of Judea, in that
+at Salt Lake, Utah, and in a host of other less important basins. If
+the rate of evaporation be yet greater in proportion to the flow, the
+lake may altogether dry away, and the river be evaporated before it
+attains the basin where it might accumulate. In that case the river is
+said to sink, but, in place of sinking into the earth, its waters
+really rise into the air. Many such sinks occur in the central portion
+of the Rocky Mountain district. It is important to note that the
+process of evaporation we are describing takes place in the case of
+all lakes, though only here and there is the air so dry that the
+evaporation prevents the basin from overflowing at the lowest point on
+its rim, forming a river which goes thence to the sea. Even in the
+case of the Great Lakes of North America a considerable part of the
+water which flows into them does not go to the St. Lawrence and thence
+to the sea. As long as the lake finds an outlet to the sea its waters
+contain but little more dissolved mineral matter than that we find in
+the rivers. But because all water which has been in contact with the
+earth has some dissolved mineral substances, while that which goes
+away by evaporation is pure water, a lake without an outlet gradually
+becomes so charged with these materials that it can hold no more in
+solution, but proceeds to lay them down in deposits of that compound
+substance which from its principal ingredient we name salt. The water
+of dead seas, because of the additional weight of the substances which
+it holds, is extraordinarily buoyant. The swimmer notes a difference
+in this regard in the waters of rivers and fresh-water lakes and those
+of the sea, due to this same cause. But in those <span class='pagenum'><a name="Page_200" id="Page_200">[Pg 200]</a></span>of dead seas,
+saturated with saline materials, the human body can not sink as it
+does in the ordinary conditions of immersion. It is easy to understand
+how the salt deposits which are mined in many parts of the world have
+generally, if not in all cases, been formed in such dead seas.<a name="FNanchor_5_5" id="FNanchor_5_5"></a><a href="#Footnote_5_5" class="fnanchor">[5]</a></p>
+
+<p>It is an interesting fact that almost all the known dead seas have in
+recent geological times been living lakes&mdash;that is, they poured over
+their brims. In the Cordilleras from the line between Canada and the
+United States to central Mexico there are several of these basins. All
+of those which have been studied show by their old shore lines that
+they were once brimful, and have only shrunk away in modern times.
+These conditions point to the conclusion that the rainfall in
+different regions varies greatly in the course of the geologic ages.
+Further confirmation of this is found in the fact that very great salt
+deposits exist on the coast of Louisiana and in northern
+Europe&mdash;regions in which the rainfall is now so great in proportion to
+the evaporation that dead seas are impossible.</p>
+
+<p>Turning now to the question of how lake basins are formed, we note a
+great variety in the conditions which may bring about their
+construction. The greatest agent, or at least that which operates in
+the construction of the largest basins, are the irregular movements of
+the earth, due to the mountain-building forces. Where this work goes
+on on a large scale, basin-shaped depressions are inevitably formed.
+If all those which have existed remained, the large part of the lands
+would be covered by them. In most cases, however, the cutting action
+of the streams has been sufficient to bring the drainage channels down
+to the bottom of the trough, while the influx of sediments has served
+to further the work by filling up the cavities. Thus <span class='pagenum'><a name="Page_201" id="Page_201">[Pg 201]</a></span>at the close of
+the Cretaceous period there was a chain of lakes extending along the
+eastern base of the Rocky Mountains, constituting fresh-water seas
+probably as large as the so-called Great Lakes of North America. But
+the rivers, by cutting down and tilling up, have long since
+obliterated these water areas. In other cases the tiltings of the
+continent, which sometimes oppose the flow of the streams, may for a
+time convert the upper part of a river basin which originally sloped
+gently toward the sea into a cavity. Several cases of this description
+occurred in New England in the closing stages of the Glacial period,
+when the ground rose up to the northward.</p>
+
+<p>We have already noted the fact that the basin of a dead sea becomes in
+course of time the seat of extensive salt deposits. These may, indeed,
+attain a thickness of many hundred feet. If now in the later history
+of the country the tract of land with the salt beneath it were
+traversed by a stream, its underground waters may dissolve out the
+salt and in a way restore the basin to its original unfilled
+condition, though in the second state that of a living lake. It seems
+very probable that a portion at least of the areas of Lakes Ontario,
+Erie, and Huron may be due to this removal of ancient salt deposits,
+remains of which lie buried in the earth in the region bordering these
+basins.</p>
+
+<p>By far the commonest cause of lake basins is found in the
+irregularities of the surface which are produced by the occupation of
+the country by glaciers. When these great sheets of ice lie over a
+land, they are in motion down the slopes on which they rest; they wear
+the bed rocks in a vigorous manner, cutting them down in proportion to
+their hardness. As these rocks generally vary in the resistance which
+they oppose to the ice, the result is that when the glacier passes
+away the surface no longer exhibits the continued down slope which the
+rivers develop, but is warped in a very complicated way. These
+depressions afford natural basins in which lakes gather; they may vary
+in extent from a few square feet to many square miles. When a gla<span class='pagenum'><a name="Page_202" id="Page_202">[Pg 202]</a></span>cier
+occupies a country, the melting ice deposits on the surface of the
+earth a vast quantity of rocky <i>d&eacute;bris</i>, which was contained in its
+mass. This detritus is irregularly accumulated; in part it is disposed
+in the form of moraines or rude mounds made at the margin of the
+glacier, in part as an irregular sheet, now thick, now thin, which
+covers the whole of the field over which the ice lay. The result of
+this action is the formation of innumerable pools, which continue to
+exist until the streams have cut channels through which their waters
+may drain away, or the basins have become filled with detritus
+imported from the surrounding country or by peat accumulations which
+the plants form in such places.</p>
+
+<p>Doubtless more than nine tenths of all the lake basins, especially
+those of small size, which exist in the world are due to
+irregularities of the land surface which are brought about by glacial
+action. Although the greater part of these small basins have been
+obliterated since the ice left this country, the number still
+remaining of sufficient size to be marked on a good map is
+inconceivably great. In North America alone there are probably over a
+hundred and fifty thousand of these glacial lakes, although by far the
+greater part of those which existed when the glacial sheet disappeared
+have been obliterated.</p>
+
+<p>Yet another interesting group of fresh-water lakes, or rather we
+should call them lakelets from their small size, owes its origin to
+the curious underground excavations or caverns which are formed in
+limestone countries. The water enters these caverns through what are
+termed "sink holes"&mdash;basins in the surface which slope gently toward a
+central opening through which the water flows into the depths below.
+The cups of the sink holes rarely exceed half a mile in diameter, and
+are usually much smaller. Their basins have been excavated by the
+solvent and cutting actions of the rain water which gathers in them to
+be discharged into the cavern below. It often happens that after a
+sink hole is formed some slight accident closes the <span class='pagenum'><a name="Page_203" id="Page_203">[Pg 203]</a></span>downward-leading
+shaft, so that the basin holds water; thus in parts of the United
+States there are thousands of these nearly circular pools, which in
+certain districts, as in southern Kentucky, serve to vary the
+landscape in much the same manner as the glacial lakes of more
+northern countries.</p>
+
+<p>Some of the most beautiful lakes in the world, though none more than a
+few miles in diameter, occupy the craters of extinct volcanoes. When
+for a time, or permanently, a volcano ceases to do its appointed work
+of pouring forth steam and molten rock from the depths of the earth,
+the pit in the centre of the cone gathers the rain water, forming a
+deep circular lake, which is walled round by the precipitous faces of
+the crater. If the volcano reawakens, the water which blocks its
+passage may be blown out in a moment, the discharge spreading in some
+cases to a great distance from the cone, to be accumulated again when
+the vent ceases to be open. The most beautiful of these volcanic lakes
+are to be found in the region to the north and south of Rome. The
+original seat of the Latin state was on the shores of one of these
+crater pools, south of the Eternal City. Lago Bolsena, which lies to
+the northward, and is one of the largest known basins of this nature,
+having a diameter of about eight miles, is a crater lake. The volcanic
+cone to which it belongs, though low, is of great size, showing that
+in its time of activity, which did not endure very long, this crater
+was the seat of mighty ejections. The noblest specimen of this group
+of basins is found in Crater Lake, Oregon, now contained in one of the
+national parks of the United States.</p>
+
+<p>Inclosed bodies of water are formed in other ways than those
+described; the list above given includes all the important classes of
+action which produce these interesting features. We should now note
+the fact that, unlike the seas, the lakes are to be regarded as
+temporary features in the physiography of the land. One and all, they
+endure for but brief geologic time, for the reason that the <span class='pagenum'><a name="Page_204" id="Page_204">[Pg 204]</a></span>streams
+work to destroy them by filling them with sediment and by carving out
+channels through which their waters drain away. The nature of this
+action can well be conceived by considering what will take place in
+the course of time in the Great Lakes of North America. As Niagara
+Falls cut back at the average rate of several feet a year, it will be
+but a brief geologic period before they begin to lower the waters of
+Lake Erie. It is very probable, indeed, that in twenty thousand years
+the waters of that basin will be to a great extent drained away. When
+this occurs, another fall or rapid will be produced in the channel
+which leads from Lake Huron to Lake Erie. This in turn will go through
+its process of retreat until the former expanse of waters disappears.
+The action will then be continued at the outlets of Lakes Michigan and
+Superior, and in time, but for the interposition of some actions which
+recreate these basins, their floors will be converted into dry land.</p>
+
+<p>It is interesting to note that lakes owe in a manner the preservation
+of their basins to an action which they bring about on the waters that
+flow into them. These rivers or torrents commonly convey great
+quantities of sediment, which serve to rasp their beds and thus to
+lower their channels. In all but the smaller lakelets these turbid
+waters lay down all their sediment before they attain the outlet of
+the basin. Thus they flow away over the rim rock in a perfectly pure
+state&mdash;a state in which, as we have noted before, water has no
+capacity for abrading firm rock. Thus where the Niagara River passes
+from Lake Erie its clean water hardly affects the stone over which it
+flows. It only begins to do cutting work where it plunges down the
+precipice of the Falls and sets in motion the fragments which are
+constantly falling from that rocky face. These Falls could not have
+begun as they did on the margin of Lake Ontario except for the fact
+that when the Niagara River began to flow, as in relatively modern
+times, it found an old precipice on the margin of Lake Ontario, formed
+by the waves of the lake, down which the waters fell, and <span class='pagenum'><a name="Page_205" id="Page_205">[Pg 205]</a></span>where they
+obtained cutting tools with which to undermine the steep which forms
+the Falls.</p>
+
+<p>Many great lakes, particularly those which we have just been
+considering, have repeatedly changed their outlets, according as the
+surface of the land on which they lie has swayed up and down in
+various directions, or as glacial sheets have barred or unbarred the
+original outlets of the basins. Thus in the Laurentian Lakes above
+Ontario the geologist finds evidence that the drainage lines have
+again and again been changed. For a time during the Glacial period,
+when Lake Ontario and the valley of the St. Lawrence was possessed by
+the ice, the discharge was southward into the upper Mississippi or the
+Ohio. At a later stage channels were formed leading from Georgian Bay
+to the eastern part of Ontario. Yet later, when the last-named lake
+was bared, an ice dam appears to have remained in the St. Lawrence,
+which held back the waters to such a height that they discharged
+through the valley of the Mohawk into the Hudson. Furthermore, at some
+time before the Glacial period, we do not know just when, there
+appears to have been an old Niagara River, now filled with drift,
+which ran from Lake Erie to Ontario, a different channel from that
+occupied by the present stream.</p>
+
+<p>The effects of lakes on the river systems with which they are
+connected is in many ways most important. Where they are of
+considerable extent, or where even small they are very numerous, they
+serve to retain the flood waters, delivering them slowly to the
+excurrent streams. In rising one foot a lake may store away more water
+than the river by its consequent rise at the point of outflow will
+carry away in many months, and this for the simple reason that the
+lake may be many hundred or even thousand times as wide as the stream.
+Moreover, as before noted, the sediment gathered by the stream above
+the level of the lake is deposited in its basin, and does not affect
+the lower reaches of the river. The result is that great rivers, such
+as drain from the Laurentian Lakes, flow clear water, are exempt <span class='pagenum'><a name="Page_206" id="Page_206">[Pg 206]</a></span>from
+floods, are essentially without alluvial plains or terraces, and form
+no delta deposits. In all these features the St. Lawrence River
+affords a wonderful contrast to the Mississippi. Moreover, owing to
+the clear waters, though it has flowed for a long time, it has never
+been able to cut away the slight obstructions which form its rapids,
+barriers which probably would have been removed if its waters had been
+charged with sediment.</p>
+
+
+<hr style="width: 65%;" />
+
+<div class="figcenter" style="width: 641px;">
+<a name="img07"></a>
+<img src="images/p7.jpg" width="641" height="436" alt="Muir Glacier, Alaska, showing crevasses and dust
+layer on surface of ice." title="" />
+<span class="caption">Muir Glacier, Alaska, showing crevasses and dust
+layer on surface of ice.</span>
+</div>
+
+
+<p><span class='pagenum'><a name="Page_207" id="Page_207">[Pg 207]</a></span></p>
+<h1><a name="CHAPTER_VI" id="CHAPTER_VI"></a>CHAPTER &nbsp; VI.<br/>
+<span class="subtitle smcap">glaciers.</span></h1>
+
+
+<p>We have already noted the fact that the water in the clouds is very
+commonly in the frozen state; a large part of that fluid which is
+evaporated from the sea attains the solid form before it returns to
+the earth. Nevertheless, in descending, at least nine tenths of the
+precipitation returns to the fluid state, and does the kind of work
+which we have noted in our account of water. Where, however, the water
+arrives on the earth in the frozen condition, it enters on a r&ocirc;le
+totally different from that followed by the fluid material.</p>
+
+<p>Beginning its descent to the earth in a snowflake, the little mass
+falls slowly, so that when it comes against the earth the blow which
+it strikes is so slight that it does no effective work. In the state
+of snow, even in the separate flakes, the frozen water contains a
+relatively large amount of air. It is this air indeed, which, by
+dividing the ice into many flakes that reflect the light, gives it the
+white colour. This important point can be demonstrated by breaking
+transparent ice into small bits, when we perceive that it has the hue
+of snow. Much the same effect is given where glass is powdered, and
+for the same reason.</p>
+
+<p>As the snowflakes accumulate layer on layer they imbed air between
+them, so that when the material falls in a feathery shape&mdash;say to the
+depth of a foot&mdash;more than nine tenths of the mass is taken up by the
+air-containing spaces. As these cells are very small, the circulation
+in them is slight, and so the layer becomes an admirable
+non-con<span class='pagenum'><a name="Page_208" id="Page_208">[Pg 208]</a></span>ductor, having this quality for the same reason that feathers
+have it&mdash;i.e., because the cells are small enough to prevent the
+circulation of the air, so that the heat which passes has to go by
+conduction, and all gases are very poor conductors. The result is that
+a snow coating is in effect an admirable blanket. When the sun shines
+upon it, much of the heat is reflected, and as the temperature does
+not penetrate it to any depth, only the superficial part is melted.
+This molten water takes up in the process of melting a great deal of
+heat, so that when it trickles down into the mass it readily
+refreezes. On the other hand, the heat going out from the earth, the
+store accumulated in its superficial parts in the last warm season,
+together with the small share which flows out from the earth's
+interior, is held in by this blanket, which it melts but slowly. Thus
+it comes about that in regions of long-enduring snowfall the ground,
+though frozen to the depth of a foot or more at the time when the
+accumulation took place, may be thawed out and so far warmed that the
+vegetation begins to grow before the protecting envelope of snow has
+melted away. Certain of the early flowers of high latitudes, indeed,
+begin to blossom beneath the mantle of finely divided ice.</p>
+
+<p>In those parts of the earth which for the most part receive only a
+temporary coating of snow the effect of this covering is
+inconsiderable. The snow water is yielded to the earth, from which it
+has helped to withdraw the frost, so that in the springtime, the
+growing season of plants, the ground contains an ample store of
+moisture for their development. Where the snowfall accumulates to a
+great thickness, especially where it lodges in forests, the influence
+of the icy covering is somewhat to protract the winter and thus to
+abbreviate the growing season.</p>
+
+<p>Where snow rests upon a steep slope, and gathers to the depth of
+several feet, it begins to creep slowly down the declivity in a manner
+which we may often note on house roofs. This motion is favoured by the
+gradual though in<span class='pagenum'><a name="Page_209" id="Page_209">[Pg 209]</a></span>complete melting of the flakes as the heat
+penetrates the mass. Making a section through a mass of snow which has
+accumulated in many successive falls, we note that the top may still
+have the flaky character, but that as we go down the flakes are
+replaced by adherent shotlike bodies, which have arisen from the
+partial melting and gathering to their centres of the original
+expanded crystalline bits. In this process of change the mass can move
+particle by particle in the direction in which gravity impels it. The
+energy of its motion, however, is slight, yet it can urge loose stones
+and forest waste down hill. Sometimes, as in the cemetery at Augusta,
+Me., where stone monuments or other structures, such as iron railings,
+are entangled in the moving mass, it may break them off and convey
+them a little distance down the slope.</p>
+
+<p>So long as the summer sun melts the winter's snow, even if the ground
+be bare but for a day, the r&ocirc;le of action accomplished by the snowfall
+is of little geological consequence. When it happens that a portion of
+the deposit holds through the summer, the region enters on the glacial
+state, and its conditions undergo a great revolution, the consequences
+of which are so momentous that we shall have to trace them in some
+detail. Fortunately, the considerations which are necessary are not
+recondite, and all the facts are of an extremely picturesque nature.</p>
+
+<p>Taking such a region as New England, where all the earth is
+life-bearing in the summer season, and where the glacial period of the
+winter continues but for a short time, we find that here and there on
+the high mountains the snow endures throughout most of the summer, but
+that all parts of the surface have a season when life springs into
+activity. On the top of Mount Washington, in the White Mountains of
+New Hampshire, in a cleft known as Tuckerman's Ravine, where the
+deposit accumulates to a great depth, the snow-ice remains until
+midsummer. It is, indeed, evident that a very slight change in the
+climatal conditions of this locality would establish a perma<span class='pagenum'><a name="Page_210" id="Page_210">[Pg 210]</a></span>nent
+accumulation of frozen water upon the summit of the mountain. If the
+crest were lifted a thousand feet higher, without any general change
+in the heat or rainfall of the district, this effect would be
+produced. If with the same amount of rainfall as now comes to the
+earth in that region more of it fell as snow, a like condition would
+be established. Furthermore, with an increase of rainfall to something
+like double that which now descends the snow bore the same proportion
+to the precipitation which it does at present, we should almost
+certainly have the peak above the permanent snow line, that level
+below which all the winter's fall melts away. These propositions are
+stated with some care, for the reason that the student should perceive
+how delicate may be&mdash;indeed, commonly is&mdash;the balance of forces which
+make the difference between a seasonal and a perennial snow covering.</p>
+
+<p>As soon as the snow outlasts the summer, the region which it occupies
+is sterilized to life. From the time the snow begins to hold over the
+warm period until it finally disappears, that field has to be reckoned
+out of the habitable earth, not only to man, but to the lowliest
+organisms.<a name="FNanchor_6_6" id="FNanchor_6_6"></a><a href="#Footnote_6_6" class="fnanchor">[6]</a></p>
+
+<p>If the snow in a glaciated region lay where it fell, the result would
+be a constant elevation of the deposit year by year in proportion to
+the annual excess of deposition over the melting or evaporation of the
+material. But no sooner does the deposit attain any considerable
+thickness than it begins to move in the directions of least
+resistance, in accordance with laws which the students of glaciers are
+just beginning to discern. In small part this motion is accomplished
+by avalanches or snow slides, phenomena which are in a way important,
+and therefore merit description.<span class='pagenum'><a name="Page_211" id="Page_211">[Pg 211]</a></span> Immediately after a heavy snowfall,
+in regions where the slopes are steep, it often happens that the
+deposit which at first clung to the surface on which it lay becomes so
+heavy that it tends to slide down the slope; a trifling action, the
+slipping, indeed, of a single flake, may begin the movement, which at
+first is gradual and only involves a little of the snow. Gathering
+velocity, and with the materials heaped together from the junction of
+that already in motion with that about to be moved, the avalanche in
+sliding a few hundred feet down the slope may become a deep stream of
+snow-ice, moving with great celerity. At this stage it begins to break
+off masses of ice from the glaciers over which it may flow, or even to
+move large stones. Armed with these, it rends the underlying earth.
+After it has flowed a mile it may have taken up so much earth and
+material that it appears like a river of mud. Owing to the fact that
+the energy which bears it downward is through friction converted into
+heat, a partial melting of the mass may take place, which converts it
+into what we call slush, or a mixture of snow and water. Finally, the
+torrent is precipitated into the bottom of a valley, where in time the
+frozen water melts away, leaving only the stony matter which it bore
+as a monument to show the termination of its flow.</p>
+
+<p>It was the good fortune of the writer to see in the Swiss Oberland one
+very great avalanche, which came from the high country through a
+descent of several thousand feet to the surface of the Upper
+Grindelwald Glacier. The first sign of the action was a vague tremor
+of the air, like that of a great organ pipe when it begins to vibrate,
+but before the pulsations come swiftly enough to make an audible note.
+It was impossible to tell when this tremor came, but the wary guide,
+noting it before his charge could perceive anything unusual, made
+haste for the middle of the glacier. The vibration swelled to a roar,
+but the seat of the sound amid the echoing cliffs was indeterminable.
+Finally, from a valley high up on the southern face of the glacier,
+<span class='pagenum'><a name="Page_212" id="Page_212">[Pg 212]</a></span>there leaped forth first a great stone, which sprang with successive
+rebounds to the floor of ice. Then in succession other stones and
+masses of ice which had outrun the flood came thicker and thicker,
+until at the end of about thirty seconds the steep front of the
+avalanche appeared like a swift-moving wall. Attaining the cliffs, it
+shot forth as a great cataract, which during the continuance of the
+flow&mdash;which lasted for several minutes&mdash;heaped a great mound of
+commingled stones and ice upon the surface of the glacier. The mass
+thus brought down the steep was estimated at about three thousand
+cubic yards, of which probably the fiftieth part was rock material. An
+avalanche of this volume is unusual, and the proportion of stony
+matter borne down exceptionally great; but by these sudden motions of
+the frozen water a large part of the snow deposited above the zone of
+complete melting is taken to the lower valleys, where it may disappear
+in the summer season, and much of the erosion accomplished in the
+mountains is brought about by these falls.</p>
+
+<p>In all Alpine regions avalanches are among the most dreaded accidents.
+Their occurrence, however, being dependent upon the shape of the
+surface, it is generally possible to determine in an accurate way the
+liability of their happening in any particular field. The Swiss take
+precaution to protect themselves from their ravages as other folk do
+to procure immunity from floods. Thus the authorities of many of the
+mountain hamlets maintain extensive forests on the sides of the
+villages whence the downfall may be expected, experience having shown
+that there is no other means so well calculated to break the blow
+which these great snowfalls can deliver, as thick-set trees which,
+though they are broken down for some distance, gradually arrest the
+stream.</p>
+
+<p>As long as the region occupied by permanent snow is limited to sharp
+mountain peaks, relief by the precipitation of large masses to the
+level below the snow line is easily accomplished, but manifestly this
+kind of a discharge can <span class='pagenum'><a name="Page_213" id="Page_213">[Pg 213]</a></span>only be effective from a very small field.
+Where the relief is not brought about by these tumbles of snow,
+another mode of gravitative action accomplishes the result, though in
+a more roundabout way, through the mechanism of glaciers.</p>
+
+<p>We have already noted the fact that the winter's snow upon our
+hillsides undergoes a movement in the direction of the slope. What we
+have now to describe in a rather long story concerning glaciers rests
+upon movements of the same nature, though they are in certain features
+peculiarly dependent on the continuity of the action from year to
+year. It is desirable, however, that the student should see that there
+is at the foundation no more mystery in glacial motion than there is
+in the gradual descent of the snow after it has lain a week on a
+hillside. It is only in the scale and continuity of the action that
+the greatest glacial envelope exceeds those of our temporary
+winters&mdash;in fact, whenever the snow falls the earth it covers enters
+upon an ice period which differs only in degree from that from which
+our hemisphere is just escaping.</p>
+
+<p>Where the reader is so fortunate as to be able to visit a region of
+glaciers, he had best begin his study of their majestic phenomena by
+ascending to those upper realms where the snow accumulates from year
+to year. He will there find the natural irregularities of the rock
+surface in a measure evened over by a vast sheet of snow, from which
+only the summits of the greater mountains rise. He may soon satisfy
+himself that this sheet is of great depth, for here and there it is
+intersected by profound crevices. If the visit is made in the season
+when snow falls, which is commonly during most of the year, he may
+observe, as before noted in our winter's snow, that the deposit,
+though at first flaky, attains at a short distance below the surface a
+somewhat granular character, though the shotlike grains fall apart
+when disturbed. Yet deeper, ordinarily a few feet below the surface,
+these granules are more or less cemented together; the mass thus loses
+the quality of <span class='pagenum'><a name="Page_214" id="Page_214">[Pg 214]</a></span>snow, and begins to appear like a whitish ice. Looking
+down one of the crevices, where the light penetrates to the depth of a
+hundred feet or more, he may see that the bluish hue somewhat
+increases with the depth. A trace of this colour is often visible even
+in the surface snow on the glacier, and sometimes also in our ordinary
+winter fields. In a hole made with a stick a foot or more in depth a
+faint cerulean glimmer may generally be discerned; but the increased
+blueness of the ice as we go down is conspicuous, and readily leads us
+to the conclusion that the air, to which, as we before noted, the
+whiteness of the snow is due, is working out of the mass as the
+process of compaction goes on. In a glacial district this snow mass
+above the melting line is called the <i>n&eacute;v&eacute;</i>.</p>
+
+<p>Remembering that the excess of snow beyond the melting in a <i>n&eacute;v&eacute;</i>
+district amounts, it may be, to some feet of material each year, we
+easily come to the conclusion that the mass works down the slope in
+the manner which it does even where the coating is impermanent. This
+supposition is easily confirmed: by observing the field we find that
+the sheet is everywhere drawing away from the cliffs, leaving a deep
+fissure between the <i>n&eacute;v&eacute;</i> and the precipices. This crevice is called
+by the German-Swiss guides the <i>Bergschrund</i>. Passage over it is
+often one of the most difficult feats to accomplish which the Alpine
+explorer has to undertake. In fact, the very appearance of the
+surface, which is that of a river with continuous down slopes, is
+sufficient evidence that the mass is slowly flowing toward the
+valleys. Following it down, we almost always come to a place where it
+passes from the upper valleys to the deeper gorges which pierce the
+skirts of the mountain. In going over this projection the mass of
+snow-ice breaks to pieces, forming a crowd of blocks which march down
+the slope with much more speed than they journeyed when united in the
+higher-lying fields. In this condition and in this part of the
+movement the snow-ice forms what are called the <i>seracs</i>, or curds, as
+the word means in the French-Swiss <span class='pagenum'><a name="Page_215" id="Page_215">[Pg 215]</a></span>dialect. Slipping and tumbling
+down the steep slope on which the <i>seracs</i> develop, the ice becomes
+broken into bits, often of small size. These fragments are quickly
+reknit into the body of ice, which we shall hereafter term the
+glacier, and in this process the expulsion of the air goes on more
+rapidly than before, and the mass assumes a more transparent icelike
+quality.</p>
+
+<p>The action of the ice in the pressures and strains to which it is
+subjected in joining the main glacier and in the further part of its
+course demand for their understanding a revision of those notions as
+to rigidity and plasticity which we derive from our common experience
+with objects. It is hard to believe that ice can be moulded by
+pressure into any shape without fracturing, provided the motion is
+slowly effected, while at the same time it is as brittle as ice to a
+sudden blow. We see, however, a similar instance of contrasted
+properties in the confection known as molasses candy, a stick of which
+may be indefinitely bent if the flexure is slowly made, but will fly
+to pieces like glass if sharply struck. Ice differs from the sugary
+substance in many ways; especially we should note that while it may be
+squeezed into any form, it can not be drawn out, but fractures on the
+application of a very slight tension. The conditions of its movement
+we will inquire into further on, when we have seen more of its action.</p>
+
+<p>Entering on the lower part of its course, that where it flows into the
+region below the snow line, the ice stream is now confined between the
+walls of the valley, a channel which in most cases has been shaped
+before the ice time, by a mountain torrent, or perhaps by a slower
+flowing river. In this part of its course the likeness of a glacial
+stream to one of fluid water is manifest. We see that it twists with
+the turn of the gorge, widens where the confining walls are far apart,
+and narrows where the space is constricted. Although the surface is
+here and there broken by fractures, it is evident that the movement of
+the frozen current, though slow, is tolerably free. By placing stakes
+<span class='pagenum'><a name="Page_216" id="Page_216">[Pg 216]</a></span>in a row across the axis of a glacier, and observing their movement
+from day to day, or even from hour to hour if a good theodolite is
+used for the purpose, we note that the movement of the stream is
+fastest in the middle parts, as in the case of a river, and that it
+slows toward either shore, though it often happens, as in a stream of
+molten water, that the speediest part of the current is near one side.
+Further observations have indicated that the movement is most rapid on
+the surface and least at the bottom, in which the stream is also
+riverlike. It is evident, in a word, that though the ice is not fluid
+in strict sense, the bits of which it is made up move in substantially
+the manner of fluids&mdash;that is, they freely slip over each other. We
+will now turn our attention to some important features of a detailed
+sort which glaciers exhibit.</p>
+
+<p>If we visit a glacier during the part of the year when the winter
+snows are upon it, it may appear to have a very uninterrupted surface.
+But as the summer heat advances, the mask of the winter coating goes
+away, and we may then see the structure of the ice. First of all we
+note in all valley glaciers such as we are observing that the stream
+is overlaid by a quantity of rocky waste, the greater part of which
+has come down with the avalanches in the manner before described,
+though a small part may have been worn from the bed over which the ice
+flows. In many glaciers, particularly as we approach their
+termination, this sheet of earth and rock materials often covers the
+ice so completely that the novice in such regions finds it difficult
+to believe that the ice is under his feet. If the explorer is minded
+to take the rough scramble, he can often walk for miles on these
+masses of stone without seeing, much less setting foot on any frozen
+water. In some of the Alaskan glaciers this coating may bear a forest
+growth. In general, this material, which is called moraine, is
+distributed in bands parallel to the sides of the glaciers, and the
+strips may amount to a half dozen or more. Those on the sides of the
+ice have evidently been derived from the <span class='pagenum'><a name="Page_217" id="Page_217">[Pg 217]</a></span>precipices which they have
+passed. Those in the middle have arisen from the union of the moraines
+formed in two or more tributary valleys.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f12.jpg" width="640" height="463" alt="Fig. 12.&mdash;Map of glaciers and moraines near Mont Blanc." title="" />
+<span class="figcaption">Fig. 12.&mdash;Map of glaciers and moraines near Mont Blanc.</span>
+</div>
+
+<p>Where the avalanches fall most plentifully, the stones lie buried with
+the snow, and only melt out when the stream attains the region where
+the annual waste of its surface exceeds the snowfall. In this section
+we can see how the progressive melting gradually brings the rocky
+<i>d&eacute;bris</i> into plain view. Here and there we will find a boulder
+perched on a pedestal of ice, which indicates a recent down-wearing of
+the field. A frequent sound in these regions arises from the tumble of
+the stones from their pedestals or the slipping of the masses from the
+sharp ridge which is formed by the protection given to the ice through
+the thick coating of detritus on its surface. These movements of the
+moraines often distribute their waste over the glacier, so that in its
+lower part we can no <span class='pagenum'><a name="Page_218" id="Page_218">[Pg 218]</a></span>longer trace the contributions from the several
+valleys, the whole area being covered by the <i>d&eacute;bris</i>. At the end of
+the ice stream, where its forward motion is finally overcome by the
+warmth which it encounters, it leaves in a rude heap, extending often
+like a wall across the valley, all the coarse fragments which it
+conveys. This accumulation, composed of all the lateral moraines which
+have gathered on the ice by the fall of avalanches, is called the
+terminal moraine. As the ice stream itself shrinks, a portion of the
+detritus next the boundary wall is apt to be left clinging against
+those slopes. It is from the presence of these heaps in valleys now
+abandoned by glaciers that we obtain some information as to the former
+greater extent of glacial action.</p>
+
+<p>The next most noticeable feature is the crevasse. These fractures
+often exist in very great numbers, and constitute a formidable barrier
+in the explorer's way. The greater part of these ruptures below the
+<i>serac</i> zone run from the sides of the stream toward the centre
+without attaining that region. These are commonly pointed up stream;
+their formation is due to the fact that, owing to the swifter motion
+in the central parts of the stream, the ice in that section draws away
+from the material which is moving more slowly next the shore. As
+before noted, these ice fractures when drawn out naturally form
+fissures at right angles to the direction of the strain. In the middle
+portions of the ice other fissures form, though more rarely, which
+appear to depend on local strains brought about through the
+irregularity of the surface over which the ice is flowing.</p>
+
+<p>If the observer is fortunate, he may in his journey over the glacier
+have a chance to see and hear what goes on when crevasses are formed.
+First he will hear a deep, booming sound beneath his feet, which
+merges into a more splintering note as the crevice, which begins at
+the bottom or in the distance, comes upward or toward him. When the
+sound is over, he may not be able to see a trace of the <span class='pagenum'><a name="Page_219" id="Page_219">[Pg 219]</a></span>fracture,
+which at first is very narrow. But if the break intersect any of the
+numerous shallow pools which in a warm summer's day are apt to cover a
+large part of the surface, he may note a line of bubbles rushing up
+through the water, marking the escape of the air from the glacier,
+some remnant of that which is imprisoned in the original snow. Even
+where this indication is wanting, he can sometimes trace the crevice
+by the hissing sound of the air streams where they issue from the ice.
+If he will take time to note what goes on, he can usually in an hour
+or two behold the first invisible crack widen until it may be half an
+inch across. He may see how the surface water hastens down the
+opening, a little river system being developed on the surface of the
+ice as the streams make their way to one or more points of descent. In
+doing this work they excavate a shaft which often becomes many feet in
+diameter, down which their waters thunder to the base of the glacier.
+This well-like opening is called a <i>moulin</i>, or mill, a name which, as
+we shall see, is well deserved from the work which falling waters
+accomplish. Although the institution of the <i>moulin</i> shaft depends
+upon the formation of a crevice, it often happens that as the ice
+moves farther on its journey its walls are again thrust together,
+soldered in the manner peculiar to ice, so that no trace of the
+rupture remains except the shaft which it permitted to form. Like
+everything else in the glacier, the <i>moulin</i> slowly moves down the
+slope, and remains open as long as it is the seat of descending waters
+produced by the summer melting. When it ceases to be kept open from
+the summer, its walls are squeezed together in the fashion that the
+crevices are closed.</p>
+
+<p>Forming here and there, and generally in considerable numbers, the
+crevices of a glacier entrap a good deal of the morainal <i>d&eacute;bris</i>,
+which falls through them to the bottom of the glacier. Smaller bits
+are washed into the <i>moulin</i>, by the streams arising from the melting
+ice, which is brought about by the warm sun of the summer, and
+particularly by the warm rains of that season. On those gla<span class='pagenum'><a name="Page_220" id="Page_220">[Pg 220]</a></span>ciers
+where, owing to the irregularity of the bottom over which the ice
+flows, these fractures are very numerous, it may happen that all the
+detritus brought upon the surface of the glacier by avalanches finds
+its way to the floor of the ice.</p>
+
+<p>Although it is difficult to learn what is going on at the under
+surface of the glacier, it is possible directly and indirectly to
+ascertain much concerning the peculiar and important work which is
+there done. The intrepid explorer may work his way in through the
+lateral fissures, and even with care safely descend some of the
+fissures which penetrate the central parts of a shallow ice stream.
+There, it may be at the depth of a hundred feet or more, he will find
+a quantity of stones, some of which may be in size like to a small
+house held in the body of the ice, but with one side resting upon the
+bed rock. He may be so fortunate as to see the stone actually in
+process of cutting a groove in the bed rock as it is urged forward by
+the motion of the glacier. The cutting is not altogether in the fixed
+material, for the boulder itself is also worn and scored in the work.
+Smaller pebbles are caught in the space between the erratic and the
+motionless rock and ground to bits. If in his explorations the student
+finds his way to the part of the floor on which the waters of a
+<i>moulin</i> fall, he may have a chance to observe how the stones set in
+motion serve to cut the bed rock, forming elongated potholes much as
+in the case of ordinary waterfalls, or at the base of those shafts
+which afford the beginnings of limestone caverns.</p>
+
+<p>The best way to penetrate beneath the glacier is through the arch of
+the stream which always flows from the terminal face of the ice river.
+Even in winter time every large glacier discharges at its end a
+considerable brook, the waters of which have been melted from the ice
+in small part by the outflow of the earth's heat; mainly, however, by
+the warmth produced in the friction of the ice on itself and on its
+bottom&mdash;in other words, by the conversion of that energy of position,
+of which we have often <span class='pagenum'><a name="Page_221" id="Page_221">[Pg 221]</a></span>to speak, into heat. In the summer time this
+subglacial stream is swollen by the surface waters descending through
+the crevices and the <i>moulins</i> which come from them, so that the
+outflow often forms a considerable river, and thus excavates in the
+ice a large or at least a long cavern, the base of which is the bed
+rock. In the autumn, when the superficial melting ceases, this gallery
+can often be penetrated for a considerable distance, and affords an
+excellent way to the secrets of the under ice. The observer may here
+see quantities of the rock material held in the grip of the ice, and
+forced to a rude journey over the bare foundation stones. Now and then
+he may find the glacial mass in large measure made up of stones, the
+admixture extending many feet above the bottom of the cavern, perhaps
+to the very top of the arch. He may perchance find that these stones
+are crushing each other where they are in contact. The result will be
+brought about by the difference in the rate of advance of the ice,
+which moves the faster the higher it is above the surface over which
+it drags, and thus forces the stones on one level over those below.
+Where the waters of the subglacial stream have swept the bed rock
+clean of <i>d&eacute;bris</i> its surface is scored, grooved, and here and there
+polished in a manner which is accomplished only by ice action, though
+some likeness to it is afforded where stones have been swept over for
+ages by blowing sand. Here and there, often in a way which interrupts
+the cavern journey, the shrunken stream, unable to carry forward the
+<i>d&eacute;bris</i>, deposits the material in the chamber, sometimes filling the
+arch so completely that the waters are forced to make a detour. This
+action is particularly interesting, for the reason that in regions
+whence glaciers have disappeared the deposits formed in the old ice
+arches often afford singularly perfect moulds of those caverns which
+were produced by the ancient subglacial streams. These moulds are
+termed <i>eskers</i>.</p>
+
+<p>If the observer be attentive, he will note the fact that the waters
+emerging from beneath the considerable glacier <span class='pagenum'><a name="Page_222" id="Page_222">[Pg 222]</a></span>are very much charged
+with mud. If he will take a glass of the water at the point of escape,
+he will often find, on permitting it to settle, that the sediment
+amounts to as much as one twentieth of the volume. While the greater
+part of this detritus will descend to the bottom of the vessel in the
+course of a day, a portion of it does not thus fall. He may also note
+that this mud is not of the yellowish hue which he is accustomed to
+behold in the materials laid down by ordinary rivers, but has a
+whitish colour. Further study will reveal the fact that the difference
+is due to the lack of oxidation in the case of the glacial detritus.
+River muds forming slowly and during long-continued exposure to the
+action of the air have their contained iron much oxidized, which gives
+them a part of their darkened appearance. Moreover, they are somewhat
+coloured with decayed vegetable matter. The waste from beneath the
+glacier has been quickly separated from the bed rock, all the faces of
+the grains are freshly fractured, and there is no admixture of organic
+matter. The faces of the particles thus reflect light in substantially
+the same way as powdered glass or pulverized ice, and consequently
+appear white.</p>
+
+<p>A little observation will show the student that this very muddy
+character of waters emerging from beneath the glacier is essentially
+peculiar to such streams as we have described. Ascending any of the
+principal valleys of Switzerland, he may note that some of the streams
+flow waters which carry little sediment even in times when they are
+much swollen, while others at all seasons have the whitish colour. A
+little further exploration, or the use of a good map, will show him
+that the pellucid streams receive no contributions of glacial water,
+while those which look as if they were charged with milk come, in part
+at least, from the ice arches. From some studies which the writer has
+made in Swiss valleys, it appears that the amount of erosion
+accomplished on equal areas of similar rock by the descent of the
+waters in the form of a glacier or in that <span class='pagenum'><a name="Page_223" id="Page_223">[Pg 223]</a></span>of ordinary torrents
+differs greatly. Moving in the form of ice, or in the state of
+ice-confined streams, the mass of water applies very many times as
+much of its energy of position to grinding and bearing away the rocks
+as is accomplished where the water descends in its fluid state.</p>
+
+<p>The effect of the intense ice action above noted is rapidly to wear
+away the rocks of the valley in which the glacier is situated. This
+work is done not only in a larger measure but in a different way from
+that accomplished by torrents. In the case of the latter, the stream
+bed is embarrassed by the rubbish which comes into it; only here and
+there can it attack the bed rock by forcing the stones over its
+surface. Only in a few days of heavy rain each year is its work at all
+effective; the greater part of the energy of position of its waters is
+expended in the endless twistings and turnings of its stream, which
+result only in the development of heat which flies away into the
+atmosphere. In the ice stream, owing to its slow movement and to the
+detritus which it forces along the bottom, a vastly greater part of
+the energy which impels it down the slope is applied to rock cutting.
+None of the boulders, even if they are yards in diameter, obstruct its
+motion; small and great alike are to it good instruments wherewith to
+attack the bed rocks. The fragments are never left to waste by
+atmospheric decay, but are to a very great extent used up in
+mechanical work, while the most of the detritus which comes to a
+torrent is left in a coarse state when it is delivered to the stream;
+the larger part of that which the glacier transports is worn out in
+its journey. To a great extent it is used up in attacking the bed
+rock. In most cases the <i>d&eacute;bris</i> in the terminal moraine is evidently
+but a small part of what entered the ice during its journey from the
+uplands; the greater part has been worn out in the rude experiences to
+which it has been subjected.</p>
+
+<p>It is evident that even in the regions now most extensively occupied
+by glaciers the drainage systems have been shaped by the movement of
+ordinary streams&mdash;in other <span class='pagenum'><a name="Page_224" id="Page_224">[Pg 224]</a></span>words, ice action is almost everywhere,
+even in the regions about the poles, an incidental feature in the work
+of water, coming in only to modify the topography, which is mainly
+moulded by the action of fluid water. When, owing to climatal changes,
+a valley such as those of the Alps is occupied by a glacial stream,
+the new current proceeds at once, according to its evident needs, to
+modify the shape of its channel. An ordinary torrent, because of the
+swiftness of its motion, which may, in general, be estimated at from
+three to five miles an hour, can convey away the precipitation over a
+very narrow bed. Therefore its channel is usually not a hundredth part
+as wide as the gorge or valley in which it lies. But when the
+discharge takes place by a glacier, the speed of which rarely exceeds
+four or five feet a day, the ice stream because of its slow motion has
+to fill the trough from side to side, it has to be some thousand times
+as deep and wide as the torrent. The result is that as soon as the
+glacial condition arises in a country the ice streams proceed to
+change the old V-shaped torrent beds into those which have a broad
+U-like form. The practised eye can in a way judge how long a valley
+has been subjected to glacial action by the extent to which it has
+been widened by this process.</p>
+
+<p>In the valleys of Switzerland and other mountain districts which have
+been attentively studied it is evident that glacial action has played
+a considerable part in determining their forms. But the work has been
+limited to that part of the basin in which the ice is abundantly
+provided with cutting tools in the stone which have found their way to
+the base of the stream. In the region of the <i>n&eacute;v&eacute;</i>, where the
+contributions of rocky matter to the surface of the deposit made from
+the few bare cliffs which rise above the sheet of snow is small, the
+snow-ice does no cutting of any consequence. Where it passes over the
+steep at the head of the deep valley into which it drains, and is
+riven into the <i>seracs</i>, such stony matter as it may have gathered is
+allowed to fall to the bottom, and so comes into a <span class='pagenum'><a name="Page_225" id="Page_225">[Pg 225]</a></span>position where it
+may do effective work. From this <i>serac</i> section downward the now
+distinct ice river, being in general below the snow line, has
+everywhere cliffs, on either side from which the contributions of rock
+material are abundant. Hence this part of the glacier, though it is
+the wasting portion of its length, does all the cutting work of any
+consequence which is performed. It is there that the underrunning
+streams become charged with sediment, which, as we have noted, they
+bear in surprising quantities, and it is therefore in this section of
+the valley that the impress of the ice work is the strongest. Its
+effect is not only to widen the valley and deepen it, but also to
+advance the deep section farther up the stream and its tributaries.
+The step in the stream beds which we find at the <i>seracs</i> appears to
+mark the point in the course of the glacier where, owing to the
+falling of stones to its base, as well as to its swifter movements and
+the firmer state of the ice, it does effective wearing.</p>
+
+<p>There are many other features connected with glaciers which richly
+repay the study of those who have a mind to explore in the manner of
+the physicist interested in ice actions the difficult problems which
+they afford; but as these matters are not important from the point of
+view of this work, no mention of them will here be made. We will now
+turn our attention to that other group of glaciers commonly termed
+continental, which now exist about either pole, and which at various
+times in the earth's history have extended far toward the equator,
+mantling over vast extents of land and shallow sea. The difference
+between the ice streams of the mountains and those which we term
+continental depends solely on the areas of the fields and the depth of
+the accumulation. In an ordinary Alpine region the <i>n&eacute;v&eacute;</i> districts,
+where the snow gathers, are relatively small. Owing to the rather
+steep slopes, the frozen water is rapidly discharged into the lower
+valleys, where it melts away. Both in the <i>n&eacute;v&eacute;</i> and in the distinct
+glacier of the lower grounds there are, particularly in the latter,
+project<span class='pagenum'><a name="Page_226" id="Page_226">[Pg 226]</a></span>ing peaks, from which quantities of stone are brought down by
+avalanches or in ordinary rock falls, so that the ice is abundantly
+supplied with cutting tools, which work from its surface down to its
+depths.</p>
+
+<p>As the glacial accumulation grows in depth there are fewer peaks
+emerging from it, and the streams which it feeds rise the higher until
+they mantle over the divides between the valleys. Thus by
+imperceptible stages valley glaciers pass to the larger form, usually
+but incorrectly termed continental. We can, indeed, in going from the
+mountains in the tropics to the poles, note every step in this
+transition, until in Greenland we attain the greatest ice mass in the
+world, unless that about the southern pole be more extensive. In the
+Greenland glacier the ice sheet covers a vast extent of what is
+probably a mountain country, which is certainly of this nature in the
+southern part of the island, where alone we find portions of the earth
+not completely covered by the deep envelope. Thanks to the labours of
+certain hardy explorers, among whom Nansen deserves the foremost
+place, we now know something as to the conditions of this vast ice
+field, for it has been crossed from shore to shore. The results of
+these studies are most interesting, for they afford us a clew as to
+the conditions which prevail over a large part of the earth during the
+Glacial period from which the planet is just escaping, and in the
+earlier ages when glaciation was likewise extensive. We shall
+therefore consider in a somewhat detailed way the features which the
+Greenland glacier presents.</p>
+
+<p>Starting from the eastern shore of that land, if we may thus term a
+region which presents itself mainly in the form of ice, we find next
+the shore a coast line not completely covered with ice and snow, but
+here and there exhibiting peaks which indicate that if the frozen
+mantle were removed the country would appear deeply intersected with
+fiords in the manner exhibited in the regions to the south of
+Greenland or the Scandinavian peninsula. The ice <span class='pagenum'><a name="Page_227" id="Page_227">[Pg 227]</a></span>comes down to the
+sea through the valleys, often facing the ocean for great distances
+with its frozen cliffs. Entering on this seaward portion of the
+glacier, the observer finds that for some distance from the coast line
+the ice is more or less rifted with crevices, the formation of which
+is doubtless due to irregularities of the rock bottom over which it
+moves. These ruptures are so frequent that for some miles back it is
+very difficult to find a safe way. Finally, however, a point is
+attained where these breaks rather suddenly disappear, and thence
+inward the ice rises at the rate of upward slope of a few feet to the
+mile in a broad, nearly smooth incline. In the central portion of the
+region for a considerable part of the territory the ice has very
+little slope. Thence it declines toward the other shore, exhibiting
+the same features as were found on the eastern versant until near the
+coast, when again the surface is beset with crevices which continue to
+the margin of the sea.</p>
+
+<p>Although the explorations of the central field of Greenland are as yet
+incomplete, several of these excursions into or across the interior
+have been made, and the identity of the observations is such that we
+can safely assume the whole region to be of one type. We can
+furthermore run no risk in assuming that what we find in Greenland, at
+least so far as the unbroken nature of the central ice field is
+concerned, is what must exist in every land where the glacial envelope
+becomes very deep. In Greenland it seems likely that the depth of the
+ice is on the average more than half a mile, and in the central part
+of the realm the sheet may well have a much greater profundity; it may
+be nearly a mile deep. The most striking feature&mdash;that of a vast
+unbroken expanse, bordered by a region where the ice is ruptured&mdash;is
+traceable wherever very extensive and presumably deep deposits of ice
+have been examined. As we shall see hereafter, these features teach us
+much as to the conditions of glacial action&mdash;a matter which we shall
+have to examine after we have completed our general <span class='pagenum'><a name="Page_228" id="Page_228">[Pg 228]</a></span>survey as to the
+changes which occur during glacial periods.</p>
+
+<p>In the present state of that wonderful complex of actions which we
+term climate, glaciers are everywhere, so far as our observations
+enable us to judge, generally in process of decrease. In Switzerland,
+although the ancients even in Roman days were in contact with the ice,
+they were so unobservant that they did not even remark that the ice
+was in motion. Only during the last two centuries have we any
+observations of a historic sort which are of value to the geologist.
+Fortunately, however, the signs written on the rock tell the story,
+except for its measurement in terms of years, as clearly as any
+records could give it. From this testimony of the rocks we perceive
+that in the geological yesterday, though it may have been some tens of
+thousands of years ago, the Swiss glaciers, vastly thickened, and with
+their horizontal area immensely expanded, stretched over the Alpine
+country, so that only here and there did any of the sharper peaks rise
+above the surface. These vast glaciers, almost continually united on
+their margins, extended so far that every portion of what is now the
+Swiss Republic was covered by them. Their front lay on the southern
+lowlands of Germany, on the Jura district of France; on the south, it
+stretched across the valley of the Po as far as near Milan. We know
+this old ice front by the accumulations of rock <i>d&eacute;bris</i> which were
+brought to it from the interior of the mountain realm. We can
+recognise the peculiar kinds of stone, and with perfect certainty
+trace them to the bed rock whence they were riven. Moreover, we can
+follow back through the same evidence the stages of retreat of the
+glaciers, until they lost their broad continental character and
+assumed something like their present valley form. Up the valley of any
+of the great rivers, as, for instance, that of the Rh&ocirc;ne above the
+lake of Geneva, we note successive terminal moraines which clearly
+indicate stages in the retreat of the ice when for a time it ceased to
+go backward, or even made a slight temporary <span class='pagenum'><a name="Page_229" id="Page_229">[Pg 229]</a></span>readvance. It is easily
+seen that on such occasions the stones carried to the ice front would
+be accumulated in a heap, while during the time when day by day the
+glacier was retreating the rock waste would be left broadcast over the
+valley.</p>
+
+<p>As we go up from the course of the glacial streams we note that the
+successive moraines have their materials in a progressively less
+decayed state. Far away from the heap now forming, and in proportion
+to the distance, the stones have in a measure rotted, and the heaps
+which they compose are often covered with soil and occupied by
+forests. Within a few miles of the ice front the stones still have a
+fresh aspect. When we arrive within, say, half a mile of the moraine
+now building, we come to the part of the glacial retreat of which we
+have some written or traditional account. This is in general to the
+effect that the wasting of the glaciers is going on in this century as
+it went on in the past. Occasionally periods of heavy snow would
+refresh the ice streams, so that for a little time they pushed their
+fronts farther down the valley. The writer has seen during one of
+these temporary advances the interesting spectacle of ice destroying
+and overturning the soil of a small field which had been planted in
+grain.</p>
+
+<p>It should be noted that these temporary advances of the ice are not
+due to the snowfall of the winter or winters immediately preceding the
+forward movement. So slow is the journey of the ice from the <i>n&eacute;v&eacute;</i>
+field to the end of a long glacier that it may require centuries for
+the store accumulated in the uplands to affect the terminal portion of
+the stream. We know that the bodies of the unhappy men who have been
+lost in the crevices of the glacier are borne forward at a uniform and
+tolerably computable rate until they emerge at the front, where the
+ice melts away. In at least one case the remains have appeared after
+many years in the <i>d&eacute;bris</i> which is contributed to the moraine. On
+account of this slow feeding of the glacial stream, we naturally may
+expect to find, as we do, in fact, that a great <span class='pagenum'><a name="Page_230" id="Page_230">[Pg 230]</a></span>snowfall of many
+years ago, and likewise a period when the winter's contribution has
+been slight, would influence the position of the terminal point of the
+ice stream at different times, according to its length. If the length
+of the flow be five miles, it may require twenty or thirty years for
+the effect to be evident; while if the stream be ten miles long, the
+influence may not be noted in less than threescore years. Thus it
+comes about that at the present time in the same glacial district some
+streams may be advancing while others are receding, though, on the
+whole, the ice is generally in process of shrinkage. If the present
+rate of retreat should be maintained, it seems certain that at the end
+of three centuries the Swiss glaciers as a whole will not have
+anything like their present area, and many of the smaller streams will
+entirely disappear.</p>
+
+<p>Following the method of the illustrious Louis Agassiz, who first
+attentively traced the evidence which shows the geologically recent
+great extension of glaciers by studying the evidence of the action in
+fields they no longer occupy, geologists have now inspected a large
+part of the land areas with a view to finding the proofs of such ice
+work. So far as these indications are concerned, the indications which
+they have had to trace are generally of a very unmistakable character.
+Rarely, indeed, does a skilled student of such phenomena have to
+search in any region for more than a day before he obtains indubitable
+evidence which will enable him to determine whether or not the field
+has recently been occupied by an enduring ice sheet&mdash;one which
+survives the summer season and therefore deserves the name of glacier.
+The indications which he has to consider consist in the direction and
+manner in which the surface materials have been carried, the physical
+conditions of these materials, the shape of the surface of the
+underlying rock as regards its general contour, and the presence or
+absence of scratches and groovings on its surface. As these records of
+ice action are of first importance in dealing with this problem, and
+as they afford excellent subjects for the study <span class='pagenum'><a name="Page_231" id="Page_231">[Pg 231]</a></span>of those who dwell in
+glaciated regions, we shall note them in some detail.</p>
+
+<p>The geologist recognises several ways in which materials may be
+transported on the surface of the earth. They may be cast forth by
+volcanoes, making their journey by being shot through the air, or by
+flowing in lava streams; it is always easy at a glance, save in very
+rare instances, to determine whether fragments have thus been
+conveyed. Again, the detritus may be moved by the wind; this action is
+limited; it only affects dust, sand, and very small pebbles, and is
+easily discriminated. The carriage may be effected by river or marine
+currents; here, again, the size of the fragments moved is small, and
+the order of their arrangement distinctly traceable. The fragments may
+be conveyed by ice rafts; here, too, the observer can usually limit
+the probabilities he has to consider by ascertaining, as he can
+generally do, whether the region which he is observing has been below
+a sea or lake. In a word, the before-mentioned agents of
+transportation are of somewhat exceptional influence, and in most
+cases can, as explanations of rock transportation, be readily
+excluded. When, therefore, the geologist finds a country abundantly
+covered with sand, pebbles, and boulders arranged in an irregular way,
+he has generally only to inquire whether the material has been carried
+by rivers or by glaciers. This discrimination can be quickly and
+critically effected. In the first place, he notes that rivers only in
+their torrent sections can carry large fragments of rock, and that in
+all cases the fragments move down hill. Further, that where deposits
+are formed, they have more or less the form of alluvial deposits. If
+now the observations show that the rock waste occupying the surface of
+any region has been carried up hill and down, across the valleys,
+particularly if there are here and there traces of frontal moraines,
+the geologist is entitled to suppose&mdash;he may, indeed, be sure&mdash;that
+the carriage has been effected by a glacial sheet.</p>
+
+<p>Important corroborative evidence of ice action is gen<span class='pagenum'><a name="Page_232" id="Page_232">[Pg 232]</a></span>erally to be
+found by inspecting the bed rock below the detritus, which indicates
+glacial action. Even if it be somewhat decayed, as is apt to be the
+case where the ice sheet long since passed away, the bed rock is
+likely to have a warped surface; it is cast into ridges and furrows of
+a broad, flowing aspect, such as liquid water never produces, which,
+indeed, can only be created by an ice sheet moving over the surface,
+cutting its bed in proportion to the hardness of the material.
+Furthermore, if the bed rock have a firm texture, and be not too much
+decayed, we almost always find upon it grooves or scratches, channels
+carved by the stones embedded in the body of the ice, and drawn by its
+motion over the fixed material. Thus the proof of glacial extension in
+the last ice epoch is made so clear that accurate maps can be prepared
+showing the realm of its action. This task is as yet incomplete,
+although it is already far advanced.</p>
+
+<p>While the study of glaciers began in Europe, inquiries concerning
+their ancient extension have been carried further and with more
+accuracy in North America than in any other part of the world. We may
+therefore well begin our description of the limits of the ice sheets
+with this continent. Imagining a seafarer to have approached America
+by the North Atlantic, as did the Scandinavians, and that his voyage
+came perhaps a hundred thousand years or more before that of Leif
+Ericsson, he would have found an ice front long before he attained the
+present shores of the land. This front may have extended from south of
+Greenland, off the shores of the present Grand Banks of Newfoundland,
+thence and westward to central or southern New Jersey. This cliff of
+ice was formed by a sheet which lay on the bottom of the sea. On the
+New Jersey coast the ice wall left the sea and entered on the body of
+the continent. We will now suppose that the explorer, animated with
+the valiant scientific spirit which leads the men of our day to seek
+the poles, undertook a land journey along the ice front across the
+<span class='pagenum'><a name="Page_233" id="Page_233">[Pg 233]</a></span>continent. From the New Jersey coast the traveller would have passed
+through central Pennsylvania, where, although there probably detached
+outlying glaciers lying to the southward as far as central Virginia,
+the main front extended westward into the Ohio Valley. In southern
+Ohio a tongue of the ice projected southwardly until it crossed the
+Ohio River, where Cincinnati now lies, extending a few miles to the
+southward of the stream. Thence it deflected northwardly, crossing the
+Mississippi, and again the Missouri, with a tongue or lobe which went
+far southward in that State. Then again turning to the northwest, it
+followed in general the northern part of the Missouri basin until it
+came to within sight of the Rocky Mountains. There the ice front of
+the main glacier followed the trend of the mountains at some distance
+from their face for an unknown extent to the northward. In the
+Cordilleras, as far south as southern Colorado, and probably in the
+Sierra Nevada to south of San Francisco, the mountain centres
+developed local glaciers, which in some places were of very great
+size, perhaps exceeding any of those which now exist in Switzerland.
+It will thus be seen that nearly one half of the present land area of
+North America was beneath a glacial covering, though, as before noted,
+the region about the Gulf of Mexico may have swayed upward when the
+northern portion of the land was borne down by the vast load of ice
+which rested upon it. Notwithstanding this possible addition to the
+land, our imaginary explorer would have found the portion of the
+continent fit for the occupancy of life not more than half as great as
+it is at present.</p>
+
+<p>In the Eurasian continent there was no such continuous ice sheet as in
+North America, but the glaciers developed from a number of different
+centres, each moving out upon the lowlands, or, if its position was
+southern, being limited to a particular mountain field. One of these
+centres included Scandinavia, northern Germany, Great Britain about as
+far south as London, and a large part of Ireland, the ice covering the
+intermediate seas and extending to <span class='pagenum'><a name="Page_234" id="Page_234">[Pg 234]</a></span>the westward, so that the passage
+of the North Atlantic was greatly restricted between this ice front
+and that of North America. Another centre, before noted, was formed in
+the Alps; yet another, of considerable area, in the Pyrenees; other
+less studied fields existed in the Apennines, in the Caucasus, the
+Ural, and the other mountains of northern Asia. Curiously enough,
+however, the great region of plains in Siberia does not appear to have
+been occupied by a continuous ice sheet, though the similar region in
+North America was deeply embedded in a glacier. Coincident with this
+development of ice in the eastern part of the continent, the ice
+streams of the Himalayan Mountains, some of which are among the
+greatest of our upland glaciers, appear to have undergone but a
+moderate extension. Many other of the Eurasian highlands were probably
+ice-bound during the last Glacial period, but our knowledge concerning
+these local fields is as yet imperfect.</p>
+
+<p>In the southern hemisphere the lands are of less extent and, on the
+whole, less studied than in the northern realm. Here and there where
+glaciers exist, as in New Zealand and in the southern part of South
+America, observant travellers have noticed that these ice fields have
+recently shrunk away. Whether the time of greatest extension and of
+retreat coincided with that of the ice sheets in the north is not yet
+determined; the problem, indeed, is one of some difficulty, and may
+long remain undecided. It seems, however, probable that the glaciers
+of the southern hemisphere, like those in the north, are in process of
+retreat. If this be true, then their time of greatest extension was
+probably the same as that of the ice sheets about the southern pole.
+From certain imperfect reports which we have concerning evidences of
+glaciation in Central America and in the Andean district in the
+northern part of South America, it seems possible that at one time the
+upland ice along the Cordilleran chain existed from point to point
+along that system of elevations, so that the widest interval <span class='pagenum'><a name="Page_235" id="Page_235">[Pg 235]</a></span>between
+the fields of permanent snow with their attendant glaciers did not
+much exceed a thousand miles.</p>
+
+<p>Observing the present gradual retreat of those ice remnants which
+remain mere shreds and patches of the ancient fields, it seems at
+first sight likely that the extension and recession of the great
+glaciers took place with exceeding slowness. Measured in terms of
+human life, in the manner in which we gauge matters of man's history,
+this process was doubtless slow. There are reasons, however, to
+believe that the coming and going were, in a geological sense, swift;
+they may have, indeed, been for a part of the time of startling
+rapidity. Going back to the time of geological yesterday, before the
+ice began its development in the northern hemisphere, all the evidence
+we can find appears to indicate a temperate climate extending far
+toward the north pole. The Miocene deposits found within twelve
+degrees, or a little more than seven hundred miles, of the north pole,
+and fairly within the realm of lowest temperature which now exists on
+the earth, show by the plant remains which they contain that the
+conditions permitted the growth of forests, the plants having a
+tolerably close resemblance to those which now freely develop in the
+southern portion of the Mississippi Valley. Among them there are
+species which had the habit of retaining their broad, rather soft
+leaves throughout the winter season. The climate appears, in a word,
+to have been one where the mean annual temperature must have been
+thirty degrees or more higher than the present average of that realm.
+Although such conditions near the sea level are not inconsistent with
+the supposition that glaciers existed in the higher mountains of the
+north, they clearly deny the possibility of the realm being occupied
+by continental glaciers.</p>
+
+<p>Although the Pliocene deposits formed in high latitudes have to a
+great extent been swept away by the subsequent glacial wearing, they
+indicate by their fossils a climatal change in the direction of
+greater cold. We trace this <span class='pagenum'><a name="Page_236" id="Page_236">[Pg 236]</a></span>change, though obscurely, in a
+progressive manner to a point where the records are interrupted, and
+the next interpretable indication we have is that the ice sheet had
+extended to somewhere near the limits which we have noted. We are then
+driven to seek what we can concerning the sojourn of the ice on the
+land by the amount of wearing which it has inflicted upon the areas
+which it occupied. This evidence has a certain, though, as we shall
+see, a limited value.</p>
+
+<p>When the students of glacial action first began the great task of
+interpreting these records, they were led to suppose that the amount
+of rock cutting which was done by the ice was very great. Observing
+what goes on, in the manner we have noted, beneath a valley glacier
+such as those of Switzerland, they saw that the ice work went on
+rapidly, and concluded that if the ice remained long at work in a
+region it must do a vast deal of erosion. They were right in a part of
+their premises, but, as we shall see, probably in another part wrong.
+Looking carefully over the field where the ice has operated, we note
+that, though at first sight the area appears to have lost all trace of
+its preglacial river topography, this aspect is due mainly to the
+irregular way in which the glacial waste is laid down. Close study
+shows us that we may generally trace the old stream valleys down to
+those which were no larger than brooks. It is true that these channels
+are generally and in many places almost altogether filled in with
+rubbish, but a close study of the question has convinced the writer,
+and this against a previous view, that the amount of erosion in New
+England and Canada, where the work was probably as great as anywhere,
+has not on the average exceeded a hundred feet, and probably was much
+less than that amount.</p>
+
+<p>Even in the region north of Lake Ontario, over which the ice was deep
+and remained for a long time, the amount of erosion is singularly
+small. Thus north of Kingston the little valleys in the limestone
+rocks which were cut by the preglacial streams, though somewhat
+encumbered with <span class='pagenum'><a name="Page_237" id="Page_237">[Pg 237]</a></span>drift, remain almost as distinct as they are on
+similar strata in central Kentucky, well south of the field which the
+ice occupied. In fact, the ice sheet appears to have done the greatest
+part of its work and to have affected the surface most in the belt of
+country a few hundred miles in width around the edges of the sheet. It
+was to be expected that in a continental glacier, as in those of
+mountain valleys, the most of the <i>d&eacute;bris</i> should be accumulated about
+the margin where the materials dropped from the ice. But why the
+cutting action should be greatest in that marginal field is not at
+first sight clear. To explain this and other features as best we may,
+we shall now consider the probable history of the great ice march in
+advance and retreat, and then take up the conditions which brought
+about its development and its disappearance.</p>
+
+<p>Ice is in many ways the most remarkable substance with which the
+physicist has to deal, and among its eminent peculiarities is that it
+expands in freezing, while the rule is that substances contract in
+passing from the fluid to the solid state. On this account frozen
+water acts in a unique manner when subjected to pressure. For each
+additional atmosphere of pressure&mdash;a weight amounting to about fifteen
+pounds to the square inch&mdash;the temperature at which the ice will melt
+is lowered to the amount of sixteen thousandths of a degree
+centigrade. If we take a piece of ice at the temperature of freezing
+and put upon it a sufficient weight, we inevitably bring about a small
+amount of melting. Where we can examine the mass under favourable
+conditions, we can see the fluid gather along the lines of the
+crystals or other bits of which the ice is composed. We readily note
+this action by bringing two pieces of ice together with a slight
+pressure; when the pressure is removed, they will adhere. The adhesion
+is brought about not by any stickiness of the materials, for the
+substance has no such property. It is accomplished by melting along
+the line of contact, which forms a film of water, that at once
+refreezes when the pressure is withdrawn. When <span class='pagenum'><a name="Page_238" id="Page_238">[Pg 238]</a></span>a firm snowball is
+made by even pressing snow, innumerable similar adhesions grow up in
+the manner described. The fact is that, given ice at the temperature
+at which it ordinarily forms, pressure upon it will necessarily
+develop melting.</p>
+
+<p>The consequences of pressure melting as above described are in
+glaciers extremely complicated. Because the ice is built into the
+glacier at a temperature considerably below the freezing point, it
+requires a great thickness of the mass before the superincumbent
+weight is sufficient to bring about melting in its lower parts. If we
+knew the height at which a thermometer would have stood in the surface
+ice of the ancient glacier which covered the northern part of North
+America, we could with some accuracy compute how thick it must have
+been before the effect of pressure alone would have brought about
+melting; but even then we should have to reckon the temperature
+derived from the grinding of the ice over the floor and the crushing
+of rocks there effected, as well as the heat which is constantly
+though slowly coming forth from the earth's interior. The result is
+that we can only say that at some depth, probably less than a mile,
+the slowly accumulating ice would acquire such a temperature that,
+subjected to the weight above it, the material next the bottom would
+become molten, or at least converted into a sludgelike state, in which
+it could not rub against the bottom, or move stones in the manner of
+ordinary glaciers.</p>
+
+<p>As fast as the ice assumed this liquid or softened state, it would be
+squeezed out toward the region where, because of the thinning of the
+glacier, it would enter a field where pressure melting did not occur.
+It would then resume the solid state, and thence journey to the margin
+of the ice in the ordinary manner. We thus can imagine how such a
+glacier as occupied the northern part of this continent could have
+moved from the central parts toward its periphery, as we can not do if
+we assume that the glacier everywhere lay upon the bed rock. There is
+no slope from Lake<span class='pagenum'><a name="Page_239" id="Page_239">[Pg 239]</a></span> Erie to the Ohio River at Cincinnati. Knowing that
+the ice moved down this line, there are but two methods of accounting
+for its motion: either the slope of the upper surface to the northward
+was so steep that the mass would have been thus urged down, the upper
+parts dragging the bottom along with them, or the ice sheet for the
+greater part of its extent rested upon pressure-molten water, or
+sludge ice, which was easily squeezed out toward the front. The first
+supposition appears inadmissible, for the reason that the ice would
+have to be many miles deep at Hudson Bay in order that its upper
+surface should have slope enough to overcome the rigidity of the
+material and bring about the movement. We know that any such depth is
+not supposable.</p>
+
+<p>The recent studies in Greenland supply us with strong corroborative
+evidence for the support of the view which is here urged. The wide
+central field of that area, where the ice has an exceeding slight
+declivity, and is unruptured by crevices, can not be explained except
+on the supposition that it rests on pressure-molten water. The thinner
+section next the shore, where the glacier is broken up by those
+irregular movements which its wrestle with the bottom inevitably
+induces, shows that there it is in contact with the bed rock, for it
+behaves exactly as do the valley glaciers of like thickness.</p>
+
+<p>The view above suggested as to the condition of continental glaciers
+enables us to explain not only their movements, but the relatively
+slight amount of wearing which they brought about on the lands they
+occupied. Beginning to develop in mountain regions, or near the poles
+on the lowlands, these sheets, as soon as they attained the thickness
+where the ice at their bottom became molten, would rapidly advance for
+great distances until they attained districts where the melting
+exceeded the supply of frozen material. In this excursion only the
+marginal portion of the glacier would do erosive work. This would
+evidently be continued for the greatest amount of time near the front
+<span class='pagenum'><a name="Page_240" id="Page_240">[Pg 240]</a></span>or outer rim of the ice field, for there, we may presume, that for
+the longest time the cutting rim would rest upon the bed rock of the
+country. As the ice receded, this rim would fall back; thus in the
+retreat as in the advance the whole of the field would be subjected to
+a certain amount of erosion. On this supposition we should expect to
+find that the front of a continental glacier, fed with pressure-molten
+water from all its interior district, which became converted into ice,
+would attain much warmer regions than the valley streams, where all
+the flow took place in the state of ice, and, furthermore, that the
+speed of the going on the margin would be much more rapid than in the
+Alpine streams. These suppositions are well borne out by the study of
+existing continental ice sheets, which move with singular rapidity at
+their fronts, and by the ancient glaciers, which evidently extended
+into rather warm fields. Thus, when the ice front lay at the site of
+Cincinnati, at six hundred feet above the sea, there were no glaciers
+in the mountains of North Carolina, though those rise more than five
+thousand feet higher in the air, and are less than two hundred miles
+farther south. It is therefore evident that the continental glacier at
+this time pushed southward into a comparatively warm country in a way
+that no stream moving in the manner of a valley glacier could possibly
+have done.</p>
+
+<p>The continental glaciers manage in many cases to convey detritus from
+a great distance. Thus, when the ice sheet advanced southwardly from
+the regions north of the Great Lakes, they conveyed quantities of the
+<i>d&eacute;bris</i> from that section as far south as the Ohio River. In part
+this rubbish was dragged forward by the ice as the sheet advanced; in
+part it was urged onward by the streams of liquid water formed by the
+ordinary process of ice melting. Such subglacial rivers appear to have
+been formed along the margins of all the great glaciers. We can
+sometimes trace their course by the excavation which they have made,
+but more commonly by the long ridges of stratified <span class='pagenum'><a name="Page_241" id="Page_241">[Pg 241]</a></span>sand and gravel
+which were packed into the caverns excavated by these subglacial
+rivers, which are known to glacialists as <i>eskers</i>, or as serpent
+kames. In many cases we can trace where these streams flowed up stream
+in the old river valleys until they discharged over their head waters.
+Thus in the valley of the Genesee, which now flows from Pennsylvania,
+where it heads against the tributaries of the Ohio and Susquehanna, to
+Lake Ontario, there was during the Glacial epoch a considerable river
+which discharged its waters into those of the Ohio and the Susquehanna
+over the falls at the head of its course.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a name="img08"></a>
+<img src="images/p8.jpg" width="640" height="392" alt="Front of Muir Glacier, showing ice entering the sea;
+also small icebergs." title="" />
+<span class="caption">Front of Muir Glacier, showing ice entering the sea;
+also small icebergs.</span>
+</div>
+
+<p>The effect of widespread glacial action on a country such as North
+America appears to have been, in the first place, to disturb the
+attitude of the land by bearing down portions of its surface, a
+process which led to the uprising of other parts which lay beyond the
+realm of the ice. Within the field of glaciation, so far as the ice
+rested bodily on the surface, the rocks were rapidly worn away. A
+great deal of the <i>d&eacute;bris</i> was ground to fine powder, and went far
+with the waters of the under-running streams. A large part was
+entangled in the ice, and moved forward toward the front of the
+glacier, where it was either dropped at the margin or, during the
+recession of the glacier, was laid upon the surface as the ice melted
+away. The result of this erosion and transportation has been to change
+the conditions of the surface both as regards soil and drainage. As
+the reader has doubtless perceived, ordinary soil is, outside of the
+river valleys, derived from the rock beneath where it lies. In
+glaciated districts the material is commonly brought from a
+considerable distance, often from miles away. These ice-made soils are
+rarely very fertile, but they commonly have a great endurance for
+tillage, and this for the reason that the earth is refreshed by the
+decay of the pebbles which they contain. Moreover, while the tillable
+earth of other regions usually has a limited depth, verging downward
+into the semisoil or subsoil which represent the little changed bed
+rocks, glacial deposits can <span class='pagenum'><a name="Page_242" id="Page_242">[Pg 242]</a></span>generally be ploughed as deeply as may
+prove desirable.</p>
+
+<p>The drainage of a country recently affected by glaciers is always
+imperfect. Owing to the irregular erosion of the bed rocks, and to the
+yet more irregular deposition of the detritus, there are very numerous
+lakes which are only slowly filled up or by erosion provided with
+drainage channels. Though several thousand years have passed by since
+the ice disappeared from North America, the greater part of the area
+of these fresh-water basins remains, the greater number of them,
+mostly those of small size, have become closed.</p>
+
+<p>Where an ice stream descends into the sea or into a large lake, the
+depth of which is about as great as the ice is thick, the relative
+lightness of the ice tends to make it float, and it shortly breaks off
+from the parent mass, forming an iceberg. Where, as is generally the
+case in those glaciers which enter the ocean, a current sweeps by the
+place where the berg is formed, it may enter upon a journey which may
+carry the mass thousands of miles from its origin. The bergs separated
+from the Greenland glaciers, and from those about the south pole, are
+often of very great size; sometimes, indeed, they are some thousand
+feet in thickness, and have a length of several miles. It often
+happens that these bergs are formed of ice, which contains in its
+lower part a large amount of rock <i>d&eacute;bris</i>. As the submerged portion
+of the glacier melts in the sea water, these stones are gradually
+dropped to the bottom, so that the cargo of one berg may be strewed
+along a line many hundred miles in length. It occasionally happens
+that the ice mass melts more slowly in those parts which are in the
+air than in its under-water portions. It thus becomes top-heavy and
+overturns, in which case such stony matter as remains attains a
+position where it may be conveyed for a greater distance than if the
+glacier were not capsized. It is likely, indeed, that now and then
+fragments of rock from Greenland are dropped on the ocean floor in the
+part of the<span class='pagenum'><a name="Page_243" id="Page_243">[Pg 243]</a></span> Atlantic which is traversed by steamers between our
+Atlantic ports and Great Britain.</p>
+
+<p>Except for the risks which they bring to navigators, icebergs have no
+considerable importance. It is true they somewhat affect the
+temperature of sea and air, and they also serve to convey fragments of
+stone far out to sea in a way that no other agent can effect; but, on
+the whole, their influence on the conditions of the earth is
+inconsiderable.</p>
+
+<p>Icebergs in certain cases afford interesting indices as to the motion
+of oceanic currents, which, though moving swiftly at a depth below the
+surface, do not manifest themselves on the plain of the sea. Thus in
+the region about Greenland, particularly in Davis Strait, bergs have
+been seen forcing their way southward at considerable speed through
+ordinary surface ice, which was either at rest or moving in the
+opposite direction. The train of these bergs, which moves upward from
+the south polar continent, west of Patagonia, indicates also in a very
+emphatic way the existence of a very strong northward-setting current
+in that part of the ocean.</p>
+
+<hr style='width: 45%;' />
+
+<p>We have now to consider the causes which could bring about such great
+extensions of the ice sheet as occurred in the last Glacial period.
+Here again we are upon the confines of geological knowledge, and in a
+field where there are no well-cleared ways for the understanding. In
+facing this problem, we should first note that those who are of the
+opinion that a Glacial period means a very cold climate in the regions
+where the ice attained its extension are probably in error. Natural as
+it may seem to look for exceeding cold as the cause of glaciation, the
+facts show us that we can not hold this view. In Siberia and in the
+parts of North America bordering on the Arctic Sea the average cold is
+so intense that the ground is permanently frozen&mdash;as it is, for
+instance, in the Klondike district&mdash;to the depth of hundreds of feet,
+only the surface thawing out <span class='pagenum'><a name="Page_244" id="Page_244">[Pg 244]</a></span>during the warm summers. All this region
+is cold enough for glaciers, but there is not sufficient snowfall to
+maintain them. On the other hand, in Greenland, and in a less though
+conspicuous degree in Scandinavia, where the waters of the North
+Atlantic somewhat diminish the rigour of the cold, and at the same
+time bring about a more abundant snowfall, the two actions being
+intimately related, we have very extensive glaciers. Such facts, which
+could be very much extended, make it clear that the climate of glacial
+periods must have been characterized by a great snowfall, and not by
+the most intense cold.</p>
+
+<p>It is evident that what would be necessary again to envelop the boreal
+parts of North America with a glacial sheet would not be a
+considerable decrease of heat, but an increase in the winter's
+contribution of frozen water. Even if the heat released by this
+snowfall elevated the average temperature of the winter, as it
+doubtless would in a considerable measure, it would not melt off the
+snow. That snowfall tends to warm the air by setting free the heat
+which was engaged in keeping the water in a state of vapour is
+familiarly shown by the warming which attends an ordinary snowstorm.
+Even if the fall begin with a temperature of about 0&deg; Fahr., the air
+is pretty sure to rise to near the freezing point.</p>
+
+<p>It is evident that no great change of temperature is required in order
+to bring about a very considerable increase in the amount of snowfall.
+In the ordinary succession of seasons we often note the occurrence of
+winters during which the precipitation of snow is much above the
+average, though it can not be explained by a considerable climatal
+change. We have to account for these departures from the normal
+weather by supposing that the atmospheric currents bring in more than
+the usual amount of moisture from the sea during the period when great
+falls of snow occur. In fact, in explaining variations in the humidity
+of the land, whether those of a constant nature or those that are to
+be termed accidental, we have always to look <span class='pagenum'><a name="Page_245" id="Page_245">[Pg 245]</a></span>to those features which
+determine the importation of vapour from the great field of the ocean
+where it enters the air. We should furthermore note that these
+peculiarities of climate are dependent upon rather slight geographic
+accidents. Thus the snowfall of northern Europe, which serves to
+maintain the glaciation of that region, and, curiously enough, in some
+measure its general warmth, depends upon the movement of the Gulf
+Stream from the tropics to high latitudes. If by any geographical
+change, such as would occur if Central America were lowered so as to
+make a free passage for its waters to the westward, the glaciers of
+Greenland and of Scandinavia would disappear, and at the same time the
+temperature of those would be greatly lowered. Thus the most evident
+cause of glaciation must be sought in those alterations of the land
+which affect the movement of the oceanic currents.</p>
+
+<p>Applying this principle to the northern hemisphere, we can in a way
+imagine a change which would probably bring about a return of such an
+ice period as that from which the boreal realm is now escaping. Let us
+suppose that the region of not very high land about Bering Strait
+should sink down so as to afford the Kuro Siwo, or North Pacific
+equivalent of our Gulf Stream, an opportunity to enter the Arctic Sea
+with something like the freedom with which the North Atlantic current
+is allowed to penetrate to high latitudes. It seems likely that this
+Pacific current, which in volume and warmth is comparable to that of
+the Atlantic, would so far elevate the temperature of the arctic
+waters that their wide field would be the seat of a great evaporation.
+Noting once again the fact that the Greenland glaciers, as well as
+those of Norway, are supplied from seas warmed by the Gulf Stream, we
+should expect the result of this change would be to develop similar
+ice fields on all the lands near that ocean.</p>
+
+<p>Applying the data gathered by Dr. Croll for the Gulf Stream, it seems
+likely that the average annual temperature <span class='pagenum'><a name="Page_246" id="Page_246">[Pg 246]</a></span>induced in the Arctic Sea
+by the free entrance of the Japan current would be between 20&deg; and 30&deg;
+Fahr. This would convert this wide realm of waters into a field of
+great evaporation, vastly increasing the annual precipitation. It
+seems also certain that the greater part of this precipitation would
+be in the form of snow. It appears to the writer that this cause alone
+may be sufficient to account for the last Glacial period in the
+northern hemisphere. As to the probability that the region about
+Bering Strait may have been lowered in the manner required by this
+view, it may be said that recent studies on the region about Mount St.
+Elias show that during or just after the ice epoch the shores in that
+portion of Alaska were at least four thousand feet lower than at
+present. As this is but a little way from the land which we should
+have to suppose to be lowered in order to admit the Japan current, we
+could fairly conclude that the required change occurred. As for the
+cause of the land movement, geologists are still in doubt. They know,
+however, that the attitudes of the land are exceedingly unstable, and
+that the shores rarely for any considerable time maintain their
+position. It is probable that these swayings of the earth's surface
+are due to ever-changing combinations of the weight in different parts
+of the crust and the strains arising from the contraction of its inner
+parts.</p>
+
+<p>In the larger operations of Nature the effects which we behold,
+however simple, are rarely the products of a single cause. In fact,
+there are few actions so limited that they can fairly be referred to
+one influence. It is therefore proper to state that there are many
+other actions besides those above noted which probably enter into
+those complicated equations which determine the climatal conditions of
+the earth. To have these would carry us into difficult and speculative
+inquiries.</p>
+
+<p>As before remarked, all the regions which have been subjected to
+glaciation are still each year brought temporarily into the glacial
+state. This fact serves to show <span class='pagenum'><a name="Page_247" id="Page_247">[Pg 247]</a></span>us that the changes necessary to
+produce great ice sheets are not necessarily of a startling nature,
+however great the consequences may be. Assuming, then, that relatively
+slight alterations of climate may cause the ice sheet to come and go,
+we may say that all the influences which have been suggested by the
+students of glaciation, and various other slighter causes which can
+not be here noted, may have co-operated to produce the peculiar
+result. In this equation geographic change has affected the course of
+the ocean currents, and has probably been the most influential, or at
+least the commonest, cause to which we must attribute the extension of
+ice sheets. Next, alterations of the solar heat may be looked to as a
+change-bringing action; unfortunately, however, we have no direct
+evidence that this is an efficient cause. Thirdly, the variations in
+the eccentricity of the earth's orbit, combined with the precession of
+the equinoxes and the rotation of the apsides, may be regarded as
+operative. The last of all, changes in the constitution of the
+atmosphere, have to be taken into account. To these must be added, as
+before remarked, many less important actions which influence this
+marvellously delicate machine, the work of which is expressed in the
+phenomena assembled under the name of climate.</p>
+
+<p>Evidence is slowly accumulating which serves to show that glacial
+periods of greater or less importance have been of frequent occurrence
+at all stages in the history of the earth of which we have a distinct
+record. As these accidents write their history upon the ground alone,
+and in a way impermanently, it is difficult to trace the ice times of
+ancient geological periods. The scratches on the bed rocks, and the
+accumulations of detritus formed as the ice disappeared, have alike
+been worn away by the agents of decay. Nevertheless, we can trace here
+and there in the older strata accumulations of pebbly matter often
+containing large boulders, which clearly were shaped and brought
+together by glacial action. These are found in <span class='pagenum'><a name="Page_248" id="Page_248">[Pg 248]</a></span>some instances far
+south of the region occupied by the glaciers during the last ice
+epoch. They occur in rocks of the Cambrian or Silurian age in eastern
+Tennessee and western North Carolina; they are also found in India
+beyond the limits to which glaciers have attained in modern times.</p>
+
+<p>In closing this inadequate account of glacial action, a story which
+for its complete telling would require many volumes, it is well for
+the reader to consider once again how slight are the changes of
+climate which may alternately withdraw large parts of the land from
+the uses of life, and again quickly restore the fields to the service
+of plants and animals. He may well imagine that these changes, by
+driving living creatures to and fro, profoundly affect the history of
+their development. This matter will be dealt with in the volume
+concerning the history of organic beings.</p>
+
+<p>When the ice went off from the northern part of this continent, the
+surface of the country, which had been borne down by the weight of the
+glacier, still remained depressed to a considerable depth below the
+level of the sea, the depression varying from somewhere about one
+hundred feet in southern New England to a thousand feet or more in
+high latitudes. Over this region, which lay beneath the level of the
+sea, the glacier, when it became thin enough to float, was doubtless
+broken up into icebergs, in the manner which we now behold along the
+coast of Greenland. Where the shore was swept by a strong current,
+these bergs doubtless drifted away; but along the most of the coast
+line they appear to have lain thickly grouped next the shores,
+gradually delivering their loads of stones and finer <i>d&eacute;bris</i> to the
+bottom. These masses of floating ice in many cases seem to have
+prevented the sea waves from attaining the shore, and thus hindered
+the formation of those beaches which in their present elevated
+condition enable us to interpret the old position of the sea along
+coast lines which have been recently elevated. Here <span class='pagenum'><a name="Page_249" id="Page_249">[Pg 249]</a></span>and there,
+however, from New Jersey to Greenland, we find bits of these ancient
+shores which clearly tell the story of that down-sinking of the land
+beneath the burden of the ice which is such an instructive feature in
+the history of that period.</p>
+
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_250" id="Page_250">[Pg 250]</a></span></p>
+<h1><a name="CHAPTER_VII" id="CHAPTER_VII"></a>CHAPTER &nbsp; VII.<br/>
+<span class="subtitle smcap">the work of underground water.</span></h1>
+
+
+<p>We have already noted two means by which water finds its way
+underground. The simplest and largest method by which this action is
+effected is by building in the fluid as the grains of the rock are
+laid down on the floors of seas or lakes. The water thus imprisoned is
+firmly inclosed in the interstices of the stone, it in time takes up
+into its mass a certain amount of the mineral materials which are
+contained in the deep-buried rocks. The other portion of the ground
+water&mdash;that with which we are now to be specially concerned&mdash;arises
+from the rain which descends into the crevices of the earth; it is
+therefore peculiar to the lands. For convenience we shall term the
+original embedded fluid <i>rock water</i>, and that which originates from
+the rain <i>crevice water</i>, the two forming the mass of the earth water.</p>
+
+<p>The crevice water of the earth, although forming at no time more than
+a very small fraction of the hidden fluid, is an exceedingly potent
+geological agent, doing work which, though unseen, yet affords the
+very foundations on which rest the life alike of land and sea. When
+this water enters the earth, though it is purified of all mineral
+materials, it has already begun to acquire a share of a gaseous
+substance, carbonic acid, or, as chemists now term it, carbon dioxide,
+which enables the fluid to begin its r&ocirc;le of marvellous activities. In
+its descent as rain, probably even before it was gathered in drops in
+the cloud realm, <span class='pagenum'><a name="Page_251" id="Page_251">[Pg 251]</a></span>the water absorbs a certain portion of this gas from
+the atmosphere. Entering the realm of the soil, where the decaying
+organic matter plentifully gives forth carbon dioxide, a further store
+of the gas is acquired. At the ordinary pressure of the air, water may
+take in many times its bulk of the gas.</p>
+
+<p>The immediate effect of carbonic acid when it is absorbed by water is
+greatly to increase the capacity which that fluid has for taking
+mineral matters into solution. When charged with this gas, in the
+measure in which it may be in the soil, water is able to dissolve
+about fifty times as much limestone as it can in its perfectly pure
+form take up. A familiar instance of this peculiar capacity which the
+gas gives may often be seen where the water from a soda-water fountain
+drips upon the marble slab beneath. In a few years this slab will be
+considerably corroded, though pure water would in the same time have
+had no effect upon it.</p>
+
+<p>The first and by far the most important effect of crevice water is
+exercised upon the soil, which is at once the product of this action,
+and the laboratory where the larger part of the work is done.
+Penetrating between the grains of the detrital covering, held in large
+quantities in the coating, and continually in slow motion, the
+gas-charged water takes a host of substances into solution, and brings
+them into a condition where they may react upon each other in the
+chemical manner. These materials are constantly being offered to the
+roots of plants and brought in contact with the underlying rock which
+has not passed into the state of soil. The changes induced in this
+stony matter lead to its breaking up, or at least to its softening to
+the point where the roots can penetrate it and complete its
+destruction. Thus it comes about that the water which to a great
+extent divides the rocks into the state of soil, which is continually
+wearing away the material on the surface, or leaching it out through
+the springs, is also at work in restoring the layer from beneath.</p>
+
+<p><span class='pagenum'><a name="Page_252" id="Page_252">[Pg 252]</a></span></p><p>The greater part of the water which enters the soil does not
+penetrate to any great depth in the underlying rocks, but finds its
+way to the surface after no long journey in the form of small springs.
+Generally those superficial springs do not emerge through distinct
+channels, but move, though slowly, in a massive way down the slopes
+until they enter a water course. Along the banks of any river, however
+small, or along the shores of the sea, a pit a few inches deep just
+above the level of the water will be quickly filled by a flow from
+this sheet which underlies the earth. At a distance from the stream
+this sheet spring is in contact with the bed rocks, and may be many
+feet below the surface, but it comes to the level of the river or the
+sea near their margins. Here and there the shape of the bed rocks,
+being like converging house roofs, causes the superficial springs to
+form small pipelike channels for the escape of their gathered waters,
+and the flow emerges at a definite point. Almost all these sources of
+considerable flow are due to the action of the water on the underlying
+rock, where we shall now follow that portion of the crevice water
+which penetrates deeply into the earth.</p>
+
+<p>Almost all rocks, however firm they may appear to be, are divided by
+crevices which extend from the soil level it may be to the depths of
+thousands of feet. These rents are in part due to the strains of
+mountain-building, which tend to disrupt the firmest stone, leaving
+open fractures. They are also formed in other ways, as by the
+imperfectly understood agencies which produce joint planes. It often
+happens that where rocks are highly tilted water finds its way
+downward between the layers, which are imperfectly soldered together,
+or a bed of coarse material, such as sandstone or conglomerate, may
+afford an easy way by which the water may descend for miles beneath
+the surface. Passing through rocks which are not readily soluble, the
+water, already to a great extent supplied with mineral matter by its
+journey through the soil, may not do much excavating work, and even
+after a long time may <span class='pagenum'><a name="Page_253" id="Page_253">[Pg 253]</a></span>only slightly enlarge the spaces in which it
+may be stored or the channels by which it discharges to the surface.
+Hence it comes about that in many countries, even where the waters
+penetrate deeply, they do not afford large springs. It is otherwise
+where the crevice waters enter limestones composed of materials which
+are readily dissolved. In such places we find the rain so readily
+entering the underlying rock that no part of the fall goes at once to
+the brooks, but all has a long underground journey.</p>
+
+<p>In any limestone district where the beds of the material are thick and
+tolerably pure&mdash;as, for instance, in the cavern district of southern
+Kentucky&mdash;the traveller who enters the region notes at once that the
+usual small streams which in every region of considerable rainfall he
+is accustomed to see intersecting the surface of the country are
+entirely absent. In their place he notes everywhere pitlike
+depressions of bowl-shaped form, the sink holes to which we have
+already adverted. Through the openings in the bottom of these the rain
+waters descend into the depths of the earth. Although the most of
+these depressions have but small openings in their bottom, now and
+then one occurs with a vertical shaft sufficiently large to permit the
+explorer to descend into it, though he needs to be lowered down in the
+manner of a miner who is entering a shaft. In fact, the journey is
+nearly always one of some hazard; it should not be undertaken save
+with many precautions to insure safety.</p>
+
+<p>When one is lowered away through an open sink hole, though the descent
+may at first be somewhat tortuous, the explorer soon finds himself
+swinging freely in the air, it may be at a point some hundred feet
+above the base of the bottle-shaped shaft or dome into which he has
+entered. Commonly the neck of the bottle is formed where the water has
+worked its way through a rather sandy limestone, a rock which was not
+readily dissolved by the water. In the pure and therefore easily cut
+limestone layers the cavity rapidly expands until the light of the
+lantern may <span class='pagenum'><a name="Page_254" id="Page_254">[Pg 254]</a></span>not disclose its walls. Farther down there is apt to be a
+shelf composed of another impure limestone, which extends off near the
+middle of the shaft. If the explorer can land upon this shelf, he is
+sure to find that from this imperfect floor the cavern extends off in
+one or more horizontal galleries, which he may follow for a great
+distance until he comes to the point where there is again a well-like
+opening through the hard layer, with another dome-shaped base beneath.
+Returning to the main shaft, the explorer may continue his descent
+until he attains the base of this vertical section of the cave, where
+he is likely to find himself delivered in a pool of water of no great
+depth, the bottom of which is occupied by a quantity of small, hard
+stones of a flinty nature, which have evidently come from the upper
+parts of the cavern. The close observer will have noted that here and
+there in the limestone there are flinty bits, such as those which he
+finds in the pool. From the bottom of the dome a determined inquirer
+can often make his way along the galleries which lead from that level,
+though it may be after a journey of miles to the point where he
+emerges from the cavern on the banks of an open-air river.</p>
+
+<p>Although a journey by way of the sink holes through a cavern system is
+to be commended for the reason that it is the course of the caverning
+waters, it is, on the whole, best to approach the cave through their
+exits along the banks of a stream or through the chance openings which
+are here and there made by the falling in of their roofs. One
+advantage of this cavity of entrance is that we can thus approach the
+cavern in times of heavy rain when the processes which lead to their
+construction are in full activity. Coming in this way to one of the
+domes formed beneath a sink hole, we may observe in rainy weather that
+the water falling down the deep shaft strikes the bottom with great
+force; in many of the Kentucky caves it falls from a greater height
+than Niagara. At such times the stones in the basin at the bottom of
+the shaft are vigorously <span class='pagenum'><a name="Page_255" id="Page_255">[Pg 255]</a></span>whirled about, and in their motion they cut
+the rocks in the bottom of the basin&mdash;in fact, this cavity is a great
+pot hole, like those at the base of open-air cascades. It is now easy
+to interpret the general principles which determine the architecture
+of the cavern realm.</p>
+
+<p>When it first enters the earth all the work which the water does in
+the initial steps of cavern formation is effected by solution. As the
+crevice enlarges and deepens, the stream acquires velocity, and begins
+to use the bits of hard rock in boring. It works downward in this way
+by the mixed mechanical and chemical action until it encounters a hard
+layer. Then the water creeps horizontally through the soft stratum,
+doing most of its work by solution, until it finds a crevice in the
+floor through which it can excavate farther in the downward direction;
+so it goes on in the manner of steps until it burrows channels to the
+open stream. In time the vertical fall under the sink hole will cut
+through the hard layer, when the water, abandoning the first line of
+exit, will develop another at a lower level, and so in time it comes
+about that there may be several stories of the cave, the lowest being
+the last to be excavated. Of the total work thus done, only a small
+part is accomplished by the falling of the water, acting through the
+boring action of its tools, the bits of stone before mentioned; the
+principal part of the task is done by the solvent action of the
+carbonated waters on the limestone. In the system of caverns known as
+the Mammoth Cave, in Kentucky, the writer has estimated that at least
+nine tenths of the stone was removed in the state of solution.</p>
+
+<p>When first excavated, the chambers of a limestone cavern have little
+beauty to attract the eye. The curves of the walls are sometimes
+graceful, but the aspect of the chambers, though in a measure grand,
+is never charming. When, however, the waters have ceased to carve the
+openings, when they have been drained away by the formation of
+channels on a lower level, there commonly sets in a pro<span class='pagenum'><a name="Page_256" id="Page_256">[Pg 256]</a></span>cess known as
+stalactitization, which transforms the scene into one of singular
+beauty. We have already noted the fact that everywhere in ordinary
+rocks there are crevices through which water, moving under the
+pressure of the fluid which is above, may find its way slowly
+downward. In the limestone roofs of caverns, particularly in those of
+the upper story, this ooze of water passes through myriads of unseen
+fissures at a rate so slow that it often evaporates in the dry air
+without dropping to the floor. When it comes out of the rocks the
+water is charged with various salts of lime; when it evaporates it
+leaves the material behind on the roof. Where the outflow is so slight
+that the fluid does not gather into drops, it forms an incrustation of
+limy matter, which often gathers in beautiful flowerlike forms, or
+perhaps in the shape of a sheet of alabaster. Where drops are formed,
+a small, pendent cone grows downward from the ceiling, over which the
+water flows, and on which it evaporates. This cone grows slowly
+downward until it may attain the floor of the chamber, which has a
+height of thirty feet or more. If all the water does not evaporate,
+that which trickles off the apex of the cone, striking on the floor,
+is splashed out into a thin sheet, so that it evaporates in a speedy
+manner, lays down its limestone, and thus builds another and ruder
+cone, which grows upward toward that which is pendent above it.
+Finally, they grow together, enlarged by the process which constructed
+them, until a mighty column may be formed, sculptured as if by the
+hands of a fantastic architect.</p>
+
+<p><span class='pagenum'><a name="Page_257" id="Page_257">[Pg 257]</a></span></p>
+<div class="figcenter" style="width: 487px;">
+<img src="images/f13.jpg" width="487" height="480" alt="Fig. 13.&mdash;Stalactites and stalagmites on roof and floor
+of a cavern. The arrows show the direction of the moving water." title="" />
+<span class="figcaption">Fig. 13.&mdash;Stalactites and stalagmites on roof and floor
+of a cavern. The arrows show the direction of the moving water.</span>
+</div>
+
+<p>All the while that subterranean streams are cutting the caverns
+downward the open-air rivers into which they discharge are deepening
+their beds, and thereby preparing for the construction of yet lower
+stories of caves. These open-air streams commonly flow in steep-sided,
+narrow valleys, which themselves were caves until the galleries became
+so wide that they could no longer support the roof. Thus we often find
+that for a certain distance the roof over a large stream has fallen
+in, so that the water flows in the open air. Then it will plunge
+under an arch and course, it may be, for some miles, before it again
+arrives at a place where the roof has disappeared, or perhaps attains
+a field occupied by rocks of another character, in which caverns were
+not formed. At places these old river caverns are abandoned by the
+streams, which find other courses. They form natural tunnels, which
+are not infrequently of considerable length. One such in southwestern
+Virginia has been made useful for a railway passing from one valley to
+another, thus sparing the expense of a costly excavation. Where the
+remnant of the arch is small, it is commonly known as a natural
+bridge, of which that in Rockbridge County, in Virginia, is a very
+noble <span class='pagenum'><a name="Page_258" id="Page_258">[Pg 258]</a></span>example. Arches of this sort are not uncommon in many cavern
+countries; five such exist in Carter County, Kentucky, a district in
+the eastern part of that State which abounds in caverns, though none
+of them are of conspicuous height or beauty.<a name="FNanchor_7_7" id="FNanchor_7_7"></a><a href="#Footnote_7_7" class="fnanchor">[7]</a></p>
+
+<p>At this stage of his studies on cavern work the student will readily
+conceive that, as the surface of the country overlying the cave is
+incessantly wearing down, the upper stories of the system are
+continually disappearing, while new ones are forming at the present
+drainage level of the country. In fact, the attentive eye can in such
+a district find here and there evidences of this progressive
+destruction. Not only do the caves wear out from above, but their
+roofs are constantly falling to their floors, a process which is
+greatly aided by the growth of stalactites. Forming in the crevices or
+joints between the stones, these rock growths sometimes prize off
+great blocks. In other cases the weight of the pendent stalactite
+drags the ill-supported masses of the roof to the floor. In this way a
+gallery originally a hundred feet below the surface may work its way
+upward to the light of day. The entrance by which the Mammoth Cave is
+approached appears to have been formed in this manner, and at several
+points in that system of caverns the effect of this action may be
+distinctly observed.</p>
+
+<p>We must now go a step further on the way of subterranean water, and
+trace its action in the depths below the plane of ordinary caves,
+which, as we have noted, do not extend below the level of the main
+streams of the cavern district. The first group of facts to be
+attended to is that exhibited by artesian wells. These occur where
+rocks have been folded down into a basinlike form. It often happens
+that in such a basin the rocks of which it <span class='pagenum'><a name="Page_259" id="Page_259">[Pg 259]</a></span>is composed are some of
+them porous, and others impervious to water, and that the porous
+layers outcrop on the high margins of the depression and have
+water-tight layers over them. These conditions can be well represented
+by supposing that we have two saucers, one within the other, with an
+intervening layer of sand which is full of water. If now we bore an
+opening in the bottom of the uppermost saucer, we readily conceive
+that the water will flow up through it. In Nature we often find these
+basins with the equivalent of the sandy layer in the model just
+described rising hundreds of feet above the valley, so that the
+artesian well, so named from the village of Artois, near Paris, where
+the first opening of this nature was made, may yield a stream which
+will mount upward, especially where piped, to a great height. At many
+places in the world it is possible by such wells to obtain a large
+supply of tolerably pure water, but in general it is found to contain
+too large a supply of dissolved mineral matter or sulphuretted gases
+to be satisfactory for domestic purposes. It may be well to note the
+fact that the greater part of the so-called artesian wells, or borings
+which deliver water to a height above the surface, are not true
+artesian sources, in that they do not send up the water by the action
+of gravitation, but under the influence of gaseous pressure.</p>
+
+<p>Where, as in the case of upturned porous beds, the crevice water
+penetrates far below the earth's surface or the open-air streams which
+drain the water away, the fluid acquires a considerable increase of
+temperature, on the average about one degree Fahrenheit for each
+eighty feet of descent. It may, indeed, become so heated that if it
+were at the earth's surface it would not only burst into steam with a
+vast explosive energy, but would actually shine in the manner of
+heated solids. As the temperature of water rises, and as the pressure
+on it increases, it acquires a solvent power, and takes in rocky
+matter in a measure unapproached at the earth's surface. At the depth
+of ten miles water beginning as inert rain would <span class='pagenum'><a name="Page_260" id="Page_260">[Pg 260]</a></span>acquire the
+properties which we are accustomed to associate with strong acids.
+Passing downward through fissures or porous strata in the manner
+indicated in the diagram, the water would take up, by virtue of its
+heat and the gases it contained, a share of many mineral substances
+which we commonly regard as insoluble. Gold and even platinum&mdash;the
+latter a material which resists all acids at ordinary
+temperatures&mdash;enters into the solution. If now the water thus charged
+with mineral stores finds in the depths a shorter way to the surface
+than that which it descended, which may well happen by way of a deep
+rift in the rocks, it will in its ascent reverse the process which it
+followed on going down. It will deposit the several minerals in the
+order of their solubilities&mdash;that is, the last to be taken in will be
+the first to be crystallized on the walls of the fissure through which
+the upflow is taking place. The result will be the formation of a vein
+belonging to the variety known as fissure veins.</p>
+
+<div class="figleft" style="width: 320px;">
+<img src="images/f14.jpg" width="320" height="275" alt="Fig. 14.&mdash;Diagram of vein. The different shadings show
+the variations in the nature of the deposits." title="" />
+<span class="figcaption">Fig. 14.&mdash;Diagram of vein. The different shadings show
+the variations in the nature of the deposits.</span>
+</div>
+
+<p>A vein deposit such as we are considering may, though rarely, be
+composed of a single mineral. Most commonly we find the deposit
+arranged in a banded form in the manner indicated in the figure (see
+diagram 14). Sometimes one material will abound in the lower portions
+of the fissure and another in its higher parts, a feature which is
+accounted for by the progressive cooling and relinquishment of
+pressure to which the water is subjected on its way to the surface.
+With each decrement of those properties some particular substance goes
+out of the fluid, which may in the end emerge in the form of a warm or
+hot spring, the <span class='pagenum'><a name="Page_261" id="Page_261">[Pg 261]</a></span>water of which contains but little mineral matter.
+Where, however, the temperature is high, some part of the deposit,
+even a little gold, may be laid down just about the spring in the
+deposits known as sinter, which are often formed at such places.</p>
+
+<p>In many cases the ore deposits are formed not only in the main channel
+of the fissure, but in all the crevices on either side of that way. In
+this manner, much as in the case of the growth of stalactitic matter
+between the blocks of stone in the roofs of a cavern, large fragments
+of rock, known as "horses," are often pushed out into the body of the
+vein. In some instances the growth of the vein appears to enlarge the
+fissure or place of the deposit as the accumulation goes on, the
+process being analogous to that by which a growing root widens the
+crevice into which it has penetrated. In other instances the fissure
+formed by the force has remained wide open, or at most has been but
+partly filled by the action of the water.</p>
+
+<p>It not infrequently happens that the ascending waters of hot springs
+entering limestones have excavated extensive caves far below the
+surface of the earth, these caverns being afterward in part filled by
+the ores of various metals. We can readily imagine that the water at
+one temperature would excavate the cavern, and long afterward, when at
+a lower heat, they might proceed to fill it in. At a yet later stage,
+when the surface of the country had worn down many thousands of feet
+below the original level, the mineral stores of the caverns may be
+brought near the surface of the earth. Some of the most important
+metalliferous deposits of the Cordilleras are found in this group of
+hot-water caverns. These caverns are essentially like those produced
+by cold water, with the exception of the temperature of the fluid
+which does the work and the opposite direction of the flow.</p>
+
+<p>In following crevice water which is free to obey the impulses of
+gravitation far down into the earth, we enter on a realm where the
+rock or construction water, that <span class='pagenum'><a name="Page_262" id="Page_262">[Pg 262]</a></span>which was built into the stone at
+the time of its formation, is plentiful. Where these two groups of
+waters come in contact an admixture occurs, a certain portion of the
+rock water joining that in the crevices. Near the surface of the
+ground we commonly find that all the construction water has been
+washed out by this action. Yet if the rocks be compact, or if they
+have layers of a soft and clayey nature, we may find the construction
+water, even in very old deposits, remaining near the surface of the
+ground. Thus in the ancient Silurian beds of the Ohio Valley a boring
+carried a hundred feet below the level of the main rivers commonly
+discovers water which is clearly that laid down in the crevices of the
+material at the time when the rocks were formed in the sea. In all
+cases this water contains a certain amount of gases derived from the
+decomposition of various substances, but principally from the
+alteration of iron pyrite, which affords sulphuretted hydrogen. Thus
+the water is forced to the surface with considerable energy, and the
+well is often named artesian, though it flows by gas pressure on the
+principle of the soda-water fountain, and not by gravity, as in the
+case of true artesian wells.</p>
+
+<p>The passage between the work done by the deeply penetrating surface
+water and that due to the fluid intimately blended with the rock built
+into the mass at the time of its formation is obscure. We are,
+however, quite sure that at great depths beneath the earth the
+construction water acts alone not only in making veins, but in
+bringing about many other momentous changes. At a great depth this
+water becomes intensely heated, and therefore tends to move in any
+direction where a chance fissure or other accident may lessen the
+pressure. Creeping through the rocks, and moving from zones of one
+temperature to another, these waters bring about in the fine
+interstices chemical changes which lead to great alterations in the
+constitution of the rock material. It is probably in part to these
+slow driftings of rock water that beds <span class='pagenum'><a name="Page_263" id="Page_263">[Pg 263]</a></span>originally made up of small,
+shapeless fragments, such as compose clay slates, sandstones, and
+limestones, may in time be altered into crystalline rocks, where there
+is no longer a trace of the original bits, all the matter having been
+taken to pieces by the process of dissolving, and reformed in the
+regular crystalline order. In many cases we may note how a crystal
+after being made has been in part dissolved away and replaced by
+another mineral. In fact, many of our rocks appear to have been again
+and again made over by the slow-drifting waters, each particular state
+in their construction being due to some peculiarity of temperature or
+of mineral contents which the fluid held. These metamorphic phenomena,
+though important, are obscure, and their elucidation demands some
+knowledge of petrographic science, that branch of geology which
+considers the principles of rock formation. They will therefore not be
+further considered in this work.</p>
+
+
+<h2 class="subtitle smcap">Volcanoes.</h2>
+
+<p>Of old it was believed that volcanoes represented the outpouring of
+fluid rock which came forth from the central realm of the earth, a
+region which was supposed still to retain the liquid state through
+which the whole mass of our earth has doubtless passed. Recent
+studies, however, have brought about a change in the views of
+geologists which is represented by the fact that we shall treat
+volcanic phenomena in connection with the history of rock water.</p>
+
+<p>In endeavouring to understand the phenomena of volcanoes it is very
+desirable that the student should understand what goes on in a normal
+eruption. The writer may, therefore, be warranted in describing some
+observations which he had an opportunity to make at an eruption of
+Vesuvius in 1883, when it was possible to behold far more than can
+ordinarily be discerned in such outbreaks&mdash;in fact, the opportunity of
+a like nature has probably not <span class='pagenum'><a name="Page_264" id="Page_264">[Pg 264]</a></span>been enjoyed by any other person
+interested in volcanic action. In the winter of 1882-'83 Vesuvius was
+subjected to a succession of slight outbreaks. At the time of the
+observations about to be noted the crater had been reduced to a cup
+about three hundred feet in diameter and about a hundred feet deep.
+The vertical shaft at the bottom, through which the outbursts were
+taking place, was about a hundred feet across. Taking advantage of a
+heavy gale from the northwest, it was practicable, notwithstanding the
+explosions, to climb to the edge of the crater wall. Looking down into
+the throat of the volcano, although the pit was full of whirling
+vapours and the heat was so great that the protection of a mask was
+necessary, it was possible to see something of what was going on at
+the moment of an explosion.</p>
+
+<p>The pipe of the volcano was full of white-hot lava. Even in a day of
+sunshine, which was only partly obscured by the vapours which hung
+about the opening, the heat of the lava made it very brilliant. This
+mass of fluid rock was in continuous motion, swaying violently up and
+down the tube. From four to six times a minute, at the moment of its
+upswaying, it would burst as by the explosion of a gigantic bubble.
+The upper portion of the mass was blown upward in fragments, the
+discharge being like that of shot from a fowling piece; the fragments,
+varying in size from small, shotlike bits to masses larger than a
+man's head, were shot up sometimes to the height of fifteen hundred
+feet above the point of ejection. The wind, blowing at the rate of
+about forty miles an hour, drove the falling bits of rock to the
+leeward, so that there was no considerable danger to be apprehended
+from them. Some seconds after the explosion they could be heard
+rattling down on the farther slope of the cone. Observations on the
+interval between the discharge and the fall of the fragments made it
+easy to compute the height to which they were thrown.</p>
+
+<p>At the moment when the lava in the pipe opened for the passage of the
+vapour which created the explosion the <span class='pagenum'><a name="Page_265" id="Page_265">[Pg 265]</a></span>movement, though performed in
+a fraction of a second, was clearly visible. At first the vapour was
+colourless; a few score feet up it began to assume a faint, bluish
+hue; yet higher, when it was more expanded, the tint changed to that
+of steam, which soon became of the ordinary aspect, and gathered in
+swift-revolving clouds. The watery nature of the vapour was perfectly
+evident by its odour. Though commingled with sulphurous-acid gas, it
+still had the characteristic smell of steam. For a half hour it was
+possible to watch the successive explosions, and even to make rough
+sketches of the scene. Occasionally the explosions would come in quick
+succession, so that the lava was blown out of the tube; again, the
+pool would merely sway up and down in a manner which could be
+explained only by supposing that great bubbles of vapour were working
+their way upward toward the point where they could burst. Each of
+these bubbles probably filled a large part of the diameter of the
+pipe. In general, the phenomena recalled the escape of the jet from a
+geyser, or, to take a familiar instance, that of steam from the pipe
+of a high-pressure engine. When the heat is great, steam may often be
+seen at the mouth of the pipe with the same transparent appearance
+which was observed in the throat of the crater. In the cold air of the
+mountain the vapour was rapidly condensed, giving a rainbow hue in the
+clouds when they were viewed at the right angle. The observations were
+interrupted by the fact that the wind so far died away that large
+balls of the ejected lava began to fall on the windward side of the
+cone. These fragments, though cooled and blackened on their outside by
+their considerable journey up and down through the air, were still so
+soft that they splashed when they struck the surface of cinders.</p>
+
+<p>Watching the cone from a distance, one could note that from time to
+time the explosions, increasing in frequency, finally attained a point
+where the action appeared to be continuous. The transition was
+comparable to that which we may observe in a locomotive which, when it
+first gets <span class='pagenum'><a name="Page_266" id="Page_266">[Pg 266]</a></span>under way, gives forth occasional jets of steam, but,
+slowly gaining speed, finally pours forth what to eye and ear alike
+seem to be a continuous outrush. All the evidence that we have
+concerning volcanic outbreaks corroborates that just cited, and is to
+the effect that the essence of the action consists in the outbreak of
+water vapour at a high temperature, and therefore endowed with very
+great expansive force. Along with this steam there are many other
+gases, which always appear to be but a very small part of the whole
+escape of a vaporous nature&mdash;in fact, the volcanic steam, so far as
+its chemical composition has been ascertained, has the composition
+which we should expect to find in rock water which had been forced out
+from the rock by the tensions that high temperature creates.</p>
+
+<p>Because of its conspicuous nature, the lava which flows from most
+volcanoes, or is blown out from them in the form of finely divided
+ash, is commonly regarded as the primary feature in a volcanic
+outbreak. Such is not really the case. Volcanic explosions may occur
+with very little output of fluid rock, and that which comes forth may
+consist altogether of the finely divided bits of rock to which we give
+the name of ash. In fact, in all very powerful explosions we may
+expect to find no lava flow, but great quantities of this finely
+divided rock, which when it started from the depths of the earth was
+in a fluid state, but was blown to pieces by the contained vapour as
+it approached the surface.</p>
+
+<p>If the student is so fortunate as to behold a flood of lava coming
+forth from the flanks of a volcano, he will observe that even at the
+very points of issue, where the material is white-hot and appears to
+be as fluid as water, the whole surface gives forth steam. On a still
+day, viewed from a distance, the path of a lava flow is marked by a
+dense cloud of this vapour which comes forth from it. Even after the
+lava has cooled so that it is safe to walk upon it, every crevice
+continues to pour forth steam. Years after the flowing has ceased, and
+when the rock surface has <span class='pagenum'><a name="Page_267" id="Page_267">[Pg 267]</a></span>become cool enough for the growth of
+certain plants upon it, these crevices still yield steam. It is
+evident, in a word, that a considerable part of a lava mass, even
+after it escapes from the volcanic pipes, is water which is intimately
+commingled with the rock, probably lying between the very finest
+grains of the heated substance. Yet this lava which has come forth
+from the volcano has only a portion of the water which it originally
+contained; a large, perhaps the greater part, has gone forth in the
+explosive way through the crater. It is reasonably believed that the
+fluidity of lava is in considerable measure due to the water which it
+contains, and which serves to give the mass the consistence of paste,
+the partial fluidity of flour and rock grains being alike brought
+about in the same manner.</p>
+
+<p>So much of the phenomena of volcanoes as has been above noted is
+intended to show the large part which interstitial water plays in
+volcanic action. We shall now turn our attention again to the state of
+the deeply buried rock water, to see how far we may be able by it to
+account for these strange explosive actions. When sediments are laid
+down on the sea floor the materials consist of small, irregularly
+shaped fragments, which lie tumbled together in the manner of a mass
+of bricks which have been shot out of a cart. Water is buried in the
+plentiful interspaces between these bits of stone; as before remarked,
+the amount of this construction water varies. In general, it is at
+first not far from one tenth part of the materials. Besides the fluid
+contained in the distinct spaces, there is a share which is held as
+combined water in the intimate structure of the crystals, if such
+there be in the mass. When this water is built into the stone it has
+the ordinary temperature of the sea bottom. As the depositing actions
+continue to work, other beds are formed on the top of that which we
+are considering, and in time the layer may be buried to the depth of
+many thousand feet. There are reasons to believe that on the floors of
+the oceans this burial of beds containing water may have brought great
+quantities of fluid to the depth <span class='pagenum'><a name="Page_268" id="Page_268">[Pg 268]</a></span>of twenty miles or more below the
+outer surface of the rocks.</p>
+
+<div class="figcenter" style="width: 473px;">
+<img src="images/f15.jpg" width="473" height="480" alt="Fig. 15.&mdash;Flow of lava invading a forest. A tree in the
+distance is not completely burned, showing that the molten rock had
+lost much of its original heat." title="" />
+<span class="figcaption">Fig. 15.&mdash;Flow of lava invading a forest. A tree in the
+distance is not completely burned, showing that the molten rock had
+lost much of its original heat.</span>
+</div>
+
+<p>The effect of deep burial is to increase the heat of strata. This
+result is accomplished in two different ways. The direct effect
+arising from the imposition of weight, that derived from the mass of
+stratified material, is, as we know, to bring about a down-sinking of
+the earth's crust. In the measure of this falling, heat is engendered
+pre<span class='pagenum'><a name="Page_269" id="Page_269">[Pg 269]</a></span>cisely as it is by the falling of a trip-hammer on the anvil, with
+which action, as is well known, we may heat an iron bar to a high
+temperature. It is true that this down-sinking of the surface under
+weight is in part due to the compression of the rocks, and in part to
+the slipping away of the soft underpinning of more or less fluid rock.
+Yet further it is in some measure brought about by the wrinkling of
+the crust. But all these actions result in the conversion of energy of
+position into heat, and so far serve to raise the temperature of the
+rocks which are concerned in the movements. By far the largest source
+of heat, however, is that which comes forth from the earth's interior,
+and which was stored there in the olden day when the matter forming
+the earth gathered into the mass of our sphere. This, which we may
+term the original heat, is constantly flowing forth into space, but
+makes its way slowly, because of the non-conductive, or, as we may
+phrase it, the "blanketing" effect of the outer rock. The effect of
+the strata is the same as that exercised by the non-conductive
+coatings which are put on steam boilers. A more familiar comparison
+may be had from the blankets used for bedclothing. If on top of the
+first blanket we put a second, we keep warmer because the temperature
+of the lower one is elevated by the heat from our body which is held
+in. In the crust of the earth each layer of rock resists the outflow
+of heat, and each addition lifts the temperature of all the layers
+below.</p>
+
+<p>When water-bearing strata have been buried to the depth of ten miles,
+the temperature of the mass may be expected to rise to somewhere
+between seven hundred and a thousand degrees Fahrenheit. If the depth
+attained should be fifty miles, it is likely that the temperature will
+be five times as great. At such a heat the water which the rocks
+contain tends in a very vigorous way to expand and pass into the state
+of vapour. This it can not readily do, because of its close
+imprisonment; we may say, however, that the tendency toward explosion
+is almost as great as <span class='pagenum'><a name="Page_270" id="Page_270">[Pg 270]</a></span>that of ignited gunpowder. Such powder, if held
+in small spaces in a mass of cast steel, could be fired without
+rending the metal. The gases would be retained in a highly compressed,
+possibly in a fluid form. If now it happens that any of the strain in
+the rocks such as lead to the production of faults produce fissures
+leading from the surface into this zone of heated water, the tendency
+of the rocks containing the fluid, impelled by its expansion, will be
+to move with great energy toward the point of relief or lessened
+pressure which the crevice affords. Where rocks are in any way
+softened, pressure alone will force them into a cavity, as is shown by
+the fact that beds of tolerably hard clay stones in deep coal mines
+may be forced into the spaces by the pressure of the rocks which
+overlie them&mdash;in fact, the expense of cutting out these in-creeping
+rocks is in some British mines a serious item in the cost of the
+product.</p>
+
+<p>The expansion of the water contained in the deep-lying heated rocks
+probably is by far the most efficient agent in urging them toward the
+plane of escape which the fissure affords. When the motion begins it
+pervades all parts of the rock at once, so that an actual flow is
+induced. So far as the movement is due to the superincumbent weight,
+the tendency is at once to increase the temperature of the moving
+mass. The result is that it may be urged into the fissure perhaps even
+hotter than when it started from the original bed place. In proportion
+as the rocky matter wins its way toward the surface, the pressure upon
+it diminishes, and the contained vapours are freer to expand. Taking
+on the vaporous form, the bubbles gather to each other, and when they
+appear at the throat of the volcano they may, if the explosions be
+infrequent, assume the character above noted in the little eruption of
+Vesuvius. Where, however, the lava ascends rapidly through the
+channel, it often attains the open air with so much vapour in it, and
+this intimately mingled with the mass, that the explosion rends the
+materials into an impalpably fine powder, which may float in the air
+for months before <span class='pagenum'><a name="Page_271" id="Page_271">[Pg 271]</a></span>it falls to the earth. With a less violent movement
+the vapour bubbles expand in the lava, but do not rend it apart, thus
+forming the porous, spongy rock known as pumice. With a yet slower
+ascent a large part of the steam may go away, so that we may have a
+flow of lava welling forth from the vent, still giving forth steam,
+but with a vapour whose tension is so lowered that the matter is not
+blown apart, though it may boil violently for a time after it escapes
+into the air.</p>
+
+<p>Although the foregoing relatively simple explanation of volcanic
+action can not be said as yet to be generally accepted by geologists,
+the reasons are sufficient which lead us to believe that it accounts
+for the main features which we observe in this class of explosions&mdash;in
+other words, it is a good working hypothesis. We shall now proceed in
+the manner which should be followed in all natural inquiry to see if
+the facts shown in the distribution of volcanoes in space and time
+confirm or deny the view.</p>
+
+<p>The most noteworthy feature in the distribution of volcanoes is that,
+at the present time at least, all active vents are limited to the sea
+floors or to the shore lands within the narrow range of three hundred
+miles from the coast. Wherever we find a coast line destitute of
+volcanoes, as is the case with the eastern coast of North and South
+America, it appears that the shore has recently been carried into the
+land for a considerable distance&mdash;in other words, old coast lines are
+normally volcanic; that is, here and there have vents of this nature.
+Thus the North Atlantic, the coasts of which appear to have gone
+inland for a great distance in geologically recent times, is
+non-volcanic; while the Pacific coast, which for a long time has
+remained in its present position, has a singularly continuous line of
+craters near the shore extending from Alaska to Tierra del Fuego. So
+uninterrupted is this line of volcanoes that if they were all in
+eruption it would very likely be possible to journey down the coast
+without ever being out of sight of the columns of vapour which they
+would send <span class='pagenum'><a name="Page_272" id="Page_272">[Pg 272]</a></span>forth. On the floor of the sea volcanic peaks appear to be
+very widely distributed; only a few of them&mdash;those which attain the
+surface of the water&mdash;are really known, but soundings show long lines
+of elevations which doubtless represent cones distributed along fault
+lines, none of the peaks of sufficient height to break the surface of
+the sea. It is likely, indeed, that for one marine volcano which
+appears as an island there are scores which do not attain the surface.
+Volcanic islands exist and generally abound in the ocean and greater
+seas; every now and then we observe a new one forming as a small
+island, which is apt to be washed away by the sea shortly after the
+eruption ceases, the disappearance being speedy, for the reason that
+the volcanic ashes of which these cones are composed drift away like
+snow before the movement of the waves.</p>
+
+<p>If the waters of the ocean and seas were drained away so that we could
+inspect the portion of the earth's surface which they cover as readily
+as we do the dry lands, the most conspicuous feature would be the
+innumerable volcanic eminences which lie hidden in these watery
+realms. Wherever the observer passed from the centres of the present
+lands he would note within the limits of those fields only mountains,
+much modified by river action; hills which the rivers had left in
+scarfing away the strata; and dales which had been carved out by the
+flowing waters. Near the shore lines of the vanished seas he would
+begin to find mountains, hills, and vales occasionally commingled with
+volcanic peaks, those structures built from the materials ejected from
+the vents. Passing the coast line to the seaward, the hills and dales
+would quickly disappear, and before long the mountains would vanish
+from his way, and he would gradually enter on a region of vast rolling
+plains beset by volcanic peaks, generally accumulated in long ranges,
+somewhat after the manner of mountains, but differing from those
+elevations not only in origin but in aspect, the volcanic set of peaks
+being altogether made up of conical, cup-topped elevations.</p>
+
+<p><span class='pagenum'><a name="Page_273" id="Page_273">[Pg 273]</a></span></p><p>A little consideration will show us that the fact of volcanoes being
+in the limit to the sea floors and to a narrow fringe of shore next
+certain ocean borders is reconcilable with the view as to their
+formation which we have adopted. We have already noted the fact that
+the continents are old, which implies that the parts of the earth
+which they occupy have long been the seats of tolerably continuous
+erosion. Now and then they have swung down partly beneath the sea, and
+during their submersion they received a share of sediments. But, on
+the whole, all parts of the lands except strips next the coast may be
+reckoned as having been subjected to an excess of wearing action far
+exceeding the depositional work. Therefore, as we readily see,
+underneath such land areas there has been no blanketing process going
+on which has served to increase the heat in the deep underlying rocks.
+On the contrary, it would be easy to show, and the reader may see it
+himself, that the progressive cooling of the earth has probably
+brought about a lowering of the temperature in all the section from
+the surface to very great depths, so that not only is the rock water
+unaffected by increase of heat, but may be actually losing
+temperature. In other words, the conditions which we assume bring
+about volcanic action do not exist beneath the old land.</p>
+
+<p>Beneath the seas, except in their very greatest depths, and perhaps
+even there, the process of forming strata is continually going on.
+Next the shores, sometimes for a hundred or two miles away to seaward,
+the principal contribution may be the sediment worn from the lands by
+the waves and the rivers. Farther away it is to a large extent made up
+of the remains of animals and plants, which when dying give their
+skeletons to form the strata. Much of the materials laid down&mdash;perhaps
+in all more than half&mdash;consist of volcanic dust, ashes, and pumice,
+which drifts very long times before it finds its way to the bottom. We
+have as yet no data of a precise kind for determining the average rate
+of accumulation of sediments upon the sea <span class='pagenum'><a name="Page_274" id="Page_274">[Pg 274]</a></span>floor, but from what is
+known of the wearing of the lands, and the amount of volcanic waste
+which finds its way to the seas, it is probably not less than about a
+foot in ten thousand years; it is most likely, indeed, much to exceed
+this amount. From data afforded by the eruptions in Java and in other
+fields where the quantity of volcanic dust contributed to the seas can
+be estimated, the writer is disposed to believe that the average rate
+of sedimentation on the sea floors is twice as great as the estimate
+above given.</p>
+
+<p>Accumulating at the average rate of one foot in ten thousand years, it
+would require a million years to produce a hundred feet of sediments;
+a hundred million to form ten thousand feet, and five hundred million
+to create the thickness of about ten miles of bed. At the rate of two
+feet in ten thousand years, the thickness accumulated would be about
+twenty miles. When we come to consider the duration of the earth's
+geologic history, we shall find reasons for believing that the
+formation of sediment may have continued for as much as five hundred
+million years.</p>
+
+<p>The foregoing inquiries concerning the origin of volcanoes show that
+at the present time they are clearly connected with some process which
+goes on beneath the sea. An extension of the inquiry indicates that
+this relation has existed in earlier geological times; for, although
+the living volcanoes are limited to places within three hundred miles
+of the sea, we find lava flows, ashes, and other volcanic
+accumulations far in the interior of the continents, though the energy
+which brought them forth to the earth's surface has ceased to operate
+in those parts of the land. In these cases of continental volcanoes it
+generally, if not always, appears that the cessation of the activity
+attended the removal of the shore line of the ocean or the
+disappearance of great inland seas. Thus the volcanoes of the
+Yellowstone district may have owed their activity to the immense
+deposits of sediment which were formed in the vast fresh-water lakes
+which during the later Cretaceous <span class='pagenum'><a name="Page_275" id="Page_275">[Pg 275]</a></span>and early Tertiary times stretched
+along the eastern face of the Rocky Mountains, forming a Mediterranean
+Sea in North America comparable to that which borders southern Europe.
+It thus appears that the arrangement of volcanoes with reference to
+sea basins has held for a considerable period in the past. Still
+further, when we look backward through the successive formations of
+the earth's crust we find here and there evidences in old lava flows,
+in volcanic ashes, and sometimes in the ruins of ancient cones which
+have been buried in the strata, that igneous activity such as is now
+displayed in our volcanoes has been, since the earliest days of which
+we have any record, a characteristic feature of the earth. There is no
+reason to suppose that this action has in the past been any greater or
+any less than in modern days. All these facts point to the conclusion
+that volcanic action is due to the escape of rock water which has been
+heated to high temperatures, and which drives along with it as it
+journeys toward a crevice the rock in which it has been confined.</p>
+
+<p>We will now notice some other explanations of volcanic action which
+have obtained a certain credence. First, we may note the view that
+these ejections from craters are forced out from a supposed liquid
+interior of the earth. One of the difficulties of this view is that we
+do not know that the earth's central parts are fluid&mdash;in fact, many
+considerations indicate that such is not the case. Next, we observe
+that we not infrequently find two craters, each containing fluid lava,
+with the fluid standing at differences of height of several thousand
+feet, although the cones are situated very near each other. If these
+lavas came from a common internal reservoir, the principles which
+control the action of fluids would cause the lavas to be at the same
+elevation. Moreover, this view does not provide any explanation of the
+fact that volcanoes are in some way connected with actions which go on
+on the floors of great water basins. There is every reason to believe
+that the fractures in the rocks under the land are as numerous and
+<span class='pagenum'><a name="Page_276" id="Page_276">[Pg 276]</a></span>deep-going as those beneath the sea. If it were a mere question of
+access to a fluid interior, volcanoes should be equally distributed on
+land and sea floors. Last of all, this explanation in no wise accounts
+for the intermixture of water with the fluid rock. We can not well
+believe that water could have formed a part of the deeper earth in the
+old days of original igneous fusion. In that time the water must have
+been all above the earth in the vaporous state.</p>
+
+<p>Another supposition somewhat akin to that mentioned is that the water
+of the seas finds its way down through crevices beneath the floors of
+the ocean, and, there coming in contact with an internal molten mass,
+is converted into steam, which, along with the fluid rock, escapes
+from the volcanic vent. In addition to the objections urged to the
+preceding view, we may say concerning this that the lava, if it came
+forth under these circumstances, would emerge by the short way, that
+by which the water went down, and not by the longer road, by which it
+may be discharged ten thousand feet or more above the level of the
+sea.</p>
+
+<p>The foregoing general account of volcanic action should properly be
+followed by some account of what takes place in characteristic
+eruptions. This history of these matters is so ample that it would
+require the space of a great encyclop&aelig;dia to contain them. We shall
+therefore be able to make only certain selections which may serve to
+illustrate the more important facts.</p>
+
+<p>By far the best-known volcanic cone is that of Vesuvius, which has
+been subjected to tolerably complete record for about twenty-four
+hundred years. About 500 <span class="smcap">b.c.</span> the Greeks, who were ever on the search
+for places where they might advantageously plant colonies, settled on
+the island of Ischia, which forms the western of what is now termed
+the Bay of Naples. This island was well placed for tillage as well as
+for commerce, but the enterprising colonists were again and again
+disturbed by violent outbreaks of one or more volcanoes which lie in
+the <span class='pagenum'><a name="Page_277" id="Page_277">[Pg 277]</a></span>interior of this island; at one time it appears that the people
+were driven away by these explosions.</p>
+
+<p>In these pre-Christian days Vesuvius, then known as Monte Somma, was
+not known to be a volcano, it never having shown any trace of
+eruption. It appeared as a regularly shaped mountain, somewhat over
+two thousand feet high, with a central depression about three miles in
+diameter at the top, and perhaps two miles over at the bottom, which
+was plainlike in form, with some lakes of bitter water in the centre.
+The most we know of this central cavity is connected with the
+insurrection of the slaves led by Spartacus, the army of the revolters
+having camped for a time on the plain encircled by the crater walls.
+The outer slopes of the mountain afforded then a remarkably fertile
+soil; some traces, indeed, of the fertility have withstood the modern
+eruptions which have desolated its flanks. This wonderful Bay of
+Naples became the seat of the fairest Roman culture, as well as of a
+very extended commerce. Toward the close of the first century of our
+era the region was perhaps richer, more beautifully cultivated, and
+the seat of a more elaborate luxury than any part of the shore line of
+Europe at the present day. At the foot of the mountain, on the eastern
+border of the bay, the city of Pompeii, with a population of about
+fifty thousand souls, was a considerable port, with an extensive
+commerce, particularly with Egypt. The charming town was also a place
+of great resort for rich Egyptians who cared to dwell in Europe. On
+the flanks of the mountain there was at least one large town,
+Herculaneum, which appears to have been an association of rich men's
+residences. On the eastern side of the bay, at a point now known as
+Bai&aelig;, the Roman Government had a naval station, which in the year 79
+was under the command of the celebrated Pliny, a most voluminous
+though unscientific writer on matters of natural history. With him in
+that year there was his nephew, commonly known as the younger Pliny,
+then a student of eighteen years, but afterward himself an author.
+These <span class='pagenum'><a name="Page_278" id="Page_278">[Pg 278]</a></span>facts are stated in some detail, for they are all involved in
+the great tragedy which we are now to describe.</p>
+
+<p>For many years there had been no eruption about the Bay of Naples. The
+volcanoes on Ischia had been still for a century or more, and the
+various circular openings on the mainland had been so far quiet that
+they were not recognised as volcanoes. Even the inquisitive Pliny,
+with his great learning, was so little of a geologist that he did not
+know the signs which indicate the seat of volcanic action, though they
+are among the most conspicuous features which can meet the eye. The
+Greeks would doubtless have recognised the meaning of these physical
+signs. In the year 63 the shores of the Bay of Naples were subjected
+to a distinctive earthquake. Others less severe followed in subsequent
+years. In an early morning in the year 79, a servant aroused the elder
+Pliny at Bai&aelig; with the news that there was a wonderful cloud rising
+from Monte Somma. The younger Pliny states that in form it was like a
+pine tree, the common species in Italy having a long trunk with a
+crown of foliage on its summit, shaped like an umbrella. This crown of
+the column grew until it spread over the whole landscape, darkening
+the field of view. Shortly after, a despatch boat brought a message to
+the admiral, who at once set forth for the seat of the disturbance. He
+invited his nephew to accompany him, but the prudent young man relates
+in his letters to Tacitus, from whom we know the little concerning the
+eruption which has come down to us, that he preferred to do some
+reading which he had to attend to. His uncle, however, went straight
+forward, intending to land at some point on the shore at the foot of
+the cone. He found the sea, however, so high that a landing was
+impossible; moreover, the fall of rock fragments menaced the ship. He
+therefore cruised along the shore for some distance, landing at a
+station probably near the present village of Castellamare. At this
+point the fall of ashes and pumice was <span class='pagenum'><a name="Page_279" id="Page_279">[Pg 279]</a></span>very great, but the sturdy old
+Roman had his dinner and slept after it. There is testimony that he
+snored loudly, and was aroused only when his servants began to fear
+that the fall of ashes and stones would block the way out of his
+bedchamber. When he came forth with his attendants, their heads
+protected by planks resting on pillows, he set out toward Pompeii,
+which was probably the place where he sought to land. After going some
+distance, the brave man fell dead, probably from heart disease; it is
+said that he was at the time exceedingly asthmatic. No sooner were his
+servants satisfied that the life had passed from his body than they
+fled. The remains were recovered after the eruption had ceased. The
+younger Pliny further relates that after his uncle left, the cloud
+from the mountain became so dense that in midday the darkness was that
+of midnight, and the earthquake shocks were so violent that wagons
+brought to the courtyard of the dwelling to bear the members of the
+household away were rolled this way and that by the quakings of the
+earth.</p>
+
+<p>Save for the above-mentioned few and unimportant details concerning
+the eruption, we have no other contemporaneous account. We have,
+indeed, no more extended story until Dion Cassius, writing long after
+the event, tells us that Herculaneum and Pompeii were overwhelmed; but
+he mixes his story with fantastic legends concerning the appearance of
+gods and demons, as is his fashion in his so-called history. Of all
+the Roman writers, he is perhaps the most untrustworthy. Fortunately,
+however, we have in the deposits of ashes which were thrown out at the
+time of this great eruption some basis for interpreting the events
+which took place. It is evident that for many hours the Vesuvian
+crater, which had been dormant for at least five hundred years, blew
+out with exceeding fury. It poured forth no lava streams; the energy
+of the uprushing vapours was too great for that. The molten rock in
+their path was blown into fine bits, and all the hard material cast
+forth as free dust. In the course of the erup<span class='pagenum'><a name="Page_280" id="Page_280">[Pg 280]</a></span>tion, which probably did
+not endure more than two days, possibly not more than twenty-four
+hours, ash enough was poured forth to form a thick layer which spread
+far over the neighbouring area of land and sea floor. It covered the
+cities of Herculaneum and Pompeii to a depth of more than twenty feet,
+and over a circle having a diameter of twenty miles the average
+thickness may have been something like this amount. So deep was it
+that, although almost all the people of these towns survived, it did
+not seem to them worth while to undertake to excavate their dwelling
+places. At Pompeii the covering did not overtop the higher of the low
+houses. An amount of labour which may be estimated at not over one
+thirtieth of the value, or at least the cost which had been incurred
+in building the city, would have restored it to a perfectly
+inhabitable state. The fact that it was utterly abandoned probably
+indicates a certain superstitious view in connection with the
+eruption.</p>
+
+<p>The fact that the people had time to flee from Herculaneum and
+Pompeii, bearing with them their more valuable effects, is proved by
+the excavations at these places which have been made in modern times.
+The larger part of Pompeii and a considerable portion of Herculaneum
+have been thus explored; only rarely have human remains been found.
+Here and there, particularly in the cellars, the labourers engaged in
+the work of disinterring the cities note that their picks enter a
+cavity; examining the space, they find they have discovered the
+remains of a human skeleton. It has recently been learned that by
+pouring soft plaster of Paris into these openings a mould may be
+obtained which gives in a surprisingly perfect manner the original
+form of the body. The explanation of this mould is as follows: Along
+with the fall of cinders in an eruption there is always a great
+descent of rain, arising from the condensation of the steam which
+pours forth from the volcano. This water, mingling with the ashes,
+forms a pasty mud, which often flows in vast streams, <span class='pagenum'><a name="Page_281" id="Page_281">[Pg 281]</a></span>and is
+sometimes known as mud lava. This material has the qualities of
+cement&mdash;that is, it shortly "sets" in a manner comparable to plaster
+of Paris or ordinary mortar. During the eruption of 79 this mud
+penetrated all the low places in Pompeii, covering the bodies of the
+people, who were suffocated by the fumes of the volcanic emanations.
+We know that these people were not drowned by the inundation; their
+attitudes show that they were dead before the flowing matter
+penetrated to where they lay.</p>
+
+<p>It happened that Pompeii lay beyond the influence of the subsequent
+great eruptions of Vesuvius, so that it afterward received only slight
+ash showers. Herculaneum, on the other hand, has century by century
+been more and more deeply buried until at the present time it is
+covered by many sheets of lava. This is particularly to be regretted,
+for the reason that, while Pompeii was a seaport town of no great
+wealth or culture, Herculaneum was the residence place of the gentry,
+people who possessed libraries, the records of which can be in many
+cases deciphered, and from which we might hope to obtain some of the
+lost treasures of antiquity. The papyrus rolls on which the books of
+that day were written, though charred by heat and time, are still
+interpretable.</p>
+
+<p>After the great explosion of 79, Vesuvius sank again into repose. It
+was not until 1056 that vigorous eruptions again began. From time to
+time slight explosions occurred, none of which yielded lava flows; it
+was not until the date last mentioned that this accompaniment of the
+eruption began to appear. In 1636, after a repose of nearly a century
+and a half, there came a very great outbreak, which desolated a wide
+extent of country on the northwestern side of the cone. At this stage
+in the history of the crater the volcanic flow began to attain the
+sea. Washing over the edge of the old original crater of Monte Somma,
+and thus lowering its elevation, these streams devastated, during the
+eruption just mentioned and in various other outbreaks, a wide field
+of cultivated <span class='pagenum'><a name="Page_282" id="Page_282">[Pg 282]</a></span>land, overwhelming many villages. The last considerable
+eruption which yielded large quantities of lava was that of 1872,
+which sent its tide for a distance of about six miles.</p>
+
+<p>Since 1636 the eruptions of Vesuvius have steadily increased in
+frequency, and, on the whole, diminished in violence. In the early
+years of its history the great outbreaks were usually separated by
+intervals of a century or more, and were of such energy that the lava
+was mostly blown to dust, forming clouds so vast that on two occasions
+at least they caused a midnight darkness at Constantinople, nearly
+twelve hundred miles away. This is as if a volcano at Chicago should
+completely hide the sun in the city of Boston. In the present state of
+Vesuvius, the cone may be said to be in slight, almost continuous
+eruption. The old central valley which existed before the eruption of
+79, and continued to be distinct for long after that time, has been
+filled up by a smaller cone, bearing a relatively tiny crater of vent,
+the original wall being visible only on the eastern and northern parts
+of its circuit, and here only with much diminished height. On the
+western face the slope from the base of the mountain to the summit of
+the new cone is almost continuous, though the trained eye can trace
+the outline of Monte Somma&mdash;its position in a kind of bench, which is
+traceable on that side of the long slope leading from the summit of
+the new cone to the sea. The fact that the lavas of Vesuvius have
+broken out on the southwestern side, while the old wall of the cone
+has remained unbroken on the eastern versant, has a curious
+explanation. The prevailing wind of Naples is from the southwest,
+being the strong counter trades which belong in that latitude. In the
+old days when the Monte Somma cone was constructed these winds caused
+the larger part of the ashes to fall on the leeward side of the cone,
+thus forming a thicker and higher wall around that part of the crater.</p>
+
+<div class="figright" style="width: 412px;">
+<img src="images/f16.jpg" width="412" height="480" alt="Fig. 16.&mdash;Diagrammatic sections through Mount Vesuvius,
+showing changes in the form of the cone. (From Phillips.)" title="" />
+<span class="figcaption">Fig. 16.&mdash;Diagrammatic sections through Mount Vesuvius,
+showing changes in the form of the cone. (From Phillips.)</span>
+</div>
+
+<p>From the nature of the recent eruptions of Vesuvius it <span class='pagenum'><a name="Page_283" id="Page_283">[Pg 283]</a></span>appears likely
+that the mountain is about to enter on a second period of inaction.
+The pipes leading through the new cone are small, and the mass of this
+elevation constitutes a great plug, closing the old crater mouth. To
+give vent to a large discharge of steam, the whole of this great mass,
+having a depth of nearly two thousand feet, would have to be blown
+away. It seems most likely that when the occasion for such a discharge
+comes, the vapours of the eruption will seek a vent through some other
+of the many volcanic openings which lie to the westward of this great
+cone. The history of these lesser volcanoes points to the conclusion
+that when the path by way of Vesuvius is obstructed they may give
+relief to the steam which is forcing its course to the surface. Two or
+three times since the eruption of Pliny, during periods when Vesuvius
+had <span class='pagenum'><a name="Page_284" id="Page_284">[Pg 284]</a></span>long been quiet, outbreaks have taken place on Ischia or in the
+Phl&aelig;gr&aelig;n Fields, a region dotted with small craters which lies to the
+west of Naples. The last of these occurred in 1552, and led to the
+formation of the beautiful little cone known as Monte Nuovo. This
+eruption took place near the town of Puzzuoli, a place which was then
+the seat of a university, the people of which have left us records of
+the accident.</p>
+
+<p>The outbreak which formed Monte Nuovo was slight but very
+characteristic. It occurred in and beside a circular pool known as the
+Lucrine Lake, itself an ancient crater. At the beginning of the
+disturbance the ground opened in ragged cavities, from which mud and
+ashes and great fragments of hard rock were hurled high in the air,
+some of the stones ascending to a height of several thousand feet.
+With slight intermissions this outbreak continued for some days,
+resulting in the formation of a hill about five hundred feet high,
+with a crater in its top, the bottom of which lay near the level of
+the sea. Although this volcanic elevation, being made altogether of
+loose fragments, is rapidly wearing down, while the crater is filling
+up, it remains a beautiful object in the landscape, and is also
+noteworthy for the fact that it is the only structure of this nature
+which we know from its beginning. In the Phl&aelig;gr&aelig;n Field there are a
+number of other craters of small size, with very low cones about them.
+These appear to have been the product of brief, slight eruptions. That
+known as the Solfatara, though not in eruption during the historic
+period, is interesting for the fact that from the crevices of the
+rocks about it there comes forth a continued efflux of carbonic-acid
+gas. This substance probably arises from the effect of heat contained
+in old lavas which are in contact with limestone in the deep
+under-earth. We know such limestones are covered by the lavas of
+Vesuvius, for the reason that numerous blocks of the rock are thrown
+out during eruptions, and are often found embedded in the lava
+streams. It is an interesting fact <span class='pagenum'><a name="Page_285" id="Page_285">[Pg 285]</a></span>that these craters of the
+Phl&aelig;gr&aelig;n Field, lying between the seats of vigorous eruption on
+Ischia and at Vesuvius, have never been in vigorous eruption. Their
+slight outbreaks seem to indicate that they have no permanent
+connection with the sources whence those stronger vents obtain their
+supply of heated steam.</p>
+
+<p>The facts disclosed by the study of the Vesuvian system of volcanoes
+afford the geologist a basis for many interesting conclusions.</p>
+
+<p>In the first place, he notes that the greater part of the cones, all
+those of small size, are made up of finely divided rock, which may
+have been more or less cemented by the processes of change which go on
+within it. It is thus clear that the lava flows are
+unessential&mdash;indeed, we may say accidental&mdash;contributions to the mass.
+In the case of Vesuvius they certainly do not amount to as much as one
+tenth of the elevation due to the volcanic action. The share of the
+lava in Vesuvius is probably greater than the average, for during the
+last six centuries this vent has been remarkably lavigerous.<a name="FNanchor_8_8" id="FNanchor_8_8"></a><a href="#Footnote_8_8" class="fnanchor">[8]</a>
+Observation on the volcanoes of other districts show that the Vesuvian
+group is in this regard not peculiar. Of nearly two hundred cones
+which the writer has examined, not more than one tenth disclose
+distinct lavas.</p>
+
+<p>An inspection of the old inner wall of Monte Somma in that portion
+where it is best preserved, on the north side of the Atria del
+Cavallo, or Horse Gulch&mdash;so called for the reason that those who
+ascended Vesuvius were accustomed to leave their saddle animals
+there&mdash;we perceive that the body of the old cone is to a considerable
+extent interlaced with dikes or fissures which have been filled with
+molten lava that has cooled in its place. It is evident that during
+the throes of an eruption, when the lava <span class='pagenum'><a name="Page_286" id="Page_286">[Pg 286]</a></span>stands high in the crater,
+these rents are frequently formed, to be filled by the fluid rock. In
+fact, lava discharges, though they may afterward course for long
+distances in the open air, generally break their way underground
+through the cindery cone, and first are disclosed at the distance of a
+mile or more from the inner walls of the crater. Their path is
+probably formed by riftings in the compacted ashes, such as we trace
+on the steep sides of the Atria del Cavallo, as before noted. For the
+further history of these fissures, we shall have to refer to facts
+which are better exhibited in the cone of &AElig;tna.</p>
+
+<p>The amount of rock matter which has been thrown forth from the
+volcanoes about the Bay of Naples is very great. Only a portion of it
+remains in the region around these cones; by far the greater part has
+been washed or blown away. After each considerable eruption a wide
+field is coated with ashes, so that the tilled grounds appear as if
+entirely sterilized; but in a short time the matter in good part
+disappears, a portion of it decays and is leached away, and the most
+of the remainder washes into the sea. Only the showers, which
+accumulate a deep layer, are apt to be retained on the surface of the
+country. A great deal of this powdered rock drifts away in the wind,
+sometimes in great quantities, as in those cases where it darkened the
+sky more than a thousand miles from the cone. Moreover, the water of
+the steam which brought about the discharges and the other gases which
+accompanied the vapour have left no traces of their presence, except
+in the deep channels which the rain of the condensing steam have
+formed on the hillsides. Nevertheless, after all these subtractions
+are made, the quantity of volcanic matter remaining on the surface
+about the Bay of Naples would, if evenly distributed, form a layer
+several hundred feet in thickness&mdash;perhaps, indeed, a thousand feet in
+depth&mdash;over the territory in which the vents occur. All this matter
+has been taken in relatively recent times from the depths of the
+earth. The surprising fact is that no considerable and, <span class='pagenum'><a name="Page_287" id="Page_287">[Pg 287]</a></span>indeed, no
+permanent subsidence of the surface has attended this excavation. We
+can not believe that this withdrawal of material from the under-earth
+has resulted in the formation of open underground spaces. We know full
+well that any such, if it were of considerable size, would quickly be
+crushed in by the weight of the overlying rocks. We have, indeed, to
+suppose that these steam-impelled lavas, which are driven toward the
+vent whence they are to go forth in the state of dust or fluid, come
+underground from distances away, probably from beneath the floors of
+the sea to the westward.</p>
+
+<p>Although the shores of the Bay of Naples have remained in general with
+unchanged elevation for about two thousand years, they have here and
+there been subjected to slight oscillations which are most likely
+connected with the movement of volcanic matter toward the vents where
+it is to find escape. The most interesting evidence of this nature is
+afforded by the studies which have been made on the ruins of the
+Temple of Serapis at Puzzuoli. This edifice was constructed in
+pre-Christian times for the worship of the Egyptian god Serapis, whose
+intervention was sought by sick people. The fact that this divinity of
+the Nile found a residence in this region shows how intimate was the
+relation between Rome and Egypt in this ancient day. The Serapeium was
+built on the edge of the sea, just above its level. When in modern
+days it began to be studied, its floor was about on its original
+level, but the few standing columns of the edifice afford indubitable
+evidence that this part of the shore has been lowered to the amount of
+twenty feet or more and then re-elevated. The subsidence is proved by
+the fact that the upper part of the columns which were not protected
+by the <i>d&eacute;bris</i> accumulated about them have been bored by certain
+shellfish, known as <i>Lithodomi</i>, which have the habit of excavating
+shelters in soft stone, such as these marble columns afford. At
+present the floor on which the ruin stands appears to be gradually
+sinking, though the rate of movement is very slow.</p>
+
+<p><span class='pagenum'><a name="Page_288" id="Page_288">[Pg 288]</a></span></p><p>Another evidence that the ejections may travel for a great distance
+underground on their way to the vent is afforded by the fact that
+Vesuvius and &AElig;tna, though near three hundred miles apart, appear to
+exchange activities&mdash;that is, their periods of outbreak are not
+simultaneous. Although these elements of the chronology of the two
+cones may be accidental, taken with similar facts derived from other
+fields, they appear to indicate that vents, though far separated from
+each other, may, so to speak, be fed from a common subterranean
+source. It is a singular fact in this connection that the volcano of
+Stromboli, though situated between these two cones, is in a state of
+almost incessant activity. This probably indicates that the last-named
+vent derives its vapours from another level in the earth than the
+greater cones. In this regard volcanoes probably behave like springs,
+of which, indeed, they may be regarded as a group. The reader is
+doubtless aware that hot and cold springs often escape very near
+together, the difference in the temperature being due to the depth
+from which their waters come forth.</p>
+
+<p>As the accidents of volcanic explosion are of a nature to be very
+damaging to man, as well as to the lower orders of Nature, it is fit
+that we should note in general the effect of the Neapolitan eruptions
+on the history of civilization in that region. As stated above, the
+first Greek settlements in this vicinity&mdash;those on the island of
+Ischia&mdash;were much disturbed by volcanic outbreaks, yet the island
+became the seat of a permanent and prosperous colony. The great
+eruption of 79 probably cost many hundred lives, and led to the
+abandonment of two considerable cities, which, however, could at small
+cost have been recovered to use. Since that day various eruptions have
+temporarily desolated portions of the territory, but only in very
+small fields have the ravages been irremediable. Where the ground was
+covered with dust, it has in most places been again tillable, and so
+rapid is the decay of the lavas that in a century after their flow has
+ceased vines can in most cases be <span class='pagenum'><a name="Page_289" id="Page_289">[Pg 289]</a></span>planted on their surfaces. The city
+of Naples, which lies amid the vents, though not immediately in
+contact with any of them, has steadfastly grown and prospered from the
+pre-Christian times. It is doubtful if any lives have ever been lost
+in the city in consequence of an eruption, and no great inconvenience
+has been experienced from them. Now and then, after a great ash
+shower, the volcanic dust has to be removed, but the labour is less
+serious than that imposed on many northern cities by a snowstorm.
+Through all these convulsions the tillage of the district has been
+maintained. It has ever been the seat of as rich and profitable a
+husbandry as is afforded by any part of Italy. In fact, the ash
+showers, as they import fine divided rock very rich in substances
+necessary for the growth of plants, have in a measure served to
+maintain the fertility of the soil, and by this action have in some
+degree compensated for the injury which they occasionally inflict.
+Comparing the ravages of the eruptions with those inflicted by war,
+unnecessary disease, or even bad politics, and we see that these
+natural accidents have been most merciful to man. Many a tyrant has
+caused more suffering and death than has been inflicted by these rude
+operations of Nature.</p>
+
+<p>From the point of view of the naturalist, &AElig;tna is vastly more
+interesting than Vesuvius. The bulk of the cone is more than twenty
+times as great as that of the Neapolitan volcano, and the magnitude of
+its explosions, as well as the range of phenomena which they exhibit,
+incomparably greater. It happens, however, that while human history of
+the recorded kind has been intimately bound up with the tiny Vesuvian
+cone, partly because the relatively slight nature of its disturbances
+permitted men to dwell beside it, the larger &AElig;tna has expelled culture
+from the field near its vent, and has done the greater part of its
+work in the vast solitude which it has created.<a name="FNanchor_9_9" id="FNanchor_9_9"></a><a href="#Footnote_9_9" class="fnanchor">[9]</a></p>
+
+<p><span class='pagenum'><a name="Page_290" id="Page_290">[Pg 290]</a></span></p><p>&AElig;tna has been in frequent eruption for a very much longer time than
+Vesuvius. In the odes of Pindar, in the sixth century before Christ,
+we find records of eruptions. It is said also that the philosopher
+Empedocles sought fame and death by casting himself into the fiery
+crater. There has thus in the case of this mountain been no such long
+period of repose as occurred in Vesuvius. Though our records of the
+outbreaks are exceedingly imperfect, they serve to show that the vent
+has maintained its activity much more continuously than is ordinarily
+the case with volcanoes. &AElig;tna is characteristically a lava-yielding
+cone; though the amount of dust put forth is large, the ratio of the
+fluid rock which flows away from the crater is very much greater than
+at Vesuvius. Nearly half the cone, indeed, may be composed of this
+material. Our space does not permit anything like a consecutive story
+of the &AElig;tnean eruptions since the dawn of history, or even a full
+account of its majestic cone; we can only note certain features of a
+particularly instructive nature which have been remarked by the many
+able men who have studied this structure and the effects of its
+outbreak.</p>
+
+<p>The most important feature exhibited by &AElig;tna is the vast size of its
+cone. At its apex its height, though variable from the frequent
+destruction and rebuilding of the crater walls, may be reckoned as
+about eleven thousand feet. The base on which the volcanic material
+lies is probably less than a thousand feet above the sea, so that the
+maximum thickness of the heap of volcanic ejections is probably about
+two miles. The average depth of this coating is probably about five
+thousand feet, and, as the cone has an average diameter of about
+thirty miles, we may conclude that the cone now contains about a
+thousand <span class='pagenum'><a name="Page_291" id="Page_291">[Pg 291]</a></span>cubic miles of volcanic materials. Great as is this mass,
+it is only a small part of the ejected material which has gone forth
+from the vent. All the matter which in its vaporous state went forth
+with the eruption, the other gases and vapours thus discharged, have
+disappeared. So, too, a large part of the ash and much of the lava has
+been swept away by the streams which drain the region, and which in
+times of eruption are greatly swollen by the accompanying torrential
+rains. The writer has estimated that if all the emanations from the
+volcano&mdash;solid, fluid, and gaseous&mdash;could be heaped on the cone, they
+would form a mass of between two and three thousand cubic miles in
+contents. Yet notwithstanding this enormous outputting of earthy
+matter, the earth on which the &AElig;tnean cone has been constructed has
+not only failed to sink down, but has been in process of continuous,
+slow uprising, which has lifted the surface more than a thousand feet
+above the level which it had at the time when volcanic action began in
+this field. Here, even more clearly than in the case of Vesuvius, we
+see that the materials driven forth from the crater are derived not
+from just beneath its foundation, but from a distance, from realms
+which in the case of this insular volcano are beneath the sea floors.
+It is certain that here the migration of rock matter, impelled by the
+expansion of its contained water toward the vent, has so far exceeded
+that which has been discharged through the crater that an uprising of
+the surface such as we have observed has been brought about.</p>
+
+<div class="figcenter" style="width: 640px;">
+<a name="img09"></a>
+<img src="images/p9.jpg" width="640" height="361" alt="Mount &AElig;tna, seen from near Catania. The imperfect
+cones on the sky line to the left are those of small secondary
+eruptions." title="" />
+<span class="caption">Mount &AElig;tna, seen from near Catania. The imperfect
+cones on the sky line to the left are those of small secondary
+eruptions.</span>
+</div>
+
+<p>There are certain peculiarities of Mount &AElig;tna which are due in part to
+its great size and in part to the climatal conditions of the region in
+which it lies. The upper part of the mountain in winter is deeply
+snow-clad; the frozen water often, indeed, forms great drifts in the
+gorges near the summit. Here it has occasionally happened that a layer
+of ashes has deeply buried the mass, so that it has been preserved for
+years, becoming gradually more inclosed by the subsequent eruptions.
+At one point where <span class='pagenum'><a name="Page_292" id="Page_292">[Pg 292]</a></span>this compact snow&mdash;which has, indeed, taken on the
+form of ice&mdash;has been revealed to view, it has been quarried and
+conveyed to the towns upon the seacoast. It is likely that there are
+many such masses of ice inclosed between the ash layers in the upper
+part of the mountain, where, owing to the height, the climate is very
+cold. This curious fact shows how perfect a non-conductor the ash beds
+of a volcano are to protect the frozen water from the heat of the
+rocks about the crater.</p>
+
+<p>The furious rains which beset the mountain in times of great eruptions
+excavate deep channels on its sides. The lava outbreaks which attend
+almost every eruption, and which descend from the base of the cinder
+cone at the height of from five to eight thousand feet above the sea,
+naturally find their way into these channels, where they course in the
+manner of rivers until the lower and less valleyed section of the cone
+is reached.</p>
+
+<p>Such a lava flow naturally begins to freeze on the surface, the lava
+at first becoming viscid, much in the manner of cream on the surface
+of milk. Urged along by the more fluid lava underneath, this viscid
+coating takes a ropy or corrugated form. As the freezing goes deeper,
+a firm stone roof may be formed across the gorge, which, when the
+current of lava ceases to flow from the crater, permits the lower part
+of the stream to drain away, leaving a long cavern or scries of caves
+extending far up the cone. The nature of this action is exactly
+comparable to that which we may observe when on a frosty morning after
+rain we may find the empty channels which were occupied by rills of
+water roofed over with ice; the ice roofs are temporary, while those
+of lava may endure for ages. Some of these lava-stream caves have been
+disclosed, in the manner of ordinary caverns, by the falling of their
+roofs; but the greater part are naturally hidden beneath the
+ever-increasing materials of the cone.</p>
+
+<p>The lava-stream caves of &AElig;tna are not only interesting <span class='pagenum'><a name="Page_293" id="Page_293">[Pg 293]</a></span>because of
+their peculiarities of form, which we shall not undertake to describe,
+but also for the reason that they help us to account for a very
+peculiar feature in the history of the great cone. On the slopes of
+the volcano, below the upper cindery portion, there are several
+hundred lesser cones, varying from a few score to seven hundred feet
+in height. Each of these has its appropriate crater, and has evidently
+been the seat of one or more eruptions. As the greater part of these
+cones are ancient, many of them being almost effaced by the rain or
+buried beneath the ejections which have surrounded their bases since
+the time they were formed, we are led to believe that many thousands
+of them have been formed during the history of the volcano. The
+history of these subsidiary cones appears to be connected with the
+lava caves noted above. These caverns, owing to the irregularities of
+their form, contain water. They are, in fact, natural cisterns, where
+the abundant rainfall of the mountain finds here and there storage.
+When, during the throes of an eruption, dikes such as we know often to
+penetrate the mountain, are riven outward from the crater through the
+mass of the cone, and filled with lava, the heated rock must often
+come in contact with these masses of buried water. The result of this
+would inevitably be the local generation of steam at a high
+temperature, which would force its way out in a brief but vigorous
+eruption, such as has been observed to take place when these
+peripheral volcanoes are formed. Sometimes it has happened that after
+the explosion the lava has found its way in a stream from the fissure
+thus opened. That this explanation is sufficient is in a measure shown
+by observations on certain effects of lava flows from Vesuvius. The
+writer was informed by a very judicious observer, a resident of
+Naples, who had interested himself in the phenomena of that volcano,
+that the lava streams when they penetrated a cistern, such as they
+often encounter in passing over villages or farmsteads, vaporized the
+water, and gave rise, through <span class='pagenum'><a name="Page_294" id="Page_294">[Pg 294]</a></span>the action of the steam, to small
+temporary cones, which, though generally washed away by the further
+flow of the liquid rock, are essentially like those which we find on
+&AElig;tna. Such subsidiary, or, as they are sometimes called, parasitic
+cones, are known about other volcanoes, but nowhere are they so
+characteristic as on the flanks of that wonderful volcano.</p>
+
+<p>A very conspicuous feature in the &AElig;tnean cone consists of a great
+valley known as the Val del Bove, or Bull Hollow, which extends from
+the base of the modern and ever-changeable cinder cone down the flanks
+of the older structure to near its base. This valley has steep sides,
+in places a thousand or more feet high, and has evidently been formed
+by the down-settling of portions of the cone which were left without
+support by the withdrawal from beneath them of materials cast forth in
+a time of explosion. In an eruption this remarkable valley was the
+seat of a vast water flood, the fluid being cast forth from the crater
+at the beginning of the explosion. In the mouths of this and other
+volcanoes, after a long period of repose, great quantities of water,
+gathering from rains or condensed from the steam which slowly escapes
+from these openings, often pours like a flood down the sides of the
+mountains. In the great eruption of Galongoon, in Java, such a mass of
+water, cast forth by a terrific explosion, mingled with ashes, so that
+the mass formed a thick mud, was shot forth with such energy that it
+ravaged an area nearly eighty miles in diameter, destroying the
+forests and their wild inhabitants, as well as the people who dwelt
+within the range of the amazing disaster. So powerfully was this water
+driven from the crater that the districts immediately at the base of
+the cone were in a manner overshot by the vast stream, and escaped
+with relatively little injury.</p>
+
+<p>When it comes forth from the base of the cinder cone, or from one of
+the small peripheral craters, the lava stream usually appears to be
+white hot, and to flow with <span class='pagenum'><a name="Page_295" id="Page_295">[Pg 295]</a></span>almost the ease of water. It does not
+really have that measure of fluidity; its condition is rather that of
+thin paste; but the great weight of the material&mdash;near two and a half
+times that of water&mdash;causes the movement down the slope to be speedy.
+The central portion of the lava stream long retains its high
+temperature; but the surface, cooling, is first converted into a tough
+sheet, which, though it may bend, can hardly be said to flow. Further
+hardening converts these outlying portions of the current into hard,
+glassy stone, which is broken into fragments in a way resembling the
+ice on the surface of a river. It thus comes about that the advancing
+front of the lava stream becomes covered, and its motion hindered by
+the frozen rock, until the rate of ongoing may not exceed a few feet
+an hour, and the appearance is that of a heap of stone slowly rolling
+down a slope. Now and then a crevice is formed, through which a thin
+stream of liquid lava pours forth, but the material, having already
+parted with much of its heat, rapidly cools, and in turn becomes
+covered with the coating of frozen fragments. In this state of the
+stream the lava flow stands on all sides high above the slope which it
+is traversing; it is, in fact, walled in by its own solidified parts,
+though it is urged forward by the contribution which continues to flow
+in the under arches. In this state of the movement trifling accidents,
+or even human interference, may direct the current this way or that.</p>
+
+<p>Some of the most interesting chapters in the history of &AElig;tna relate to
+the efforts of the people to turn these slow-moving streams so that
+their torrents might flow into wilderness places rather than over the
+fields and towns. In the great flow of 1669, which menaced the city of
+Catania, a large place on the seashore to the southeast of the cone, a
+public-spirited citizen, Se&ntilde;or Papallardo, protecting himself and his
+servants with clothing made of hides, and with large shields, set
+forth armed with great hooks with the purpose of diverting the course
+of the lava <span class='pagenum'><a name="Page_296" id="Page_296">[Pg 296]</a></span>mass. He succeeded in pulling away the stones on the
+flank of the stream, so that a flow of the molten rock was turned in
+another direction. The expedient would probably have been successful
+if he had been allowed to continue his labours; but the inhabitants of
+a neighbouring village, which was threatened by the off-shooting
+current which Papallardo had created, took up arms and drove him and
+his retainers away. The flow continued until it reached Catania. The
+people made haste to build the city walls on the side of danger higher
+than it was before, but the tide mounted over its summit.</p>
+
+<p>Although the lavas which come forth from the volcano evidently have a
+high temperature, their capacity for melting other rocks is relatively
+small. They scour these rocks, because of their weight, even more
+energetically than do powerful torrents of water, but they are
+relatively ineffective in melting stone. On &AElig;tna and elsewhere we may
+often observe lavas which have flowed through forests. When the tide
+of molten rock has passed by, the trees may be found charred but not
+entirely burned away; even stems a few inches in diameter retain
+strength enough to uphold considerable fringes and clots of the lava
+which has clung to them. These facts bear out the conclusion that the
+fluidity of the heated stone depends in considerable measure on the
+water which is contained, either in its fluid or vaporous state,
+between the particles of the material.</p>
+
+<p>If we consider the Italian volcanoes as a whole, we find that they lie
+in a long, discontinuous line extending from the northern part of the
+valley of the Po, within sight of the Alps, to &AElig;tna, and in
+subterranean cones perhaps to the northern coast of Africa. At the
+northern end of the line we have a beautiful group of extinct
+volcanoes, known as the Eugean Mountains. Thence southward to southern
+Tuscany craters are wanting, but there is evidence of fissures in the
+earth which give forth thermal waters. From southern Tuscany southward
+through<span class='pagenum'><a name="Page_297" id="Page_297">[Pg 297]</a></span> Rome to Naples there are many extinct craters, none of which
+have been active in the historic period. From Naples southward the
+cones of this system, about a dozen in number, are on islands or close
+to the margin of the sea. It is a noteworthy fact that the greater
+part of these shore or insular vents have been active since the dawn
+of history; several of them frequently and furiously so, while none of
+those occupying an inland position have been the seat of explosions.
+This is a striking instance going to show the relation of these
+processes to conditions which are brought about on the sea bottom.</p>
+
+<p>&AElig;tna is, as we have noticed, a much more powerful volcano than
+Vesuvius. Its outbreaks are more vigorous, its emanations vastly
+greater in volume, and the mass of its constructions many times as
+great as those accumulated in any other European cone. There are,
+however, a number of volcanoes in the world which in certain features
+surpass &AElig;tna as much as that crater does Vesuvius. Of these we shall
+consider but two&mdash;Skaptar Jokul, of Iceland, remarkable for the volume
+of its lava flow, and Krakatoa, an island volcano between Java and
+Sumatra, which was the seat of the greatest explosion of which we have
+any record.</p>
+
+<p>The whole of Iceland may be regarded as a volcanic mass composed
+mainly of lavas and ashes which have been thrown up by a group of
+volcanoes lying near the northern end of the long igneous axis which
+extends through the centre of the Atlantic. The island has been the
+seat of numerous eruptions; in fact, since its settlement by the
+Northmen in 1070 its sturdy inhabitants have been almost as much
+distressed by the calamities which have come from the internal heat as
+they have been by the enduring external cold. They have, indeed, been
+between frost and fire. The greatest recorded eruption of Iceland
+occurred in 1783, when the volcano of Skaptar, near the southern
+border of the island, poured forth, first, a vast discharge of dust
+and ashes, and afterward in the <span class='pagenum'><a name="Page_298" id="Page_298">[Pg 298]</a></span>languid state of eruption inundated a
+series of valleys with the greatest lava flow of which we have any
+written record. The dust poured forth into the upper air, being finely
+divided and in enormous quantity, floated in the air for months,
+giving a dusky hue to the skies of Europe, which led the common people
+and many of the learned to fear that the wrath of God was upon them,
+and that the day of judgment was at hand. Even the poet Cowper, a man
+of high culture and education, shared in this unreasonable view.</p>
+
+<p>The lava flow in this eruption filled one of the considerable valleys
+of the island, drying up the river, and inundating the plains on
+either side. Estimates which have been made as to the volume of this
+flow appear to indicate that it may have amounted to more than the
+bulk of the Mont Blanc.</p>
+
+<p>This great eruption, by the direct effect of the calamity, and by the
+famine due to the ravaging of the fields and the frightening of the
+fish from the shores which it induced, destroyed nearly one fifth of
+the Icelandic people. It is, in fact, to be remembered as one of the
+three or four most calamitous eruptions of which we have any account,
+and, from the point of view of lava flow, the greatest in history.</p>
+
+<p>Just a hundred years after the great Skaptar eruption, which darkened
+the skies of Europe, the island of Krakatoa, an isle formed by a small
+volcano in the straits of Java, was the seat of a vapour explosion
+which from its intensity is not only unparalleled, but almost
+unapproached in all accounts of such disturbances. Krakatoa had long
+been recognised as a volcanic isle; it is doubtful, however, if it had
+ever been seen in eruption during the three centuries or more since
+European ships began to sail by it until the month of May of the year
+above mentioned. Then an outbreak of what may be called ordinary
+violence took place, which after a few days so far ceased that
+observers landed and took account of the changes which <span class='pagenum'><a name="Page_299" id="Page_299">[Pg 299]</a></span>the convulsion
+had brought about. For about three months there were no further signs
+of activity, but on the 29th of August a succession of vast explosions
+took place, which blew away a great part of the island, forming in its
+place a submarine crater two or three miles in diameter, creating
+world-wide disturbances of sea and air. The sounds of the outbreak
+were heard at a distance of sixteen hundred miles away. The waves of
+the air attendant on the explosion ran round the earth at least once,
+as was distinctly indicated by the self-recording barometers; it is
+possible, indeed, that, crossing each other in their east and west
+courses, these atmospheric tides twice girdled the sphere. In effect,
+the air over the crater was heaved up to the height of some tens of
+thousands of feet, and thence rolled off in great circular waves, such
+as may be observed in a pan of milk when a sharp blow pushes the
+bottom upward.</p>
+
+<p>The violent stroke delivered to the waters of the sea created a vast
+wave, which in the region where it originated rolled upon the shores
+with a surf wall fifty or more feet high. In a few minutes about
+thirty thousand people were overwhelmed. The wave rolled on beyond its
+destructive limits much in the manner of the tide; its influence was
+felt in a sharp rise and fall of the waters as far as the Pacific
+coast of North America, and was indicated by the tide gauges in the
+Atlantic as far north as the coast of Europe.</p>
+
+<p>Owing to the violence of the eruption, Krakatoa poured forth no lava,
+but the dust and ashes which ascended into the air&mdash;or, in other
+words, the finely divided lava which escaped into the
+atmosphere&mdash;probably amounted in bulk to more than twenty cubic miles.
+The coarser part of this material, including much pumice, fell upon
+the seas in the vicinity, where, owing to its lightness, it was free
+to drift in the marine currents far and wide throughout the oceanic
+realm. The finer particles, thrown high into the air, perhaps to the
+height of nearly a hundred thousand feet&mdash;certainly to the elevation
+of more than half this amount&mdash;drifted <span class='pagenum'><a name="Page_300" id="Page_300">[Pg 300]</a></span>far and wide in the
+atmosphere, so that for years the air of all regions was clouded by
+it, the sunrise and sunset having a peculiar red glow, which the dust
+particles produce by the light which they reflect. In this period, at
+all times when the day was clear, the sun appeared to be surrounded by
+a dusky halo. In time the greater part of this dust was drawn down by
+gravity, some portion of it probably falling on every square foot of
+the earth. Since the disappearance of the characteristic phenomena
+which it produced in the atmosphere, European observers have noted the
+existence of faint clouds lying in the upper part of the air at the
+height of a hundred miles or more above the surface. These clouds,
+which were at first distinctly visible in the earliest stage of dawn
+and in the latest period of the sunset glow, seemed to be in rapid
+motion to the eastward, and to be mounting higher above the earth. It
+has been not unreasonably supposed that these shining clouds represent
+portions of the finest dust from Krakatoa, which has been thrown so
+far above the earth's attraction that it is separating itself from the
+sphere. If this view be correct, it seems likely that we may look to
+great volcanic explosions as a source whence the dustlike particles
+which people the celestial spaces may have come. They may, in a word,
+be due to volcanic explosions occurring on this and other celestial
+spheres.</p>
+
+<p>The question suggested above as to the possibility of volcanic
+ejections throwing matter from the earth beyond the control of its
+gravitative energy is one of great scientific interest. Computations
+(not altogether trustworthy) show that a body leaving the earth's
+surface under the conditions of a cannon ball fired vertically upward
+would have to possess a velocity at the start of at least seven miles
+a second in order to go free into space. It would at first sight seem
+that we should be able to reckon whether volcanoes can propel earth
+matter upward with this speed. In fact, however, sufficient data are
+not obtainable; we only know in a general way that the column of
+vapour <span class='pagenum'><a name="Page_301" id="Page_301">[Pg 301]</a></span>rises to the height of thirty or forty thousand feet, and this
+in eruptions of no great magnitude. In an accident such as that at
+Krakatoa, even if an observer were near enough to see clearly what was
+going on, the chance of his surviving the disturbance would be small.
+Moreover, the ascending vapours, owing to their expansion of the steam
+in the column, begin to fly out sideways on its periphery, so that the
+upper part of the central section in the discharge is not visible from
+the earth.</p>
+
+<p>It is in the central section of the uprushing mass, if anywhere, that
+the dust might attain the height necessary to put it beyond the
+earth's attraction, bringing it fairly into the realm of the solar
+system, or to the position where its own motion and the attraction of
+the other spheres would give it an independent orbital movement about
+the sun, or perhaps about the earth. We can only say that observations
+on the height of volcanic ejections are extremely desirable; they can
+probably only be made from a balloon. An ascension thus made beyond
+the cloud disk which the eruption produces might bring the observer
+where he could discern enough to determine the matter. Although the
+movements of the rocky particles could not be observed, the colour
+which they would give to the heavens might tell the story which we
+wish to know. There is evidence that large masses of stone hurled up
+by volcanic eruption have fallen seven miles from the base of the
+cone. Assuming that the masses went straight upward at the beginning
+of their ascent, and that they were afterward borne outwardly by the
+expansion of the column, computations which have a general but no
+absolute value appear to indicate that the masses attained a height of
+from thirty to fifty miles, and had an initial velocity which, if
+doubled, might have carried them into space.</p>
+
+<p>Last of all, we shall note the conditions which attend the eruptions
+of submarine volcanoes. Such explosions have been observed in but a
+few instances, and only in those cases where there is reason to
+believe that the crater <span class='pagenum'><a name="Page_302" id="Page_302">[Pg 302]</a></span>at the time of its explosion had attained to
+within a few hundred feet of the sea level. In these cases the
+ejections, never as yet observed in the state of lava, but in the
+condition of dust and pumice, have occasionally formed a low island,
+which has shortly been washed away by the waves. Knowing as we do that
+volcanoes abound on the sea floor, the question why we do not oftener
+see their explosions disturbing the surface of the waters is very
+interesting, but not as yet clearly explicable. It is possible,
+however, that a volcanic discharge taking place at the depth of
+several thousand feet below the surface of the water would not be able
+to blow the fluid aside so as to open a pipe to the surface, but would
+expend its energy in a hidden manner near the ocean floor. The vapours
+would have to expand gradually, as they do in passing up through the
+rock pipe of a volcano, and in their slow upward passage might be
+absorbed by the water. The solid materials thrown forth would in this
+case necessarily fall close about the vent, and create a very steep
+cone, such, indeed, as we find indicated by the soundings off certain
+volcanic islands which appear only recently to have overtopped the
+level of the waters.</p>
+
+<p>As will be seen, though inadequately from the diagrams of Vesuvius,
+volcanic cones have a regularity and symmetry of form far exceeding
+that afforded by the outlines of any other of the earth's features.
+Where, as is generally the case, the shape of the cone is determined
+by the distribution of the falling cinders or divided lava which
+constitutes the mass of most cones, the slope is in general that known
+as a catenary curve&mdash;i.e., the line formed by a chain hanging between
+two points at some distance from the vertical. It is interesting to
+note that this graceful outline is a reflection or consequence of the
+curve described by the uprushing vapour. The expansion in the
+ascending column causes it to enlarge at a somewhat steadfast rate,
+while the speed of the ascent is ever diminishing. Precisely the same
+action can be seen in the like rush of steam <span class='pagenum'><a name="Page_303" id="Page_303">[Pg 303]</a></span>and other gases and
+vapours from the cannon's mouth; only in the case of the gun, even of
+the greatest size, we can not trace the movement for more than a few
+hundred feet. In this column of ejection the outward movement from the
+centre carries the bits of lava outwardly from the centre of the
+shaft, so that when they lose their ascending velocity they are drawn
+downward upon the flanks of the cone, the amount falling upon each
+part of that surface being in a general way proportional to the
+thickness of the vaporous mass from which they descend. The result is,
+that the thickest part of the ash heap is formed on the upper part of
+the crater, from which point the deposit fades away in depth in every
+direction. In a certain measure the concentration toward the centre of
+the cone is brought about by the draught of air which moves in toward
+the ascending column.</p>
+
+<p>Although, in general, ejections of volcanic matter take place through
+cones, that being the inevitable form produced by the escaping steam,
+very extensive outpourings of lava, ejections which in mass probably
+far exceed those thrown forth through ordinary craters, are
+occasionally poured out through fissures in the earth's crust. Thus in
+Oregon, Idaho, and Washington, in eastern Europe, in southern India,
+and at some other points, vast flows, which apparently took place from
+fissures, have inundated great realms with lava ejections. The
+conditions which appear to bring about these fissure eruptions of lava
+are not yet well understood. A provisional and very probable account
+of the action can be had in the hypothesis which will now be set
+forth.</p>
+
+<p>Where any region has been for a long time the seat of volcanic action,
+it is probable that a large amount of rock in a more or less fluid
+condition exists beneath its surface. Although the outrushing steam
+ejects much of this molten material, there are reasons to suppose that
+a yet greater part lies dormant in the underground spaces. Thus in the
+case of &AElig;tna we have seen that, though some thousands <span class='pagenum'><a name="Page_304" id="Page_304">[Pg 304]</a></span>of miles of
+rock matter have come forth, the base of the cone has been uplifted,
+probably by the moving to that region of more or less fluid rock. If
+now a region thus underlaid by what we may call incipient lavas is
+subjected to the peculiar compressive actions which lead to
+mountain-building, we should naturally expect that such soft material
+would be poured forth, possibly in vast quantities through fault
+fissures, which are so readily formed in all kinds of rock when
+subject to irregular and powerful strains, such as are necessarily
+brought about when rocks are moved in mountain-making. The great
+eruptions which formed the volcanic table-lands on the west coast of
+North America appear to have owed the extrusion of their materials to
+mountain-building actions. This seems to have been the case also in
+some of those smaller areas where fissure flows occur in Europe. It is
+likely that this action will explain the greater part of these massive
+eruptions.</p>
+
+<p>It need not be supposed that the rock beneath these countries, which
+when forced out became lava, was necessarily in the state of perfect
+fluidity before it was forced through the fissures. Situated at great
+depth in the earth, it was under a pressure so great that its
+particles may have been so brought together that the material was
+essentially solid, though free to move under the great strains which
+affected it, and acquiring temperature along with the fluidity which
+heat induces as it was forced along by the mountain-building pressure.
+As an illustration of how materials may become highly heated when
+forced to move particle on particle, it may be well to cite the case
+in which the iron stringpiece on top of a wooden dam near Holyoke,
+Mass., was affected when the barrier went away in a flood. The iron
+stringer, being very well put together, was, it is said, drawn out by
+the strain until it became sensibly reddened by the motion of its
+particles, and finally fell hissing into the waters below. A like
+heating is observable when metal is drawn out in making wire. Thus a
+mass of <span class='pagenum'><a name="Page_305" id="Page_305">[Pg 305]</a></span>imperfectly fluid rock might in a forced journey of a few
+miles acquire a decided increase of temperature.</p>
+
+<p>Although the most striking volcanic action&mdash;all such phenomena,
+indeed, as commonly receives the name&mdash;is exhibited finally on the
+earth's surface, a great deal of work which belongs in the same group
+of geological actions is altogether confined to the deep-lying rock,
+and leads to the formation of dikes which penetrate the strata, but do
+not rise to the open air. We have already noted the fact that dikes
+abound in the deeper parts of volcanic cones, though the fissures into
+which they find their way are seldom riven up to the surface. In the
+same way beneath the ground in non-volcanic countries we may discover
+at a great depth in the older, much-changed rock a vast number of
+these crevices, varying from a few inches to a hundred feet or more in
+width, which have been filled with lavas, the rock once molten having
+afterward cooled. In most cases these dikes are disclosed to us
+through the down-wearing of the earth that has removed the beds into
+which the dikes did not penetrate, thus disclosing the realm in which
+the disturbances took place.</p>
+
+<p>Where, as is occasionally the case in deep mines, or on some bare
+rocky cliff of great height, we can trace a dike in its upward course
+through a long distance, we find that we can never distinctly discover
+the lower point of its extension. No one has ever seen in a clear way
+the point of origin of such an injection. We can, however, often
+follow it upward to the place where there was no longer a rift into
+which it could enter. In its upward path the molten matter appears
+generally to have followed some previously existing fracture, a joint
+plane or a fault, which generally runs through the rocks on those
+planes. We can observe evidence that the material was in the state of
+igneous fluidity by the fact that it has baked the country rocks on
+either side of the fissure, the amount of baking being in proportion
+to the width of the dike, and thus to the amount of heat which it
+could give forth. A dike six <span class='pagenum'><a name="Page_306" id="Page_306">[Pg 306]</a></span>inches in diameter will sometimes barely
+sear its walls, while one a hundred feet in width will often alter the
+strata for a great distance on either side. In some instances, as in
+the coal beds near Richmond, Va., dikes occasionally cut through beds
+of bituminous coal. In these cases we find that the coal has been
+converted into coke for many feet either side of a considerable
+injection. The fact that the dike material was molten is still further
+shown by the occurrence in it of fragments which it has taken up from
+the walls, and which may have been partly melted, and in most cases
+have clearly been much heated.</p>
+
+<p>Where dikes extend up through stratified beds which are separated from
+each other by distinct layers, along which the rock is not firmly
+bound together, it now and then happens, as noted by Mr. G.K. Gilbert,
+of the United States Geological Survey, that the lava has forced its
+way horizontally between these layers, gradually uplifting the
+overlying mass, which it did not break through, into a dome-shaped
+elevation. These side flows from dikes are termed laccolites, a word
+which signifies the pool-like nature of the stony mass which they form
+between the strata.</p>
+
+<p>In many regions, where the earth has worn down so as to reveal the
+zone of dikes which was formed at a great depth, the surface of the
+country is fairly laced with these intrusions. Thus on Cape Ann, a
+rocky isle on the east coast of Massachusetts, having an area of about
+twenty square miles, the writer, with the assistance of his colleague,
+Prof. R.S. Tarr, found about four hundred distinct dikes exhibited on
+the shore line where the rocks had been swept bare by the waves. If
+the census of these intrusions could have been extended over the whole
+island, it would probably have appeared that the total number exceeded
+five thousand. In other regions square miles can be found where the
+dikes intercepted by the surface occupy an aggregate area greater than
+that of the rocks into which they have been intruded.</p>
+
+<p><span class='pagenum'><a name="Page_307" id="Page_307">[Pg 307]</a></span></p><p>Now and then, but rarely, the student of dikes finds one where the
+bordering walls, in place of having the clean-cut appearance which
+they usually exhibit, has its sides greatly worn away and much melted,
+as if by the long-continued passage of the igneous fluid through the
+crevice. Such dikes are usually very wide, and are probably the paths
+through which lavas found their way to the surface of the earth,
+pouring forth in a volcanic eruption. In some cases we can trace their
+relation to ancient volcanic cones which have worn down in all their
+part which were made up of incoherent materials, so that there remains
+only the central pipe, which has been preserved from decay by the
+coherent character of the lava which filled it.</p>
+
+<p>The hypothesis that dikes are driven upward into strata by the
+pressure of the beds which overlie materials hot and soft enough to be
+put in motion when a fissure enters them, and that their movement
+upward through the crevice is accounted for by this pressure, makes
+certain features of these intrusions comprehensible. Seeing that very
+long, slender dikes are found penetrating the rock, which could not
+have had a high temperature, it becomes difficult to understand how
+the lava could have maintained its fluidity; but on the supposition
+that it was impelled forward by a strong pressure, and that the energy
+thus transmitted through it was converted into heat, we discover a
+means whereby it could have been retained in the liquid condition,
+even when forced for long distances through very narrow channels.
+Moreover, this explanation accounts for the fact which has long
+remained unexplained that dikes, except those formed about volcanic
+craters, rarely, if ever, rise to the surface.</p>
+
+<p>The materials contained in dikes differ exceedingly in their chemical
+and mineral character. These variations are due to the differences in
+Nature of the deposits whence they come, and also in a measure to
+exchanges which take place between their own substance and that of the
+rocks <span class='pagenum'><a name="Page_308" id="Page_308">[Pg 308]</a></span>between which they are deposited. This process often has
+importance of an economic kind, for it not infrequently leads to the
+formation of metalliferous veins or other aggregations of ores, either
+in the dike itself or in the country rock. The way in which this is
+brought about may be easily understood by a familiar example. If flesh
+be placed in water which has the same temperature, no exchange of
+materials will take place; but if the water be heated, a circulation
+will be set up, which in time will bring a large part of the soluble
+matter into the surrounding water. This movement is primarily
+dependent on differences of temperature, and consequently differences
+in the quantity of soluble substances which the water seeks to take
+up. When a dike is injected into cooler rocks, such a slow circulation
+is induced. The water contained in the interstices of the stone
+becomes charged with mineral materials, if such exist in positions
+where it can obtain possession of them, and as cooling goes on, these
+dissolved materials are deposited in the manner of veins. These veins
+are generally laid down on the planes of contact between the two kinds
+of stone, but they may be formed in any other cavities which exist in
+the neighbourhood. The formation of such veins is often aided by the
+considerable shrinkage of the lava in the dike, which, when it cools,
+tends to lose about fifteen per cent of its volume, and is thus likely
+to leave a crevice next the boundary walls. Ores thus formed afford
+some of the commonest and often the richest mineral deposits. At
+Leadville, in Colorado, the great silver-bearing lodes probably were
+produced in this manner, wherein lavas, either those of dikes or those
+which flowed in the open air, have come in contact with limestones.
+The mineral materials originally in the once molten rock or in the
+limy beds was, we believe, laid down on ancient sea floors in the
+remains of organic forms, which for their particular uses took the
+materials from the old sea water. The vein-making action has served to
+assemble these scattered bits of metal into <span class='pagenum'><a name="Page_309" id="Page_309">[Pg 309]</a></span>the aggregation which
+constitutes a workable deposit. In time, as the rocks wear down, the
+materials of the veins are again taken into solution and returned to
+the sea, thence perhaps to tread again the cycle of change.</p>
+
+<p>In certain dikes, and sometimes also, perhaps, in lavas known as
+basalts, which have flowed on the surface, the rock when cooling, from
+the shrinkage which then occurs, has broken in a very regular way,
+forming hexagonal columns which are more or less divided on their
+length by joints. When worn away by the agencies of decay, especially
+where the material forms steep cliffs, a highly artificial effect is
+produced, which is often compared, where cut at right angles to the
+columns, to pavements, or, where the division is parallel to the
+columns, to the pipes of an organ.</p>
+
+<p>What we know of dikes inclines us to the opinion that as a whole they
+represent movements of softened rock where the motion-compelling agent
+is not mainly the expansion of the contained water which gives rise to
+volcanic ejection, but rather in large part due to the weight of
+superincumbent strata setting in motion materials which were somewhat
+softened, and which tended to creep, as do the clays in deep coal
+mines. It is evident, however; it is, moreover, quite natural, that
+dike work is somewhat mingled with that produced by the volcanic
+forces; but while the line between the two actions is not sharp, the
+discrimination is important, and occurs with a distinctness rather
+unusual on the boundary line between two adjacent fields of phenomena.</p>
+
+<hr style='width: 45%;' />
+
+<p>We have now to consider the general effects of the earth's interior
+heat so far as that body of temperature tends to drive materials from
+the depths of the earth to the surface. This group of influences is
+one of the most important which operates on our sphere; as we shall
+shortly see, without such action the earth would in time become an
+unfit theatre for the development of organic <span class='pagenum'><a name="Page_310" id="Page_310">[Pg 310]</a></span>life. To perceive the
+effect of these movements, we must first note that in the great
+rock-constructing realm of the seas organic life is constantly
+extracting from the water substances, such as lime, potash, soda, and
+a host of other substances necessary for the maintenance of
+high-grade organisms, depositing these materials in the growing
+strata. Into these beds, which are buried as fast as they form, goes
+not only these earthy materials, but a great store of the sea water as
+well. The result would be in course of time a complete withdrawal into
+the depths of the earth of those substances which play a necessary
+part in organic development. The earth would become more or less
+completely waterless on its surface, and the rocks exposed to view
+would be composed mainly of silica, the material which to a great
+extent resists solution, and therefore avoids the dissolving which
+overtakes most other kinds of rocks. Here comes in the machinery of
+the hot springs, the dikes, and the volcanoes. These agents, operating
+under the influence of the internal heat of the earth, are constantly
+engaged in bearing the earthy matter, particularly its precious more
+solvent parts, back to the surface. The hot springs and volcanoes work
+swiftly and directly, and return the water, the carbon dioxide, and a
+host of other vaporizable and soluble and fusible substances to the
+realm of solar activity, to the living surface zone of the earth. The
+dikes operate less immediately, but in the end to the same effect.
+They lift their materials miles above the level where they were
+originally laid, probably from a zone which is rarely if ever exposed
+to view, placing them near the surface, where the erosive agents can
+readily find access to them.</p>
+
+<p>Of the three agents which serve to export earth materials from its
+depths, volcanoes are doubtless the most important. They send forth
+the greater part of the water which is expelled from the rocks.
+Various computations which the writer has made indicate that an
+ordinary volcano, such as &AElig;tna, in times of most intense explosion,
+<span class='pagenum'><a name="Page_311" id="Page_311">[Pg 311]</a></span>may send forth in the form of steam one fourth of a cubic mile or
+more of water during each day of its discharge, and in a single great
+eruption may pour forth several times this quantity. In its history
+&AElig;tna has probably returned to the atmosphere some hundred cubic miles
+of water which but for the process would have remained permanently
+locked up in its rock prison.</p>
+
+<p>The ejection of rock material, though probably on the average less in
+quantity than the water which escapes, is also of noteworthy
+importance. The volcanoes of Java and the adjacent isles have, during
+the last hundred and twenty years, delivered to the seas more earth
+material than has been carried into those basins by the great rivers.
+If we could take account of all the volcanic ejections which have
+occurred in this time, we should doubtless find that the sum of the
+materials thus cast forth into the oceans was several times as great
+as that which was delivered from the lands by all the superficial
+agents which wear them away. Moreover, while the material from the
+land, except the small part which is in a state of complete solution,
+all falls close to the shore, the volcanic waste, because of its fine
+division or because of the blebs of air which its masses contain, may
+float for many years before it finds its way to the bottom, it may be
+at the antipodes of the point at which it came from the earth. While
+thus journeying through the sea the rock matter from the volcanoes is
+apt to become dissolved in water; it is, indeed, doubtful if any
+considerable part of that which enters the ocean goes by gravitation
+to its floor. The greater portion probably enters the state of
+solution and makes its way thence through the bodies of plants and
+animals again into the ponderable state.</p>
+
+<p>If an observer could view the earth from the surface of the moon, he
+would probably each day behold one of these storms which the volcanoes
+send forth. In the fortnight of darkness, even with the naked eye, it
+would probably be possible to discern at any time several eruptions,
+<span class='pagenum'><a name="Page_312" id="Page_312">[Pg 312]</a></span>some of which would indicate that the earth's surface was ravaged by
+great catastrophes. The nearer view of these actions shows us that
+although locally and in small measure they are harmful to the life of
+the earth, they are in a large way beneficent.</p>
+
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_313" id="Page_313">[Pg 313]</a></span></p>
+<h1><a name="CHAPTER_VIII" id="CHAPTER_VIII"></a>CHAPTER &nbsp; VIII.<br/>
+<span class="subtitle smcap">the soil.</span></h1>
+
+
+<p>The frequent mention which it has been necessary to make of soil
+phenomena in the preceding chapters shows how intimately this feature
+in the structure of the earth is blended with all the elements of its
+physical history. It is now necessary for us to take up the phenomena
+of soils in a consecutive manner.</p>
+
+<p>The study of any considerable river basin enables us to trace the more
+important steps which lead to the destructure and renovation of the
+earth's detrital coating. In such an interpretation we note that
+everywhere the rocks which were built on the sea bottom, and more or
+less made over in the great laboratory of the earth's interior, are at
+the surface, when exposed to the conditions of the atmosphere, in
+process of being taken to pieces and returned to the sea. This action
+goes on everywhere; every drop of rain helps it. It is aided by frost,
+or even by the changes of expansion and contraction which occur in the
+rocks from variations of heat. The result is that, except where the
+slopes are steep, the surface is quickly covered with a layer of
+fragments, all of which are in the process of decay, and ready to
+afford some food to plants. Even where the rock appears bare, it is
+generally covered with lichens, which, adhering to it, obtain a share
+of nutriment from the decayed material which they help to hold on the
+slope. When they have retained a thin sheet of the <i>d&eacute;bris</i>, mosses
+and small flowering plants help the work of retaining the <span class='pagenum'><a name="Page_314" id="Page_314">[Pg 314]</a></span>detritus.
+Soon the strong-rooted bushes and trees win a foothold, and by sending
+their rootlets, which are at first small but rapidly enlarge, into the
+crevices, they hasten the disruption of the stones.</p>
+
+<p>If the construction of soil goes on upon a steep cliff, the quantity
+retained on the slope may be small, but at the base we find a talus,
+composed of the fragments not held by the vegetation, which gradually
+increases as the cliff wears down, until the original precipice may be
+quite obliterated beneath a soil slope. At first this process is
+rapid; it becomes gradually slower and slower as the talus mounts up
+the cliff and as the cliff loses its steepness, until finally a gentle
+slope takes the place of the steep.</p>
+
+<p>From the highest points in any river valley to the sea level the
+broken-up rock, which we term soil, is in process of continuous
+motion. Everywhere the rain water, flowing over the surface or soaking
+through the porous mass, is conveying portions of the material which
+is taken into solution in a speedy manner to the sea. Everywhere the
+expansion of the soil in freezing, or the movements imposed on it by
+the growth of roots, by the overturning of trees, or by the
+innumerable borings and burrowings which animals make in the mass, is
+through the action of gravitation slowly working down the slope. Every
+little disturbance of the grains or fragments of the soil which lifts
+them up causes them when they fall to descend a little way farther
+toward the sea level. Working toward the streams, the materials of the
+soil are in time delivered to those flowing waters, and by them urged
+speedily, though in most cases interruptedly, toward the ocean.</p>
+
+<p>There is another element in the movement of the soils which, though
+less appreciable, is still of great importance. The agents of decay
+which produce and remove the detritus, the chemical changes of the bed
+rock, and the mechanical action which roots apply to them, along with
+the solutional processes, are constantly lowering the surface of the
+mass. In this way we can often prove that a soil con<span class='pagenum'><a name="Page_315" id="Page_315">[Pg 315]</a></span>tinuously
+existing has worked downward through many thousand feet of strata. In
+this process of downgoing the country on which the layer rests may
+have greatly changed its form, but the deposit, under favourable
+conditions, may continue to retain some trace of the materials which
+it derived from beds which have long since disappeared, their position
+having been far up in the spaces now occupied by the air. Where the
+slopes are steep and streams abound, we rarely find detritus which
+belonged in rock more than a hundred feet above the present surface of
+the soil. Where, however, as on those isolated table-lands or buttes
+which abound in certain portions of the Mississippi Valley, as well as
+in many other countries, we find a patch of soil lying on a nearly
+level surface, which for geologic ages has not felt the effect of
+streams, we may discover, commingled in the <i>d&eacute;bris</i>, the harder
+wreckage derived from the decay of a thousand feet or more of vanished
+strata.</p>
+
+<p>When we consider the effect of organic life on the processes which go
+on in the soil, we first note the large fact that the development of
+all land vegetation depends upon the existence of this detritus&mdash;in a
+word, on the slow movement of the decaying rocky matter from the point
+where it is disrupted to its field of rest in the depths of the sea.
+The plants take their food from the portion of this rocky waste which
+is brought into solution by the waters which penetrate the mass. On
+the plants the animals feed, and so this vast assemblage of organisms
+is maintained. Not only does the land life maintain itself on the
+soil, and give much to the sea, but it serves in various ways to
+protect this detrital coating from too rapid destruction, and to
+improve its quality. To see the nature of this work we should visit a
+region where primeval forests still lie upon the slopes of a hilly
+region. In the body of such a wood we find next the surface a coating
+of decayed vegetable matter, made up of the falling leaves, bark,
+branches, and trunks which are constantly descending to the earth.
+Ordinarily, this layer is a foot or more in thickness; at the <span class='pagenum'><a name="Page_316" id="Page_316">[Pg 316]</a></span>top it
+is almost altogether composed of vegetable matter; at the bottom it
+verges into the true soil. An important effect of this decayed
+vegetation is to restrain the movement of the surface water. Even in
+the heaviest rains, provided the mass be not frozen, the water is
+taken into it and delivered in the manner of springs to the larger
+streams. We can better note the measure of this effect by observing
+the difference in the ground covered by this primeval forest and that
+which we find near by which has been converted into tilled fields.
+With the same degree of rapidity in the flow, the distinct stream
+channels on the tilled ground are likely to be from twenty to a
+hundred times in length what they are on the forest bed. The result is
+that while the brook which drains the forested area maintains a
+tolerably constant flow of clean water, the other from the tilled
+ground courses only in times of heavy rain, and then is heavily
+charged with mud. In the virgin conditions of the soil the downwear is
+very slow; in its artificial state this wearing goes on so rapidly
+that the sloping fields are likely to be worn to below the soil level
+in a few score years.</p>
+
+<p>Not only does the natural coating of vegetation, such as our forests
+impose upon the country, protect the soil from washing away, but the
+roots of the larger plants are continually at work in various ways to
+increase the fertility and depth of the stratum. In the form of
+slender fibrils these underground branches enter the joints and bed
+planes of the rock, and there growing they disrupt the materials,
+giving them a larger surface on which decay may operate. These bits,
+at first of considerable size, are in turn broken up by the same
+action. Where the underlying rocks afford nutritious materials, the
+branches of our tap-rooted trees sometimes find their way ten feet or
+more below the base of the true soil. Not only do they thus break up
+the stones, but the nutrition which they obtain in the depths is
+brought up and deposited in the parts above the ground, as well as in
+the roots which lie in the true soil, so that <span class='pagenum'><a name="Page_317" id="Page_317">[Pg 317]</a></span>when the tree dies it
+becomes available for other plants. Thus in the forest condition of a
+country the amount of rock material contributed to the deposit in
+general so far exceeds that which is taken away to the rivers by the
+underground water as to insure the deepening of the soil bed to the
+point where only the strongest roots&mdash;those belonging to our
+tap-rooted trees&mdash;can penetrate through it to the bed rocks.</p>
+
+<p>Almost all forests are from time to time visited by winds which uproot
+the trees. When they are thus rent from the earth, the underground
+branches often form a disk containing a thick tangle of stones and
+earth, and having a diameter of ten or fifteen feet. The writer has
+frequently observed a hundred cubic feet of soil matter, some of it
+taken from the depth of a yard or more, thus uplifted into the air. In
+the path of a hurricane or tornado we may sometimes find thousands of
+acres which have been subjected to this rude overturning&mdash;a natural
+ploughing. As the roots rot away, the <i>d&eacute;bris</i> which they held falls
+outside of the pit, thus forming a little hillock along the side of
+the cavity. After a time the thrusting action of other roots and the
+slow motion of the soil down the slope restore the surface from its
+hillocky character to its original smoothness; but in many cases the
+naturalist who has learned to discern with his feet may note these
+irregularities long after it has been recovered with the forest.</p>
+
+<p>Great as is the effect of plants on the soil, that influence is almost
+equalled by the action of the animals which have the habit of entering
+the earth, finding there a temporary abiding place. The number of
+these ground forms is surprisingly great. It includes, indeed, a host
+of creatures which are efficient agents in enriching the earth. The
+species of earthworms, some of which occupy forested districts as well
+as the fields, have the habit of passing the soil material through
+their bodies, extracting from the mass such nutriment as it may
+contain. In this manner the particles of mineral matter become
+pulverized, and in <span class='pagenum'><a name="Page_318" id="Page_318">[Pg 318]</a></span>a measure affected by chemical changes in the
+bodies of the creatures, and are thus better fitted to afford plant
+food. Sometimes the amount of the earth which the creatures take in in
+moving through their burrows and void upon the surface is sufficient
+to form annually a layer on the surface of the ground having a depth
+of one twentieth of an inch or more. It thus may well happen that the
+soil to the depth of two or three feet is completely overturned in the
+course of a few hundred years. As the particles which the creatures
+devour are rather small, the tendency is to accumulate the finer
+portions of the soil near the surface of the earth, where by solution
+they may contribute to the needs of the lowly plants. It is probably
+due to the action of these creatures that small relics of ancient men,
+such as stone tools, are commonly found buried at a considerable depth
+beneath the earth, and rarely appear upon the surface except where it
+has been subjected to deep ploughing or to the action of running
+streams.</p>
+
+<p>Along with the earthworms, the ants labour to overturn the soil;
+frequently they are the more effective of the two agents. The common
+species, though they make no permanent hillocks, have been observed by
+the writer to lay upon the surface each year as much as a quarter of
+an inch of sand and other fine materials which they have brought up
+from a considerable depth. In many regions, particularly in those
+occupied by glacial drift, and pebbly alluvium along the rivers, the
+effect of this action, like that of earthworms, is to bring to the
+surface the finer materials, leaving the coarser pebbles in the
+depths. In this way they have changed the superficial character of the
+soil over great areas; we may say, indeed, over a large part of the
+earth, and this in a way which fits it better to serve the needs of
+the wild plants as well as the uses of the farmer.</p>
+
+<p>Many thousand species of insects, particularly the larger beetles,
+have the habit of passing their larval state <span class='pagenum'><a name="Page_319" id="Page_319">[Pg 319]</a></span>in the under earth. Here
+they generally excavate burrows, and thus in a way delve the soil. As
+many of them die before reaching maturity, their store of organic
+matter is contributed to the mass, and serves to nourish the plants.
+If the student will carefully examine a section of the earth either in
+its natural or in its tilled state, he will be surprised to find how
+numerous the grubs are. They may often be found to the number of a
+score or more of each cubic foot of material. Many of the species
+which develop underground come from eggs which have carefully been
+encased in organic matter before their deposition in the earth. Thus
+some of the carrion beetles are in the habit of laying their eggs in
+the bodies of dead birds or field mice, which they then bury to the
+depth of some inches in the earth. In this way nearly all the small
+birds and mammals of our woods disappear from view in a few hours
+after they are dead. Other species make balls from the dung of cattle
+in which they lay their eggs, afterward rolling the little spheres, it
+may be for hundreds of feet, to the chambers in the soil which they
+have previously prepared. In this way a great deal of animal matter is
+introduced into the earth, and contributes to its fertility.</p>
+
+<p>Many of our small mammals have the habit of making their dwelling
+places in the soil. Some of them, such as the moles, normally abide in
+the subterranean realm for all their lives. Others use the excavations
+as places of retreat. In any case, these excavations serve to move the
+particles of the soil about, and the materials which the animals drag
+into the earth, as well as the excrement of the creatures, act to
+enrich it. This habit of taking food underground is not limited to the
+mammals; it is common with the ants, and even the earthworms, as noted
+by Charles Darwin in his wonderful essay on these creatures, are
+accustomed to drag into their burrows bits of grass and the slender
+leaves of pines. It is not known what purpose they attain by these
+actions, but it is sufficiently common somewhat to affect the
+conditions of the soil.</p>
+
+<p><span class='pagenum'><a name="Page_320" id="Page_320">[Pg 320]</a></span></p><p>The result of these complicated works done by animals and plants on
+the soil is that the material to a considerable depth are constantly
+being supplied with organic matter, which, along with the mineral
+material, constitutes that part of the earth which can support
+vegetation. Experiment will readily show that neither crushed rock nor
+pure vegetable mould will of itself serve to maintain any but the
+lowliest vegetation. It requires that the two materials be mixed in
+order that the earth may yield food for ordinary plants, particularly
+for those which are of use to man, as crops. On this account all the
+processes above noted whereby the waste of plant and animal life is
+carried below the surface are of the utmost importance in the creation
+and preservation of the soil. It has been found, indeed, in almost all
+cases, necessary for the farmer to maintain the fertility of his
+fields to plough-in quantities of such organic waste. By so doing he
+imitates the work which is effected in virgin soil by natural action.
+As the process is costly in time and material, it is often neglected
+or imperfectly done, with the result that the fields rapidly diminish
+in fertility.</p>
+
+<p>The way in which the buried organic matter acts upon the soil is not
+yet thoroughly understood. In part it accomplishes the results by the
+materials which on its decay it contributes to the soil in a state in
+which they may readily be dissolved and taken up by the roots into
+their sap; in part, however, it is believed that they better the
+conditions by affording dwelling places for a host of lowly species,
+such as the forms which are known as bacteria. The organisms probably
+aid in the decomposition of the mineral matter, and in the conversion
+of nitrogen, which abounds in the air or the soil, into nitrates of
+potash and soda&mdash;substances which have a very great value as
+fertilizers. Some effect is produced by the decay of the foreign
+matter brought into the soil, which as it passes away leaves channels
+through which the soil water can more readily pass.</p>
+
+<p><span class='pagenum'><a name="Page_321" id="Page_321">[Pg 321]</a></span></p><p>By far the most general and important effect arising from the decay
+of organic matter in the earth is to be found in the carbon dioxide
+which is formed as the oxygen of the air combines with the carbon
+which all organic material contains. As before noted, water thus
+charged has its capacity for taking other substances into solution
+vastly increased, and on this solvent action depends in large part the
+decay of the bed rocks and the solution of materials which are to be
+appropriated by the plants.</p>
+
+<p>Having now sketched the general conditions which lead to the formation
+of soils, we must take account of certain important variations in
+their conditions due to differences in the ways in which they are
+formed and preserved. These matters are not only of interest to the
+geologist, but are of the utmost importance to the life of mankind, as
+well as all the lower creatures which dwell upon the lands. First, we
+should note that soils are divisible into three great groups, which,
+though not sharply parted from each other, are sufficiently peculiar
+for the purposes of classification. Where the earth material has been
+derived from the rocks which nearly or immediately underlie it, we
+have a group of soils which may be entitled those of immediate
+derivation&mdash;that is, derived from rocks near by, or from beds which
+once overlaid the level and have since been decayed away. Next, we
+have alluvial soils, those composed of materials which have been
+transported by streams, commonly from a great distance, and laid down
+on their flood plains. Third, the soils the mineral matters of which
+have been brought into their position by the action of glaciers; these
+in a way resemble those formed by rivers, but the materials are
+generally imperfectly sorted, coarse and fine being mingled together.
+Last of all, we have the soils due to the accumulation of blown dust
+or blown sand, which, unlike the others, occupy but a small part of
+the land surface. It would be possible, indeed, to make yet another
+division, including those areas which when emerging from the sea were
+cov<span class='pagenum'><a name="Page_322" id="Page_322">[Pg 322]</a></span>ered with fine, uncemented detritus ready at once to serve the
+purposes of a soil. Only here and there, and but seldom, do we find
+soils of this nature.</p>
+
+<p>It is characteristic of soils belonging to the group to which we have
+given the title of immediate derivation that they have accumulated
+slowly, that they move very gradually down the slopes on which they
+lie, and that in all cases they represent, with a part of their mass
+at least, levels of rock which have disappeared from the region which
+they occupied. The additions made to their mass are from below, and
+that mass is constantly shrinking, generally at a pretty rapid rate,
+by the mineral matter which is dissolved and goes away with the spring
+water. They also are characteristically thin on steep slopes,
+thickening toward the base of the incline, where the diminished grade
+permits the soil to move slowly, and therefore to accumulate.</p>
+
+<p>In alluvial soils we find accumulations which are characterized by
+growth on their upper surfaces, and by the distant transportation of
+the materials of which they are composed. In these deposits the
+outleaching removes vast amounts of the materials, but so long as the
+floods from time to time visit their surfaces the growth of the
+deposits is continued. This growth rarely takes place from the waste
+of the bed rocks on which the alluvium lies. It is characteristic of
+alluvial soils that they are generally made up of <i>d&eacute;bris</i> derived
+from fields where the materials have undergone the change which we
+have noted in the last paragraph; therefore these latter deposits have
+throughout the character which renders the mineral materials easily
+dissolved. Moreover, the mass as it is constructed is commonly mingled
+with a great deal of organic waste, which serves to promote its
+fertility. On these accounts alluvial grounds, though they vary
+considerably in fertility, commonly afford the most fruitful fields of
+any region. They have, moreover, the signal advantage that they often
+may be refreshed by allowing the flood waters <span class='pagenum'><a name="Page_323" id="Page_323">[Pg 323]</a></span>to visit them, an
+action which but for the interference of man commonly takes place once
+each year. Thus in the valley of the Nile there are fields which have
+been giving rich grain harvests probably for more than four thousand
+years, without any other effective fertilizing than that derived from
+the mud of the great river.</p>
+
+<p>The group of glaciated soils differs in many ways from either of those
+mentioned. In it we find the mineral matter to have been broken up,
+transported, and accumulated without the influence of those conditions
+which ordinarily serve to mix rock <i>d&eacute;bris</i> with organic matter during
+the process by which it is broken into bits. When vegetation came to
+preoccupy the fields made desolate by glacial action, it found in most
+places more than sufficient material to form soils, but the greater
+part of the matter was in the condition of pebbles of very hard rock
+and sand grains, fragments of silex. Fortunately, the broken-up state
+of this material, by exposing a great surface of the rocky matter to
+decay, has enabled the plants to convert a portion of the mass into
+earth fit for the uses of their roots. But as the time which has
+elapsed since the disappearance of the glaciers is much less than that
+occupied in the formation of ordinary soil, this decay has in most
+cases not yet gone very far, so that in a cubic foot of glaciated
+waste the amount of material available for plants is often only a
+fraction of that held in the soils of immediate derivation.</p>
+
+<p>In the greater portion of the fields occupied by glacial waste the
+processes which lead to the introduction of organic matter into the
+earth have not gone far enough to set in effective work the great
+laboratory which has to operate in order to give fertile soil. The
+pebbles hinder the penetration of the roots as well as the movement of
+insects and other animals. There has not been time enough for the
+overturning of trees to bring about a certain admixture of vegetable
+matter with the soil&mdash;in a word, the process of soil-making, though
+the first condi<span class='pagenum'><a name="Page_324" id="Page_324">[Pg 324]</a></span>tion, that of broken-up rock, has been accomplished,
+is as yet very incomplete. It needs, indeed, care in the introduction
+of organic matter for its completion.</p>
+
+<p>It is characteristic of glacial soils that they are indefinitely deep.
+This often is a disadvantageous feature, for the reason that the soil
+water may pass so far down into the earth that the roots are often
+deprived of the moisture which they need, and which in ordinary soils
+is retained near the surface by the hard underlayer. On the other
+hand, where the glacial waste is made up of pebbles formed from rocks
+of varied chemical composition, which contain a considerable share of
+lime, potash, soda, and other substances which are required by plants,
+the very large surface which they expose to decay provides the soil
+with a continuous enrichment. In a cubic foot of pebbly glacial earth
+we often find that the mass offers several hundred times as much
+surface to the action of decay as is afforded by the underlying solid
+bed rock from which a soil of immediate derivation has to win its
+mineral supply. Where the pebbly glacial waste is provided with a
+mixture of vegetable matter, the process of decay commonly goes
+forward with considerable rapidity. If the supply of such matter is
+large, such as may be produced by ploughing in barnyard manure or
+green crops, the nutritive value of the earth may be brought to a very
+high point.</p>
+
+<p>It is a familiar experience in regions where glacial soils exist that
+the earth beneath the swamps when drained is found to be
+extraordinarily well suited for farming purposes. On inspecting the
+pebbles from such places, we observe that they are remarkably decayed.
+Where the masses contain large quantities of feldspar, as is the case
+in the greater part of our granitic and other crystalline rocks, this
+material in its decomposition is converted into kaolin or feldspar
+clay, and gives the stones a peculiar white appearance, which marks
+the decomposition, and indicates the process by which a great variety
+of valuable <span class='pagenum'><a name="Page_325" id="Page_325">[Pg 325]</a></span>soil ingredients are brought into a state where they may
+be available for plants.</p>
+
+<p>In certain parts of the glacial areas, particularly in the region near
+the margin of the ice sheet, where the glacier remained in one
+position for a considerable time, we find extensive deposits of
+silicious sand, formed of the materials which settled from the
+under-ice stream, near where they escaped from the glacial cavern.
+These kames and sand plains, because of the silicious nature of their
+materials and the very porous nature of the soil which they afford,
+are commonly sterile, or at most render a profit to the tiller by dint
+of exceeding care. Thus in Massachusetts, although the first settlers
+seized upon these grounds, and planted their villages upon them
+because the forests there were scanty and the ground free from
+encumbering boulders, were soon driven to betake themselves to those
+areas where the drift was less silicious, and where the pebbles
+afforded a share of clay. Very extensive fields of this sandy nature
+in southeastern New England have never been brought under tillage.
+Thus on the island of Martha's Vineyard there is a connected area
+containing about thirty thousand acres which lies in a very favourable
+position for tillage, but has been found substantially worthless for
+such use. The farmers have found it more advantageous to clear away
+the boulders from the coarser drift in order to win soil which would
+give them fair returns.</p>
+
+<p>Those areas which are occupied by soil materials which have been
+brought into their position by the action of the wind may, as regards
+their character, be divided into two very distinct groups&mdash;the dunes
+and loess deposits. In the former group, where, as we have noted (see
+page <a href="#Page_123">123</a>), the coarse sea sands or those from the shores of lakes are
+driven forward as a marching hillock, the grains of the material are
+almost always silicious. The fragments in the motion are not taken up
+into the air, but are blown along the surface. Such dune accumulations
+afford an <span class='pagenum'><a name="Page_326" id="Page_326">[Pg 326]</a></span>earth which is even more sterile than that of the glacial
+sand plains, where there is generally a certain admixture of pebbles
+from rocks which by their decomposition may afford some elements of
+fertility. Fortunately for the interests of man, these wind-borne
+sands occupy but a small area; in North America, in the aggregate,
+there probably are not more than one thousand square miles of such
+deposits.</p>
+
+<p>Where the rock material drifted by the winds is so fine that it may
+rise into the air in the form of dust, the accumulations made of it
+generally afford a fertile soil, and this for the reason that they are
+composed of various kinds of rock, and not, as in the case of dunes,
+of nearly pure silica. In some very rare cases, where the seashore is
+bordered by coral reefs, as it is in parts of southern Florida, and
+the strand is made up of limestone bits derived from the hard parts
+which the polyps secrete, small dunes are made of limy material.
+Owing, however, in part to the relatively heavy nature of this
+substance, as well as to the rapid manner in which its grains become
+cemented together, such limestone dunes never attain great size nor
+travel any distance from their point of origin.</p>
+
+<p>As before noted, dust accumulations form the soil in extended areas
+which lie to the leeward of great deserts. Thus a considerable part of
+western China and much of the United States to the west of the
+Mississippi is covered by these wind-blown earths. Wherever the
+rainfall is considerable these loess deposits have proved to have a
+high agricultural value.</p>
+
+<p>Where a region has an earth which has recently passed from beneath the
+sea or a great lake, the surface is commonly covered by incoherent
+detritus which has escaped consolidation into hard rock by the fact
+that it has not been buried and thus brought into the laboratory of
+the earth's crust. When such a region becomes dry land, the materials
+are immediately ready to enter into the state of soil. They commonly
+contain a good deal of waste <span class='pagenum'><a name="Page_327" id="Page_327">[Pg 327]</a></span>derived from the organic life which
+dwelt upon the sea bottom and was embedded in the strata as they were
+formed. Where these accumulations are made in a lake, the land
+vegetation at once possesses the field, even a single year being
+sufficient for it to effect its establishment. Where the lands emerge
+from the sea, it requires a few years for the salt water to drain away
+so that the earth can be fit for the uses of plants. In a general way
+these sea-bottom soils resemble those formed in the alluvial plains.
+They are, however, commonly more sandy, and their substances less
+penetrated by that decay which goes on very freely in the atmosphere
+because of the abundant supply of oxygen, and but slowly on the sea
+floor. Moreover, the marine deposits are generally made up in large
+part of silicious sand, a material which is produced in large
+quantities by the disruption of the rocks along the sea coast. The
+largest single field of these ocean-bottom soils of North America is
+found in the lowland region of the southern United States, a wide belt
+of country extending along the coast from the Rio Grande to New York.
+Although the streams have channelled shallow valleys in the beds of
+this region, the larger part of its surface still has the peculiar
+features of form and composition which were impressed upon it when it
+lay below the surface of the sea.</p>
+
+<p>Local variations in the character of the soil covering are exceedingly
+numerous, and these differences of condition profoundly affect the
+estate of man. We shall therefore consider some of the more important
+of these conditions, with special reference to their origin.</p>
+
+<p>The most important and distinctly marked variation in the fertility of
+soils is that which is produced by differences in the rainfall. No
+parts of the earth are entirely lacking in rain, but over considerable
+areas the precipitation does not exceed half a foot a year. In such
+realms the soil is sterile, and the natural coating of vegetation
+limited to those plants which can subsist on dew <span class='pagenum'><a name="Page_328" id="Page_328">[Pg 328]</a></span>or which can take on
+an occasional growth at such times as moisture may come upon them.
+With a slight increase in precipitation, the soil rapidly increases in
+productivity, so that we may say that where as much as about ten
+inches of water enters the earth during the summer half of the year,
+it becomes in a considerable measure fit for agriculture. Observations
+indicate that the conditions of fertility are not satisfied where the
+rainfall is just sufficient to fill the pores of the soil; there must
+be enough water entering the earth to bring about a certain amount of
+outflow in the form of springs. The reason of this need becomes
+apparent when we study the evident features of those soils which,
+though from season to season charged with water, do not yield springs,
+but send the moisture away through the atmosphere. Wherever these
+conditions occur we observe that the soil in dry seasons becomes
+coated with a deposit of mineral matter, which, because of its taste,
+has received the name of alkali. The origin of this coating is as
+follows: The pores of the soil, charged from year to year with
+sufficient water to fill them, become stored with a fluid which
+contains a very large amount of dissolved mineral matter&mdash;too much,
+indeed, to permit the roots of plants, save a few species which have
+become accustomed to the conditions, to do their appointed work. In
+fact, this water is much like that of the sea, which the roots of only
+a few of our higher plants can tolerate. When the dry season comes on,
+the heat of the sun evaporates the water at the surface, leaving
+behind a coating composed of the substances which the water contains.
+The soil below acts in the manner of a lamp-wick to draw up fluid as
+rapidly as the heat burns it away. When the soil water is as far as
+possible exhausted, the alkali coating may represent a considerable
+part of the soluble matter of the soil, and in the next rainy season
+it may return in whole or in part to the under-earth, again to be
+drawn in the manner before described to the upper level. It is
+therefore only when a considerable <span class='pagenum'><a name="Page_329" id="Page_329">[Pg 329]</a></span>share of the ground water goes
+forth to the streams in each year that the alkaline materials are in
+quantity kept down to the point where the roots of our crop-giving
+plants can make due use of the soil. Where, in an arid region, the
+ground can be watered from the enduring streams or from artificial
+reservoirs, the main advantage arising from the process is commonly
+found in the control which it gives the farmer in the amount of the
+soil water. He can add to the rainfall sufficient to take away the
+excess of mineral matter. When such soils are first brought under
+tillage it is necessary to use a large amount of water from the
+canals, in order to wash away the old store of alkali. After that a
+comparatively small contribution will often keep the soil in excellent
+condition for agriculture. It has been found, however, in the
+irrigated lands beside the Nile that where too much saving is
+practised in the irrigation, the alkaline coating will appear where it
+has been unknown before, and with it an unfitness of the earth to bear
+crops.</p>
+
+<p>Although the crust of mineral matters formed in the manner above
+described is characteristic of arid countries, and in general peculiar
+to them, a similar deposit may under peculiar conditions be formed in
+regions of great rainfall. Thus on the eastern coast of New England,
+where the tidal marshes have here and there been diked from the sea
+and brought under tillage, the dissolved mineral matters of the soil,
+which are excessive in quantity, are drawn to the surface, forming a
+coating essentially like that which is so common in arid regions. The
+writer has observed this crust on such diked lands, having a thickness
+of an eighth of an inch. In fact, this alkali coating represents
+merely the extreme operation of a process which is going on in all
+soils, and which contributes much to their fertility. When rain falls
+and passes downward into the earth, it conveys the soluble matter to a
+depth below the surface, often to beyond the point where our ordinary
+crop plants, such as the small grains, can have <span class='pagenum'><a name="Page_330" id="Page_330">[Pg 330]</a></span>access to it, and
+this for the reason that their roots do not penetrate deeply. When dry
+weather comes and evaporation takes place from the surface, the fluid
+is drawn up to the upper soil layer, and there, in process of
+evaporation, deposits the dissolved materials which it contains. Thus
+the mineral matter which is fit for plant food is constantly set in
+motion, and in its movement passes the rootlets of the plants. It is
+probably on this account&mdash;at least in part&mdash;that very wet weather is
+almost as unfavourable to the farmer as exceedingly dry, the normal
+alternation in the conditions being, as is well known, best suited to
+his needs.</p>
+
+<p>So long as the earth is subjected to conditions in which the rainfall
+may bring about a variable amount of water in the superficial detrital
+layer, we find normal fruitful soils, though in their more arid
+conditions they may be fit for but few species of plants. When, by
+increasing aridity, we pass to conditions where there is no tolerably
+permanent store of water in the <i>d&eacute;bris</i>, the material ceases to have
+the qualities of a soil, and becomes mere rock waste. At the other
+extreme of the scale we pass to conditions where the water is
+steadfastly maintained in the interstices of the detritus, and there
+again the characteristic of the soil and its fitness for the uses of
+land vegetation likewise disappear. In a word, true soil conditions
+demand the presence of moisture, but that in insufficient quantities,
+to keep the pores of the earth continually filled; where they are thus
+filled, we have the condition of swamps. Between these extremes the
+level at which the water stands in the soil in average seasons is
+continually varying. In rainy weather it may rise quite to the
+surface; in a dry season it may sink far down. As this water rises and
+falls, it not only moves, as before noted, the soluble mineral
+materials, but it draws the air into and expels it from the earth with
+each movement. This atmospheric circulation of the soil, as has been
+proved by experiment, is of great importance in <span class='pagenum'><a name="Page_331" id="Page_331">[Pg 331]</a></span>maintaining its
+fertility; the successive charges of air supply the needs of the
+microscopic underground creatures which play a large part in enriching
+the soil, and the direct effect of the oxygen in promoting decay is
+likewise considerable. A part of the work which is accomplished by
+overturning the earth in tillage consists in this introduction of the
+air into the pores of the soil, where it serves to advance the actions
+which bring mineral matters into solution.</p>
+
+<div class="figcenter" style="width: 609px;">
+<a name="img10"></a>
+<img src="images/p10.jpg" width="609" height="480" alt="Mountain gorge, Himalayas, India. Note the difference
+in the slope of the eroded rocks and the effect of erosion upon them;
+also the talus slopes at the base of the cliffs which the torrent is
+cutting away. On the left of the foreground there is a little bench
+showing a recent higher line of the water." title="" />
+<span class="caption">Mountain gorge, Himalayas, India. Note the difference
+in the slope of the eroded rocks and the effect of erosion upon them;
+also the talus slopes at the base of the cliffs which the torrent is
+cutting away. On the left of the foreground there is a little bench
+showing a recent higher line of the water.</span>
+</div>
+
+<p>In the original conditions of any country which is the seat of
+considerable rainfall, and where the river system is not so far
+developed as to provide channels for the ready exit of the waters, we
+commonly find very extensive swamps; these conditions of bad drainage
+almost invariably exist where a region has recently been elevated
+above the level of the sea, and still retains the form of an irregular
+rolling plain common to sea floors, and also in regions where the work
+done by glaciers has confused the drainage which the antecedent
+streams may have developed. In an old, well-elaborated river system
+swamps are commonly absent, or, if they occur, are due to local
+accidents of an unimportant nature.</p>
+
+<p>For our purpose swamps may be divided into three groups&mdash;climbing
+bogs, lake bogs, and marine marshes. The first two of these groups
+depend on the movements of the rain water over the land; the third on
+the action of the tides. Beginning our account with the first and most
+exceptional of these groups, we note the following features in their
+interesting history:</p>
+
+<p>Wherever in a humid region, on a gentle slope&mdash;say with an inclination
+not exceeding ten feet to the mile&mdash;the soil is possessed by any
+species of plants whose stems grow closely together, so that from
+their decayed parts a spongelike mass is produced, we have the
+conditions which favour the development of climbing bogs. Beginning
+usually in the shores of a pool, these plants, necessarily of a
+water-loving species, retain so much moisture <span class='pagenum'><a name="Page_332" id="Page_332">[Pg 332]</a></span>in the spongy mass
+which they form that they gradually extend up the slope. Thus
+extending the margin of their field, and at the same time thickening
+the deposit which they form, these plants may build a climbing bog
+over the surface until steeps are attained where the inclination is so
+great that the necessary amount of water can not be held in the spongy
+mass, or where, even if so held, the whole coating will in time slip
+down in the manner of an avalanche.</p>
+
+<p>The greater part of the climbing bogs of the world are limited to the
+moist and cool regions of high latitudes, where species of moss
+belonging to the genus <i>Sphagnum</i> plentifully flourish. These plants
+can only grow where they are continuously supplied with a bath of
+water about their roots. They develop in lake bogs as far south as
+Mexico, but in the climbing form they are hardly traceable south of
+New England, and are nowhere extensively developed within the limits
+of the United States. In more northern parts of this continent, and in
+northwestern Europe, particularly in the moist climate of Ireland,
+climbing bogs occupy great areas, and hold up their lakes of
+interstitially contained water over the slopes of hills, where the
+surface rises at the rate of thirty feet or more to the mile. So long
+as the deposit of decayed vegetable matter which has accumulated in
+this manner is thin, therefore everywhere penetrated by the fibrous
+roots of the moss, it may continue to cling to its sloping bed; but
+when it attains a considerable thickness, and the roots in the lower
+part decay, the pulpy mass, water-laden in some time of heavy rain,
+break away in a vast torrent of thick, black mud, which may inundate
+the lower lands, causing widespread destruction.</p>
+
+<p>In more southern countries, other water-loving plants lead to the
+formation of climbing bogs. Of these, the commonest and most effective
+are the species of reeds, of which our Indian cane is a familiar
+example. Brakes of this vegetation, plentifully mingled with other
+species <span class='pagenum'><a name="Page_333" id="Page_333">[Pg 333]</a></span>of aquatic growth, form those remarkable climbing bogs known
+as the Dismal and other swamps, which numerously occur along the coast
+line of the United States from southern Maryland to eastern Texas.
+Climbing bogs are particularly interesting, not only from the fact
+that they are eminently peculiar effects of plant growth, but because
+they give us a vivid picture of those ancient morasses in which grew
+the plants that formed the beds of vegetable matter now appearing in
+the state of coal. Each such bed of buried swamp material was, with
+rare exceptions, where the accumulation took place in lakes, gathered
+in climbing bogs such as we have described.</p>
+
+<p>Lake bogs occur in all parts of the world, but in their best
+development are limited to relatively high latitudes, and this for the
+reason that the plants which form vegetable matter grow most
+luxuriantly in cool climates and in regions where the level of the
+basin is subject to less variation than occurs in the alternating wet
+and dry seasons which exist in nearly all tropical regions. The
+fittest conditions are found in glaciated regions, where, as before
+noted, small lakes are usually very abundant. On the shores of one of
+these pools, of size not so great that the waves may attain a
+considerable height, or in the sheltered bay of a larger lake, various
+aquatic plants, especially the species of pond lilies, take root upon
+the bottom, and spread their expanded leaves on the surface of the
+water. These flexible-leaved and elastic-stemmed plants can endure
+waves which attain no more than a foot or two of height, and by the
+friction which they afford make the swash on the shore very slight. In
+the quiet water, rushes take root, and still further protect the
+strand, so that the very delicate vegetation of the mosses, such as
+the <i>Sphagnum</i>, can fix itself on the shore.</p>
+
+<p>As soon as the <i>Sphagnum</i> mat has begun its growth, the strength given
+by its interlaced fibres enables it to extend off from the shore and
+float upon the water. In this way it may rapidly enlarge, if not
+broken up by the <span class='pagenum'><a name="Page_334" id="Page_334">[Pg 334]</a></span>waves, so that its front advances into the lake at
+the rate of several inches each year. While growing outwardly it
+thickens, so that the bottom of the mass gradually works down toward
+the floor of the basin. At the same time the lower part of the sheet,
+decaying, contributes a shower of soft peat mud to the floor of the
+lake. In this way, growing at its edge, deepening, and contributing to
+an upgrowth from the bottom, a few centuries may serve entirely to
+fill a deep basin with peaty accumulation. In general, however, the
+surface of the bog closes over the lake before the accumulation has
+completely filled the shoreward portions of the area. In these
+conditions we have what is familiarly known as a quaking bog, which
+can be swayed up and down by a person who quickly stoops and rises
+while standing on the surface. In this state the tough and thick sheet
+of growing plants is sufficient to uphold a considerable weight, but
+so elastic that the underlying water can be thrown into waves. Long
+before the bog has completely filled the lake with the peaty
+accumulations the growth of trees is apt to take place on its surface,
+which often reduces the area to the appearance of a very level wet
+wood.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f17.jpg" width="640" height="138" alt="Fig. 17.&mdash;Diagram showing beginning of peat bog: A,
+lake; B, lilies and rushes; C, lake bog; D, climbing bog." title="" />
+<span class="figcaption">Fig. 17.&mdash;Diagram showing beginning of peat bog: A,
+lake; B, lilies and rushes; C, lake bog; D, climbing bog.</span>
+</div>
+
+<p>Climbing and lake bogs in the United States occupy a total area of
+more than fifty thousand square miles. In all North America the total
+area is probably more than twice as great. Similar deposits are
+exceedingly common in the Eurasian continent and in southern
+Patagonia. It is probable that the total amount of these fields in
+differ<span class='pagenum'><a name="Page_335" id="Page_335">[Pg 335]</a></span>ent parts of the world exceeds half a million square miles.
+These two groups of fresh-water swamps have an interest, for the
+reason that when reduced to cultivation by drainage and by subsequent
+removal of the excess of peaty matter, by burning or by natural decay,
+afford very rich soil. The fairest fields of northern Europe,
+particularly in Great Britain and Ireland, have been thus won to
+tillage. In the first centuries of our era a large part of
+England&mdash;perhaps as much as one tenth of the ground now tilled in that
+country&mdash;was occupied by these lands, which retained water in such
+measure as to make them unfit for tillage, the greater portion of this
+area being in the condition of thin climbing bog. For many centuries
+much of the energy of the people was devoted to the reclamation of
+these valuable lands. This task of winning the swamp lands to
+agriculture has been more completely accomplished in England than
+elsewhere, but it has gone far on the continent of Europe,
+particularly in Germany. In the United States, owing to the fact that
+lands have been cheap, little of this work of swamp-draining has as
+yet been accomplished. It is likely that the next great field of
+improvement to be cultivated by the enterprising people will be found
+in these excessively humid lands, from which the food-giving resources
+for the support of many million people can be won.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f18.jpg" width="640" height="148" alt="Fig. 18.&mdash;Diagram showing development of swamp: A,
+remains of lake; B, surface growth; c, peat." title="" />
+<span class="figcaption">Fig. 18.&mdash;Diagram showing development of swamp: A,
+remains of lake; B, surface growth; c, peat.</span>
+</div>
+
+<p>The group of marine marshes differs in many important regards from
+those which are formed in fresh water.<span class='pagenum'><a name="Page_336" id="Page_336">[Pg 336]</a></span> Where the tide visits any
+coast line, and in sheltered positions along that shore, a number of
+plants, mostly belonging to the group of grasses, species which have
+become accustomed to having their roots bathed by salt water, begin
+the formation of a spongy mat, which resembles that composed of
+<i>Sphagnum</i>, only it is much more solid. This mat of the marine marshes
+soon attains a thickness of a foot or more, the upper or growing
+surface lying in a position where it is covered for two or three hours
+at each visit of the tide. Growing rapidly outward from the shore, and
+having a strength which enables it to resist in a tolerably effective
+manner waves not more than two or three feet high, this accumulation
+makes head against the sea. To a certain extent the waves undermine
+the front of the sheet and break up masses of it, which they
+distribute over the shallow bottom below the level at which these
+plants can grow. In this deeper water, also, other marine animals and
+plants are continually developing, and their remains are added to the
+accumulations which are ever shallowing the water, thus permitting a
+further extension of the level, higher-lying marsh. This process
+continues until the growth has gone as far as the scouring action of
+the tidal currents will permit. In the end the bay, originally of
+wide-open water, is only such at high tide. For the greater part of
+the time it appears as broad savannas, whose brilliant green gives
+them the aspect of rare fertility.</p>
+
+<p>Owing to the conditions of their growth, the deposits formed in marine
+marshes contain no distinct peat, the nearest approach to that
+substance being the tangle of wirelike roots which covers the upper
+foot or so of the accumulation. The greater part of the mass is
+composed of fine silt, brought in by the streams of land water which
+discharge into the basin, and by the remains of animals which dwelt
+upon the bottom or between the stalks of the plants that occupy the
+surface of the marshes. These interspaces afford admirable shelter to
+a host of small <span class='pagenum'><a name="Page_337" id="Page_337">[Pg 337]</a></span>marine forms. The result is, that the tidal marshes,
+as well as the lower-lying mud flats, which have been occupied by the
+mat of vegetation, afford admirable earth for tillage. Unfortunately,
+however, there are two disadvantages connected with the redemption of
+such lands. In the first place, it is necessary to exclude the sea
+from the area, which can only be accomplished by considerable
+engineering work; in the second place, the exclusion of the tide
+inevitably results in the silting up of the passage by which the water
+found its way to the sea. As these openings are often used for
+harbours, the effect arising from their destruction is often rather
+serious. Nevertheless, in some parts of the world very extensive and
+most fertile tracts of land have thus been won from the sea; a large
+part of Holland and shore-land districts in northern Europe are made
+up of fields which were originally covered by the tide. Near the mouth
+of the Rhine, indeed, the people have found these sea-bottom soils so
+profitable that they have gone beyond the zone of the marshes, and
+have drained considerable seas which of old were permanently covered,
+even at the lowest level of the waters.</p>
+
+<p>On the coast of North America marine marshes have an extensive
+development, and vary much in character. In the Bay of Fundy, where
+the tides have an altitude of fifty feet or more, the energy of their
+currents is such that the marsh mat rarely forms. Its place, however,
+is taken by vast and ever-changing mud flats, the materials of which
+are swept to and fro by the moving waters. The people of this region
+have learned an art of a peculiar nature, by which they win broad
+fields of excellent land from the sea. Selecting an area of the flats,
+the surface of which has been brought to within a few feet of high
+tide, they inclose it with a stout barrier or dike, which has openings
+for the free admission of the tidal waters. Entering this basin, the
+tide, moving with considerable velocity, bears in quantities of
+sediment. In the basin, <span class='pagenum'><a name="Page_339" id="Page_339">[Pg 339]</a></span><span class='pagenum'><a name="Page_338" id="Page_338">[Pg 338]</a></span>the motion being arrested, this sediment
+falls to the bottom, and serves to raise its level. In a few months
+the sheet of sediment is brought near the plane of the tidal movement,
+then the gates are closed at times when the tide has attained half of
+its height, so that the ground within the dike is not visited by the
+sea water, and can be cultivated.</p>
+
+<div class="figleft" style="width: 319px;">
+<a href="images/f19-large.jpg">
+<img src="images/f19.jpg" style="border-style: none;" width="319" height="534" alt="Fig. 19.&mdash;Map of Ipswich marshes, Massachusetts, formed
+behind a barrier beach." title="" />
+</a>
+<span class="figcaption">Fig. 19.&mdash;Map of Ipswich marshes, Massachusetts, formed
+behind a barrier beach.<br/>
+(Transcriber's note: click on the image for a full-size version of the map.)</span>
+</div>
+
+<p>Along the coast of New England the ordinary marine marshes attain an
+extensive development in the form of broad-grassed savannas. With this
+aspect, though with a considerable change in the plants which they
+bear, the fringe of savannas continues southward along the coast to
+northern Florida. In the region about the mouth of the Savannah River,
+so named from the vast extent of the tidal marshes, these fields
+attain their greatest development. In central and southern Florida,
+however, where the seacoast is admirably suited for their development,
+these coastal marshes of the grassy type disappear, their place being
+taken by the peculiar morasses formed by the growth of the mangrove
+tree.</p>
+
+<p>In the mangrove marshes the tree which gives the areas their name
+covers all the field which is visited by the tide. This tree grows
+with its crown supported on stiltlike roots, at a level above high
+tide. From its horizontal branches there grow off roots, which reach
+downward into the water, and thence to the bottom. The seeds of the
+mangrove are admirably devised so as to enable the plant to obtain a
+foothold on the mud flats, even where they are covered at low tide
+with a depth of two or three feet of water. They are several inches in
+length, and arranged with booklets at their lower ends; floating near
+the bottom, they thus catch upon it, and in a few weeks' growth push
+the shoot to the level of the water, thus affording a foundation for a
+new plantation. In this manner, extending the old forests out into the
+shallow water of the bays, and forming new colonies wherever the water
+is not too deep, these plants rapidly <span class='pagenum'><a name="Page_340" id="Page_340">[Pg 340]</a></span>occupy all the region which
+elsewhere would appear in the form of savannas.</p>
+
+<p>The tidal marshes of North America, which may be in time converted to
+the uses of man, probably occupy an area exceeding twenty thousand
+square miles. If the work of reclaiming such lands from the sea ever
+attains the advance in this country that it has done in Holland, the
+area added to the dry land by engineering devices may amount to as
+much as fifty thousand square miles&mdash;a territory rather greater than
+the surface of Kentucky, and with a food-yielding power at least five
+times as great as is afforded by that fertile State. In fact, these
+conquests from the sea are hereafter to be among the great works which
+will attract the energies of mankind. In the arid region of the
+Cordilleras, as well as in many other countries, the soil, though
+destitute of those qualities which make it fit for the uses of man,
+because of the absence of water in sufficient amount, is, as regards
+its structure and depth, as well as its mineral contents, admirably
+suited to the needs of agriculture. The development of soils in desert
+regions is in almost all cases to be accounted for by the former
+existence in the realms they occupy of a much greater rainfall than
+now exists. Thus in the Rocky Mountain country, when the <span class='pagenum'><a name="Page_341" id="Page_341">[Pg 341]</a></span>deep soils
+of the ample valleys were formed, the lakes, as we have before noted,
+were no longer dead seas, as is at present so generally the case, but
+poured forth great streams to the sea. Here, as elsewhere, we find
+evidence that certain portions of the earth which recently had an
+abundant rainfall have now become starved for the lack of that supply.
+All the soils of arid regions where the trial has been made have
+proved very fertile when subjected to irrigation, which can often be
+accomplished by storing the waters of the brief rainy season or by
+diverting those of rivers which enter the deserts from well-watered
+mountain fields. In fact, the soil of these arid realms yields
+peculiarly ample returns to the husbandman, because of certain
+conditions due to the exceeding dryness of the air. This leads to an
+absence of cloudy weather, so that from the time the seed is planted
+the growth is stimulated by uninterrupted and intense sunshine. The
+same dryness of the air leads, as we have seen, to a rapid evaporation
+from the surface, by which, in a manner before noted, the dissolved
+mineral matter is brought near the top of the soil, where it can best
+serve the greater part of our crop plants. On these accounts an acre
+of irrigated soil can be made to yield a far greater return than can
+be obtained from land of like chemical composition in humid regions.</p>
+
+<div class="figcenter" style="width: 640px;">
+<img src="images/f20.jpg" width="640" height="271" alt="Fig. 20.&mdash;Diagram showing mode of growth of mangroves." title="" />
+<span class="figcaption">Fig. 20.&mdash;Diagram showing mode of growth of mangroves.</span>
+</div>
+
+<p>In many parts of the world, particularly in the northern and western
+portions of the Mississippi Valley, there are widespread areas, which,
+though moderately well watered, were in their virgin state almost
+without forests. In the prairie region the early settlers found the
+country unwooded, except along the margins of the streams. On the
+borders of the true prairies, however, they found considerable areas
+of a prevailingly forested land, with here and there a tract of
+prairie. There were several of these open fields south of the Ohio,
+though the country there is in general forested; one of these prairie
+areas, in the Green River district of Kentucky, was several thou<span class='pagenum'><a name="Page_342" id="Page_342">[Pg 342]</a></span>sand
+square miles in extent. At first it was supposed that the absence of
+trees in the open country of the Mississippi Valley was due to some
+peculiarity of the soil, but experience shows that plantations
+luxuriantly develop, and that the timber will spread rapidly in the
+natural way. In fact, if the seeds of the trees which have been
+planted since the settlement of the country were allowed to develop as
+they seek to do, it would only be a few centuries before the region
+would be forest-clad as far west as the rainfall would permit the
+plants to develop. Probably the woods would attain to near the
+hundredth meridian.</p>
+
+<p>In the opinion of the writer, the treeless character of the Western
+plains is mainly to be accounted for by the habit which our Indians
+had of burning the herbage of a lowly sort each year, so that the
+large game might obtain better pasturage. It is a well-known fact to
+all those who have had to deal with cattle on fields which are in the
+natural state that fire betters the pasturage. Beginning this method
+of burning in the arid regions to the west of the original forests,
+the natural action of the fire has been gradually to destroy these
+woods. Although the older and larger trees, on account of their thick
+bark and the height of their foliage above the ground, escaped
+destruction, all the smaller and younger members of the species were
+constantly swept away. Thus when the old trees died they left no
+succession, and the country assumed its prairie character. That the
+prairies were formed in this manner seems to be proved by the
+testimony which we have concerning the open area before mentioned as
+having existed in western Kentucky. It is said that around the
+timberless fields there was a wide fringe of old fire-scarred trees,
+with no undergrowth beneath their branches, and that as they died no
+kind of large vegetation took their place. When the Indians who set
+these fires were driven away, as was the case in the last decade of
+the last century, the country at once began to resume its timbered
+condition. From the margin and from every <span class='pagenum'><a name="Page_343" id="Page_343">[Pg 343]</a></span>interior point where the
+trees survived, their seeds spread so that before the open land was
+all subjugated to the plough it was necessary in many places to clear
+away a thick growth of the young forest-building trees.</p>
+
+<p>The soils which develop on the lavas and ashes about an active volcano
+afford interesting subjects for study, for the reason that they show
+how far the development of the layer which supports vegetation may
+depend upon the character of the rocks from which it is derived. Where
+the materials ejected from a volcano lie in a rainy district, the
+process of decay which converts the rock into soil is commonly very
+rapid, a few years of exposure to the weather being sufficient to
+bring about the formation of a fertile soil. This is due to the fact
+that most lavas, as well as the so-called volcanic ashes, which are of
+the same material as the lavas, only blown to pieces, are composed of
+varied minerals, the most of which are readily attacked by the agents
+of decay. Now and then, however, we find the materials ejected from a
+particular volcano, or even the lavas and ashes of a single eruption,
+in such a chemical state that soils form upon them with exceeding
+slowness.</p>
+
+<hr style='width: 45%;' />
+
+<p>The foregoing incomplete considerations make it plain that the
+soil-covering of the earth is the result of very delicate adjustments,
+which determine the rate at which the broken-down rocks find their
+path from their original bed places to the sea. The admirable way in
+which this movement is controlled is indicated by the fact that almost
+everywhere we find a soil-covering deep enough for the use of a varied
+vegetation, but rarely averaging more than a dozen feet in depth. Only
+here and there are the rocks bare or the earth swathed in a profound
+mass of detritus. This indicates how steadfast and measured is the
+march of the rock waste from the hills to the sea. Unhappily, man,
+when by his needs he is forced to till the soil, is compelled to break
+up this ancient and perfect <span class='pagenum'><a name="Page_344" id="Page_344">[Pg 344]</a></span>order. He has to strip the living mantle
+from the earth, replacing it with growth of those species which serve
+his needs. Those plants which are most serviceable&mdash;which are, indeed,
+indispensable in the higher civilization, the grains&mdash;require for
+their cultivation that the earth be stripped bare and deeply stirred
+during the rainy season, and thus subjected to the most destructive
+effect of the rainfall. The result is, that in almost all grain fields
+the rate of soil destruction vastly surpasses that at which the
+accumulation is being made. We may say, indeed, that, except in
+alluvial plains, where the soil grows by flood-made additions to its
+upper surface, no field tilled in grain can without exceeding care
+remain usable for a century. Even though the agriculturist returns to
+the earth all the chemical substances which he takes away in his
+crops, the loss of the soil by the washing away of its substance to
+the stream will inevitably reduce the region to sterility.</p>
+
+<p>It is not fanciful to say that the greatest misfortune which in a
+large way man has had to meet in his agriculture arises from this
+peculiar stress which grain crops put upon the soil. If these grains
+grew upon perennial plants, in the manner of our larger fruits, the
+problem of man's relation to the soil would be much simpler than it is
+at present. He might then manage to till the earth without bringing
+upon it the inevitable destruction which he now inflicts. As it is, he
+should recognise that his needs imperil this ancient and precious
+element in the earth's structure, and he should endeavour in every
+possible way to minimize the damage which he brings about. This result
+he may accomplish in certain simple ways.</p>
+
+<p>First, as regards the fertility of the soil, as distinguished from the
+thickness of the coating, it may be said that modern discoveries
+enable us to see the ways whereby we may for an indefinite period
+avoid the debasement of our great heritage, the food-giving earth. We
+now know in various parts of the world extensive and practically
+inexhaustible deposits, whence may be obtained the phos<span class='pagenum'><a name="Page_345" id="Page_345">[Pg 345]</a></span>phates,
+potash, soda, etc., which we take from the soil in our crops. We also
+have learned ways in which the materials contained in our sewage may
+be kept from the sea and restored to the fields. In fact, the recent
+developments of agriculture have made it not only easy, but in most
+cases profitable, to avoid this waste of materials which has reduced
+so many regions to poverty. We may fairly look forward to the time,
+not long distant, when the old progressive degradation in the
+fertility of the soil coating will no longer occur. It is otherwise
+with the mass of the soil, that body of commingled decayed rock and
+vegetable matter which must possess a certain thickness in order to
+serve its needs. As yet no considerable arrest has been made in the
+processes which lead to the destruction of this earthy mass. In all
+countries where tillage is general the rivers are flowing charged with
+all they can bear away of soil material. Thus in the valley of the Po,
+a region where, if the soil were forest-clad, the down-wearing of the
+surface would probably be at no greater rate than one foot in five
+thousand years, the river bears away the soil detritus so rapidly that
+at the present time the downgoing is at the rate of one foot in eight
+hundred years, and each decade sees the soil disappear from hillsides
+which were once fertile, but are now reduced to bare rocks. All about
+the Mediterranean the traveller notes extensive regions which were
+once covered with luxuriant forests, and were afterward the seats of
+prosperous agriculture, where the soil has utterly disappeared,
+leaving only the bare rocks, which could not recover its natural
+covering in thousands of years of the enforced fallow.</p>
+
+<p>Within the limits of the United States the degradation of the soil,
+owing to the peculiar conditions of the country, is in many districts
+going forward with startling rapidity. It has been the habit of our
+people&mdash;a habit favoured by the wide extent of fertile and easily
+acquired frontier ground&mdash;recklessly to till their farms until the
+fields were exhausted, and then to abandon them for new <span class='pagenum'><a name="Page_346" id="Page_346">[Pg 346]</a></span>ground. By
+shallow ploughing on steep hillsides, by neglect in the beginning of
+those gulches which form in such places, it is easy in the hill
+country of the eastern United States to have the soil washed away
+within twenty years after the protecting forests have been destroyed.
+The writer has estimated that in the States south of the Ohio and
+James Rivers more than eight thousand square miles of originally
+fertile ground have by neglect been brought into a condition where it
+will no longer bear crops of any kind, and over fifteen hundred miles
+of the area have been so worn down to the subsoil or the bed rock that
+it may never be profitable to win it again to agricultural uses.</p>
+
+<p>Hitherto, in our American agriculture, our people have been to a great
+extent pioneers; they have been compelled to win what they could in
+the cheapest possible way and with the rudest implements, and without
+much regard to the future of those who were in subsequent generations
+to occupy the fields which they were conquering from the wilderness
+and the savages. The danger is now that this reckless tillage, in a
+way justified of old, may be continued and become habitual with our
+people. It is, indeed, already a fixed habit in many parts of the
+country, particularly in the South, where a small farmer expects to
+wear out two or three plantations in the course of his natural life.
+Many of them manage to ruin from one to two hundred acres of land in
+the course of half a century of uninterrupted labour. This system
+deserves the reprobation of all good citizens; it would be well,
+indeed, if it were possible to do so, to stamp it out by the law. The
+same principle which makes it illegal for a man to burn his own
+dwelling house may fairly be applied in restraining him from
+destroying the land which he tills.</p>
+
+<p>There are a few simple principles which, if properly applied, may
+serve to correct this misuse of our American soil. The careful tiller
+should note that all soils whatever which lie on declivities having a
+slope of more than <span class='pagenum'><a name="Page_347" id="Page_347">[Pg 347]</a></span>one foot in thirty inevitably and rapidly waste
+when subject to plough tillage. This instrument tends to smear and
+consolidate the layer of earth over which its heel runs, so that at a
+depth of a few inches below the surface a layer tolerably impervious
+to water is formed. The result is that the porous portion of the
+deposit becomes excessively charged with water in times of heavy rain,
+and moves down the hillside in a rapid manner. All such steep slopes
+should be left in their wooded state, or, if brought into use, should
+be retained as pasture lands.</p>
+
+<p>Where, as is often the case with the farms in hilly countries, all the
+fields are steeply inclined, it is an excellent precaution to leave
+the upper part of the slope with a forest covering. In this condition
+not only is the excessive flow of surface water diminished, but the
+moisture which creeps down the slope from the wooded area tends to
+keep the lower-lying fields in a better state for tillage, and
+promotes the decay of the underlying rocks, and thus adds to the body
+and richness of the earth.</p>
+
+<p>On those soils which must be tilled, even where they tend to wash
+away, the aim should be to keep the detritus open to such a depth that
+it may take in as much as possible of the rainfall, yielding the water
+to the streams through the springs. This end can generally be
+accomplished by deep ploughing; it can, in almost all cases, be
+attained by under-drainage. The effect of allowing the water to
+penetrate is not only to diminish the superficial wearing, but to
+maintain the process of subsoil and bed-rock decay by which the
+detrital covering is naturally renewed. Where, as in many parts of the
+country, the washing away of the soil can not otherwise be arrested,
+the progress of the destruction can be delayed by forming with the
+skilful use of the plough ditches of slight declivity leading along
+the hillsides to the natural waterways. One of the most satisfactory
+marks of the improvement which is now taking place in the agriculture
+of the cotton-yielding States of this country is to be found <span class='pagenum'><a name="Page_348" id="Page_348">[Pg 348]</a></span>in the
+rapid increase in the use of the ditch system here mentioned. This
+system, combined with ploughing in the manner where the earth is with
+each overturning thrown uphill, will greatly reduce the destructive
+effect of rainfall on steep-lying fields. But the only effective
+protection, however, is accomplished by carefully terracing the
+slopes, so that the tilled ground lies in level benches. This system
+is extensively followed in the thickly settled portions of Europe, but
+it may be a century before it will be much used in this country.</p>
+
+<p>The duty of the soil-tiller by the earth with which he deals may be
+briefly summed up: He should look upon himself as an agent necessarily
+interfering with the operations which naturally form and preserve the
+soil. He should see that his work brings two risks; he may impoverish
+the accumulation of detrital material by taking out the plant food
+more rapidly than it is prepared for use. This injurious result may be
+at any time reparable by a proper use of manures. Not so, however,
+with the other form of destruction, which results in the actual
+removal of the soil materials. Where neglect has brought about this
+disaster, it can only be repaired by leaving the area to recover
+beneath the slowly formed forest coating. This process in almost all
+cases requires many thousands of years for its accomplishment. The man
+who has wrought such destruction has harmed the inheritance of life.</p>
+
+
+
+<hr style="width: 65%;" /><p><span class='pagenum'><a name="Page_349" id="Page_349">[Pg 349]</a></span></p>
+<h1><a name="CHAPTER_IX" id="CHAPTER_IX"></a>CHAPTER &nbsp; IX.<br/>
+<span class="subtitle smcap">the rocks and their order.</span></h1>
+
+
+<p>In the preceding chapters of this book the attention of the student
+has been directed mainly to the operations of those natural forces
+which act upon the surface of the earth. Incidentally the consequences
+arising from the applications of energy to the outer part of the
+planet have been attended to, but the main aim has been to set forth
+the work which solar energy, operating in the form of heat,
+accomplishes upon the lands. We have now to consider one of the great
+results of these actions, which is exhibited in the successive strata
+that make up the earth's crust.</p>
+
+<p>The most noteworthy effect arising from the action of the solar forces
+on the earth and their co-operation with those which originate in our
+sphere is found in the destruction of beds or other deposits of rock,
+and the removal of the materials to the floors of water basins, where
+they are again aggregated in strata, and gradually brought once more
+into a stable condition within the earth. This work is accomplished by
+water in its various states, the action being directly affected by
+gravitation. In the form of steam, water which has been built into
+rocks and volcanically expelled by tensions, due to the heat which it
+has acquired at great depths below the surface, blows forth great
+quantities of lava, which is contributed to the formation of strata,
+either directly in the solid form or indirectly, after having been
+dissolved in <span class='pagenum'><a name="Page_350" id="Page_350">[Pg 350]</a></span>the sea. Acting as waves, water impelled by solar energy
+transmitted to it by the winds beats against the shores, wearing away
+great quantities of rock, which is dragged off to the neighbouring sea
+bottoms, there to resume the bedded form. Moving ice in glaciers,
+water again applying solar energy given to it by its elevation above
+the sea, most effectively grinds away the elevated parts of the crust,
+the <i>d&eacute;bris</i> being delivered to the ocean. In the rain the same work
+is done, and even in the wind the power of the sun serves to abrade
+the high-lying rocks, making new strata of their fragments.</p>
+
+<p>As gravity enters as an element in all the movements of divided rock,
+the tendency of the waste worn from the land is to gather on to the
+bottoms of basins which contain water. Rarely, and only in a small
+way, this process results in the accumulation of lake deposits; the
+greater part of the work is done upon the sea floor. When the beds are
+formed in lake basins, they may be accumulated in either of two very
+diverse conditions. They may be formed in what are called dead seas,
+in which case the detrital materials are commonly small in amount, for
+the reason that the inflowing streams are inconsiderable; in such
+basins there is normally a large share of saline materials, which are
+laid down by the evaporation of the water. In ordinary lakes the
+deposits which are formed are mostly due to the sediment that the
+rivers import. These materials are usually fine-grained, and the sand
+or pebbles which they contain are plentifully mingled with clay. Hence
+lake deposits are usually of an argillaceous nature. As organic life,
+such as secretes limestone, is rarely developed to any extent in lake
+basins, limy beds are very rarely formed beneath those areas of water.
+Where they occur, they are generally due to the fact that rivers
+charged with limy matter import such quantities of the substance that
+it is precipitated on the bottom.</p>
+
+<p>As lake deposits are normally formed in basins above the level of the
+sea, and as the drainage channels of the <span class='pagenum'><a name="Page_351" id="Page_351">[Pg 351]</a></span>basins are always cutting
+down, the effect is to leave such strata at a considerable height
+above the sea level, where the erosive agents may readily attack them.
+In consequence of this condition, lacustrine beds are rarely found of
+great antiquity; they generally disappear soon after they are formed.
+Where preserved, their endurance is generally to be attributed to the
+fact that the region they occupy has been lowered beneath the sea and
+covered by marine strata.</p>
+
+<p>The great laboratory in which the sedimentary deposits are
+accumulated, the realm in which at least ninety-nine of the hundred
+parts of these materials are laid down, is the oceanic part of the
+earth. On the floors of the seas and oceans we have not only the
+region where the greater part of the sedimentation is effected, but
+that in which the work assumes the greatest variety. The sea bottoms,
+as regards the deposits formed upon them, are naturally divided into
+two regions&mdash;the one in which the <i>d&eacute;bris</i> from the land forms an
+important part of the sediment, and the other, where the remoteness
+of the shores deprives the sediment of land waste, or at least of
+enough of that material in any such share as can affect the character
+of the deposits.</p>
+
+<p>What we may term the littoral or shore zone of the sea occupies a belt
+of prevailingly shallow water, varying in width from a few score to a
+few hundred miles. Where the bottom descends steeply from the coast,
+where there are no strong off-shore setting currents, and where the
+region is not near the mouth of a large river which bears a great tide
+of sediment to the sea, the land waste may not affect the bottom for
+more than a mile or two from the shore. Where these conditions are
+reversed, the <i>d&eacute;bris</i> from the air-covered region may be found three
+or four hundred miles from the coast line. It should also be noted
+that the incessant up-and-down goings of the land result in a constant
+change in the position of the coast line, and consequently in the
+extension of the land sedi<span class='pagenum'><a name="Page_352" id="Page_352">[Pg 352]</a></span>ment, in the course of a few geological
+periods over a far wider field of sea bottom than that to which they
+would attain if the shores remained steadfast.</p>
+
+<p>It is characteristic of the sediments deposited within the influence
+of the continental detritus that they vary very much in their action,
+and that this variation takes place not only horizontally along the
+shores in the same stratum, but vertically, in the succession of the
+beds. It also may be traced down the slope from the coast line to deep
+water. Thus where all the <i>d&eacute;bris</i> comes from the action of the waves,
+the deposits formed from the shore outwardly will consist of coarse
+materials, such as pebbles near the coast, of sand in the deeper and
+remoter section, and of finer silt in the part of the deposit which is
+farthest out. With each change in the level of the coast line the
+position of these belts will necessarily be altered. Where a great
+river enters the sea, the changes in the volume of sediment which it
+from time to time sends forth, together with the alternations in the
+position of its point of discharge, led to great local complexities in
+the strata. Moreover, the turbid water sent forth by the stream may,
+as in the case of the tide from the Amazon, be drifted for hundreds of
+miles along the coast line or into the open sea.</p>
+
+<p>The most important variations which occur in the deposits of the
+littoral zone are brought about by the formations of rocks more or
+less composed of limestone. Everywhere the sea is, as compared with
+lake waters, remarkably rich in organic life. Next the shore, partly
+because the water is there shallow, but also because of its relative
+warmth and the extent to which it is in motion, organic life, both
+that of animals and plants, commonly develops in a very luxuriant way.
+Only where the bottom is composed of drifting sands, which do not
+afford a foothold for those species which need to rest upon the shore,
+do we fail to find that surface thickly tenanted with varied forms.
+These are arranged according to the <span class='pagenum'><a name="Page_353" id="Page_353">[Pg 353]</a></span>depth of the bottom. The species
+of marine plants which are attached to fixed objects are limited to
+the depth within which the sunlight effectively penetrates the water;
+in general, it may be said that they do not extend below a depth of
+one hundred feet. The animal forms are distributed, according to their
+kinds, over the floor, but few species having the capacity to endure
+any great range in the pressure of the sea water. Only a few forms,
+indeed, extend from low tide to the depth of a thousand feet.</p>
+
+<p>The greatest development of organic life, the realm in which the
+largest number of species occur, and where their growth is most rapid,
+lies within about a hundred feet of the low-tide level. Here sunlight,
+warmth, and motion in the water combine to favour organic development.
+It is in this region that coral reefs and other great accumulations of
+limestone, formed from the skeletons of polyps and mollusks, most
+abundantly occur. These deposits of a limy nature depend upon a very
+delicate adjustment of the conditions which favour the growth of
+certain creatures; very slight geographic changes, by inducing
+movements of sand or mud, are apt to interrupt their formation,
+bringing about a great and immediate alteration in the character of
+the deposits. Thus it is that where geologists find considerable
+fields of rock, where limestones are intercalated with sandstones and
+deposits of clay, they are justified in assuming that the strata were
+laid down near some ancient shore. In general, these coast deposits
+become more and more limy as we go toward the tropical realms, and
+this for the reason that the species which secrete large amounts of
+lime are in those regions most abundant and attain the most rapid
+growth. The stony polyps, the most vigorous of the limestone makers,
+grow in large quantities only in the tropical realm, or near to it,
+where ocean streams of great warmth may provide the creatures with the
+conditions of temperature and food which they need.</p>
+
+<p><span class='pagenum'><a name="Page_354" id="Page_354">[Pg 354]</a></span></p><p>As we pass from the shore to the deeper sea, the share of land
+detritus rapidly diminishes until, as before remarked, at the distance
+of five hundred miles from the coast line, very little of that waste,
+except that from volcanoes, attains the bottom of the sea. By far the
+larger part of the contributions which go to the formation of these
+deep-sea strata come from organic remains, which are continually
+falling upon the sea floor. In part, this waste is derived from
+creatures which dwell upon the bottom; in considerable measure,
+however, it is from the dead bodies of those forms which live near the
+surface of the sea, and which when dying sink slowly through the
+intermediate realm to the bottom.</p>
+
+<p>Owing to the absence of sunlight, the prevailingly cold water of the
+deeper seas, and the lack of vegetation in those realms, the growth of
+organic forms on the deep-sea floor is relatively slow. Thus it
+happens that each shell or other contribution to the sediment lies for
+some time on the bottom before it is buried. While in this condition
+it is apt to be devoured by some of the many species which dwell on
+the bottom and subsist from the remains of animals and plants which
+they find there. In all cases the fossilization of any form depends
+upon the accumulation of sediment before the processes of destruction
+have overtaken them, and among these processes we must give the first
+place to the creatures which subsist on shells, bones, or other
+substances of like nature which find their way to the ocean floor. In
+the absolute darkness, the still water, and the exceeding cold of the
+deeper seas, animals find difficult conditions for development.
+Moreover, in this deep realm there is no native vegetation, and, in
+general, but little material of this nature descends to the bottom
+from the surface of the sea. The result is, the animals have to
+subsist on the remains of other animals which at some step in the
+succession have obtained their provender from the plants which belong
+on the surface or in the shallow waters of the sea.<span class='pagenum'><a name="Page_355" id="Page_355">[Pg 355]</a></span> This limitation
+of the food supply causes the depths of the sea to be a realm of
+continual hunger, a region where every particle of organic matter is
+apt to be seized upon by some needy creature.</p>
+
+<p>In consequence of the fact that little organic matter on the deeper
+sea floors escapes being devoured, the most of the material of this
+nature which goes into strata enters that state in a finely divided
+condition. In the group of worms alone&mdash;forms which in a great
+diversity of species inhabit the sea floor&mdash;we find creatures which
+are specially adapted to digesting the <i>d&eacute;bris</i> which gathers on the
+sea bottom. Wandering over this surface, much in the manner of our
+ordinary earthworms, these creatures devour the mud, voiding the
+matter from their bodies in a yet more perfectly divided form. Hence
+it comes about that the limestone beds, so commonly formed beneath the
+open seas, are generally composed of materials which show but few and
+very imperfect fossils. Studying any series of limestone beds, we
+commonly find that each layer, in greater or less degree, is made up
+of rather massive materials, which evidently came to their place in
+the form of a limy mud. Very often this lime has crystallized, and
+thus has lost all trace of its original organic structure.</p>
+
+<p>One of the conspicuous features which may be observed in any
+succession of limestone beds is the partings or divisions into layers
+which occur with varied frequency. Sometimes at vertical intervals of
+not more than one or two inches, again with spacings of a score of
+feet, we find divisional planes, which indicate a sudden change in the
+process of rock formation. The lime disappears, and in place of it we
+have a thin layer of very fine detritus, which takes on the form of a
+clay. Examining these partings with care, we observe that on the upper
+surface on the limestone the remains of the animal which dwelt on the
+ancient sea floor are remarkably well preserved, they having evidently
+escaped the effect of the process which <span class='pagenum'><a name="Page_356" id="Page_356">[Pg 356]</a></span>reduced their ancestors,
+whose remains constitute the layer, to mud. Furthermore, we note that
+the shaly layer is not only lacking in lime, but commonly contains no
+trace of animals such as might have dwelt on the bottom. The fossils
+it bears are usually of species which swam in the overlying water and
+came to the bottom after death. Following up through the layer of
+shale, we note that the ordinary bottom life gradually reappears, and
+shortly becomes so plentiful that the deposit resumes the character
+which it had before the interruption began. Often, however, we note
+that the assemblage of species which dwelt on the given area of sea
+floor has undergone a considerable change. Forms in existence in the
+lower layer may be lacking in the upper, their place being taken by
+new varieties.</p>
+
+<p>So far the origin of these divisional planes in marine deposits has
+received little attention from geologists; they have, indeed, assumed
+that each of these alterations indicates some sudden disturbance of
+the life of the sea floors. They have, however, generally assumed that
+the change was due to alterations in the depth of the sea or in the
+run of ocean currents. It seems to the writer, however, that while
+these divisions may in certain cases be due to the above-mentioned
+and, indeed, to a great variety of causes, they are in general best to
+be explained by the action of earthquakes. Water being an exceedingly
+elastic substance, an earthquake passes through it with much greater
+speed than it traverses the rocks which support the ocean floor. The
+result is that, when the fluid and solid oscillate in the repeated
+swingings which a shock causes, they do not move together, but rub
+over each other, the independent movements having the swing of from a
+few inches to a foot or two in shocks of considerable energy.</p>
+
+<p>When the sea bottom and the overlying water, vibrating under the
+impulse of an earthquake shock, move past each other, the inevitable
+result is the formation of muddy <span class='pagenum'><a name="Page_357" id="Page_357">[Pg 357]</a></span>water; the very fine silt of the
+bottom is shaken up into the fluid, which afterward descends as a
+sheet to its original position. It is a well-known fact that such
+muddying of water, in which species accustomed to other conditions
+dwell, inevitably leads to their death by covering their breathing
+organs and otherwise disturbing the delicately balanced conditions
+which enable them to exist. We find, in fact, that most of the tenants
+of the water, particularly the forms which dwell upon the bottom, are
+provided with an array of contrivances which enable them to clear away
+from their bodies such small quantities of silt as may inconvenience
+them. Thus, in the case of our common clam, the breathing organs are
+covered with vibratory cilia, which, acting like brooms, sweep off any
+foreign matter which may come upon their surfaces. Moreover, the
+creature has a long, double, spoutlike organ, which it can elevate
+some distance above the bottom, through which it draws and discharges
+the water from which it obtains food and air. Other forms, such as the
+crinoids, or sea lilies, elevate the breathing parts on top of tall
+stems of marvellous construction, which brings those vital organs at
+the level, it may be, of three or four feet above the zone of mud. In
+consequence of the peculiar method of growth, the crinoids often
+escape the damage done by the disturbance of the bottom, and thus form
+limestone beds of remarkable thickness; sometimes, indeed, we find
+these layers composed mainly of crinoidal remains, which exhibit only
+slight traces of partings such as we have described, being essentially
+united for the depth of ten or twenty feet. Where the layers have been
+mainly accumulated by shellfish, their average thickness is less than
+half a foot.</p>
+
+<p>When we examine the partitions between the layers of limestone, we
+commonly find that, however thin, they generally extend for an
+indefinite distance in every direction. The writer has traced some of
+these for miles; never, indeed, has he been able to find where they
+disappeared.<span class='pagenum'><a name="Page_358" id="Page_358">[Pg 358]</a></span> This fact makes it clear that the destruction which took
+place at the stage where these partings were formed was widespread; so
+far as it was due to earthquake shocks, we may fairly believe that in
+many cases it occurred over areas which were to be measured by tens of
+thousands of square miles. Indeed, from what we know of earthquake
+shocks, it seems likely that the devastation may at times have
+affected millions of square miles.</p>
+
+<p>Another class of accidents connected with earthquakes may also
+suddenly disturb the mud on the sea bottom. When, as elsewhere noted,
+a shock originates beneath the sea, the effect is suddenly to elevate
+the water over the seat of the jarring and the regions thereabouts to
+the height of some feet. This elevation quickly takes the shape of a
+ringlike wave, which rolls off in every direction from its point of
+origin. Where the sea is deep, the effect of this wave on the bottom
+may be but slight; but as the undulation attains shallower water, and
+in proportion to the shoaling, the front of the surge is retarded in
+its advance by the friction of the bottom, while the rear part, being
+in deeper water, crowds upon the advancing line. The action is
+precisely that which has been described as occurring in wind-made
+waves as they approach the beach; but in this last-named group of
+undulations, because of the great width of the swell, the effect of
+the shallowing is evident in much deeper water. It is likely that at
+the depth of a thousand feet the passing of one of these vast surges
+born of earthquakes may so stir the mud of the sea floor as to bring
+about a widespread destruction of life, and thus give rise to many of
+the partitions between strata.</p>
+
+<p>If we examine with the microscope the fine-grained silts which make up
+the shaly layers between limestones, we find the materials to be
+mostly of inorganic origin. It is hard to trace the origin of the
+mineral matter which it contains; some of the fragments are likely to
+prove of Volcanic origin; others, bits of dust from meteorites; yet
+<span class='pagenum'><a name="Page_359" id="Page_359">[Pg 359]</a></span>others, dust blown from the land, which may, as we know, be conveyed
+for any distance across the seas. Mingled with this sediment of an
+inorganic origin we almost invariably find a share of organic waste,
+derived not from creatures which dwelt upon the bottom, but from those
+which inhabited the higher-lying waters. If, now, we take a portion of
+the limestone layer which lies above or below the shale parting, and
+carefully dissolve out with acids the limy matter which it contains,
+we obtain a residuum which in general character, except so far as the
+particles may have been affected by the acid, is exactly like the
+material which forms the claylike partition. We are thus readily led
+to the conclusion that on the floors of the deeper seas there is
+constantly descending, in the form of a very slow shower, a mass of
+mineral detritus. Where organic life belonging to the species which
+secrete hard shells or skeletons is absent, this accumulation,
+proceeding with exceeding slowness, gradually accumulates layers,
+which take on a shaly character. Where limestone-making animals
+abound, they so increase the rate of deposition that the proportion of
+the mineral material in the growing strata is very much reduced; it
+may, indeed, become as small as one per cent of the mass. In this case
+we may say that the deposit of limestone grew a hundred times as fast
+as the intervening beds of shale.</p>
+
+<p>The foregoing considerations make it tolerably clear that the sea
+floor is in receipt of two diverse classes of sediment&mdash;those of a
+mineral and those of an organic origin. The mineral, or inorganic,
+materials predominate along the shores. They gradually diminish in
+quantity toward the open sea, where the supply is mainly dependent on
+the substances thrown forth from volcanoes, on pumice in its massive
+or its comminuted form&mdash;i.e., volcanic dust, states of lava in which
+the material, because of the vesicles which it contains, can float for
+ages before it comes to rest on the sea bottom. Variations in the
+volcanic waste contributed to the sea floor may somewhat <span class='pagenum'><a name="Page_360" id="Page_360">[Pg 360]</a></span>affect the
+quantity of the inorganic sediments, but, as a whole, the downfalling
+of these fragments is probably at a singularly uniform rate. It is
+otherwise with the contributions of sediment arising from organic
+forms. This varies in a surprising measure. On the coral reefs, such
+as form in the mid oceans, the proportion of matter which has not come
+into the accumulation through the bodies of animals and plants may be
+as small as one tenth of one per cent, or less. In the deeper seas, it
+is doubtful whether the rate of animal growth is such as to permit the
+formation of any beds which have less than one half of their mass made
+up of materials which fell through the water.</p>
+
+<p>In certain areas of the open seas the upper part of the water is dwelt
+in by a host of creatures, mostly foraminifera, which extract
+limestone from the water, and, on dying, send their shells to the
+bottom. Thus in the North Atlantic, even where the sea floor is of
+great depth beneath the surface, there is constantly accumulating a
+mass of limy matter, which is forming very massive limestone strata,
+somewhat resembling chalk deposits, such as abundantly occur in Great
+Britain, in the neighbouring parts of Europe, in Texas, and elsewhere.
+Accumulations such as this, where the supply is derived from the
+surface of the water, are not affected by the accidents which divide
+beds made on the bottom in the manner before described. They may,
+therefore, have the singularly continuous character which we note in
+the English chalk, where, for the thickness of hundreds of feet, we
+may have no evident partitions, except certain divisions, which have
+evidently originated long after the beds were formed.</p>
+
+<p>We have already noted the fact that, while the floors of the deeper
+seas appear to lack mountainous elevations, those arising from the
+folding of strata, they are plentifully scattered over with volcanic
+cones. We may therefore suppose that, in general, the deposits formed
+on the sea floor are to a great extent affected by the materials which
+these vents cast forth. Lava streams and showers <span class='pagenum'><a name="Page_361" id="Page_361">[Pg 361]</a></span>represent only a
+part of the contributions from volcanoes, which finally find their way
+to the bottom. In larger part, the materials thrown forth are probably
+first dissolved in the water and then taken up by the organic species;
+only after the death of these creatures does the waste go to the
+bottom. As hosts of these creatures have no solid skeleton to
+contribute to the sea floor, such mineral matter as they may obtain is
+after their death at once restored to the sea.</p>
+
+<p>Not only does the contribution of organic sediment diminish in
+quantity with the depth which is attained, but the deeper parts of the
+ocean bed appear to be in a condition where no accumulations of this
+nature are made, and this for the reason that the water dissolves the
+organic matter more rapidly than it is laid down. Thus in place of
+limestone, which would otherwise form, we have only a claylike
+residuum, such as is obtained when we dissolve lime rocks in acids.
+This process of solution, by which the limy matter deposited on the
+bottom is taken back into the water, goes on everywhere, but at a rate
+which increases with the depth. This increase is due in part to the
+augmentation of pressure, and in part to the larger share of carbonic
+dioxide which the water at great depths holds. The result is, that
+explorations with the dredge seem to indicate that on certain parts of
+the deeper sea floors the rocks are undergoing a process of
+dissolution comparable to that which takes place in limestone caverns.
+So considerable is the solvent work that a large part of the inorganic
+waste appears to be taken up by the waters, so as to leave the bottom
+essentially without sedimentary accumulations. The sea, in a word,
+appears to be eating into rocks which it laid down before the
+depression attained its present great depth.</p>
+
+<p>We should here note something of the conditions which determine the
+supply of food which the marine animals obtain. First of all, we may
+recur to the point that the ocean waters appear to contain something
+of all the earth <span class='pagenum'><a name="Page_362" id="Page_362">[Pg 362]</a></span>materials which do not readily decompose when they
+are taken into the state of solution. These mineral substances,
+including the metals, are obtained in part from the lands, through the
+action of the rain water and the waves, but perhaps in larger share
+from the volcanic matter which, in the form of floating lava, pumice,
+or dust, is plentifully delivered to the sea. Except doubtfully, and
+at most in a very small way, this chemical store of the sea water can
+not be directly taken into the structures of animals; it can only be
+immediately appropriated by the marine plants. These forms can only
+develop in that superficial realm of the seas which is penetrated by
+the sunlight, or say within the depth of five hundred feet, mostly
+within one hundred feet of the surface, about one thirtieth of the
+average, and about one fiftieth of the maximum ocean depth. On this
+marine plant life, and in a small measure on the vegetable matter
+derived from the land, the marine animals primarily depend for their
+provender. Through the conditions which bring about the formation of
+<i>Sargassum</i> seas, those areas of the ocean where seaweeds grow afloat,
+as well as by the water-logging and weighting down of other vegetable
+matter, some part of the plant remains is carried to the sea floor,
+even to great depths; but the main dependence of the deep-sea forms of
+animals is upon other animal forms, which themselves may have obtained
+their store from yet others. In fact, in any deep-sea form we might
+find it necessary to trace back the food by thousands of steps before
+we found the creature which had access to the vegetable matter. It is
+easy to see how such conditions profoundly limit the development of
+organic being in the abysm of the ocean.</p>
+
+<p>The sedentary animals, or those which are fixed to the sea bottom&mdash;a
+group which includes the larger part of the marine species&mdash;have to
+depend for their sustenance on the movement of the water which passes
+their station. If the seas were perfectly still, none of these
+creatures except the most minute could be fed; therefore <span class='pagenum'><a name="Page_363" id="Page_363">[Pg 363]</a></span>the currents
+of the ocean go far by their speed to determine the rate at which life
+may flourish. At great depths, as we have seen, these movements are
+practically limited to that which is caused by the slow movement which
+the tide brings about. The amount of this motion is proportional to
+the depth of the sea; in the deeper parts, it carries the water to and
+fro twice each day for the distance of about two hundred and fifty
+feet. In the shallower water this motion increases in proportion to
+the shoaling, and in the regions near the shores the currents of the
+sea which, except the massive drift from the poles, do not usually
+touch the bottom, begin to have their influence. Where the water is
+less than a hundred feet in depth, each wave contributes to the
+movement, which attains its maximum near the shore, where every surge
+sweeps the water rapidly to and fro. It is in this surge belt, where
+the waves are broken, that marine animals are best provided with food,
+and it is here that their growth is most rapid. If the student will
+obtain a pint of water from the surf, he will find that it is clouded
+by fragments of organic matter, the quantity in a pound of the fluid
+often amounting to the fiftieth part of its weight. He will thus
+perceive that along the shore line, though the provision of victuals
+is most abundant, the store is made from the animals and plants which
+are ground up in the mill. In a word, while the coast is a place of
+rapid growth, it is also a region of rapid destruction; only in the
+case of the coral animals, which associate their bodies with a number
+of myriads in large and elaborately organized communities, do we find
+animals which can make such head against the action of the waves that
+they can build great deposits in their realm.</p>
+
+<p>It should be noted that a part of the advantage which is afforded to
+organic life by the shore belt is due to the fact that the waters are
+there subjected to a constant process of a&euml;ration by the whipping into
+foam and spray which occurs where the waves overturn.</p>
+
+<p><span class='pagenum'><a name="Page_364" id="Page_364">[Pg 364]</a></span></p><p>It will be interesting to the student to note the great number of
+mechanical contrivances which have been devised to give security to
+animals and plants which face these difficult conditions arising from
+successive violent blows of falling water. Among these may be briefly
+noted those of the limpets&mdash;mollusks which dwell in a conical shell,
+which faces the water with a domelike outside, and which at the moment
+of the stroke is drawn down upon the rock by the strong muscle which
+fastens the creature to its foundation. The barnacles, which with
+their wedge-shaped prows cut the water at the moment of the stroke,
+but open in the pauses between the waves, so that the creature may
+with its branching arms grasp at the food which floats about it; the
+nullipores, forms of seaweed which are framed of limestone and cling
+firmly to the rock&mdash;afford yet other instances of protective
+adaptations contrived to insure the safety of creatures which dwell in
+the field of abundant food supply.</p>
+
+<hr style='width: 45%;' />
+
+<p>The facts above presented will show the reader that the marine
+sediments are formed under conditions which permit a great variety in
+the nature of the materials of which they are composed. As soon as the
+deposits are built into rocks and covered by later accumulations,
+their materials enter the laboratory of the under earth, where they
+are subjected to progressive changes. Even before they have attained a
+great depth, through the laying down of later deposits upon them,
+changes begin which serve to alter their structure. The fragments of a
+soluble kind begin to be dissolved, and are redeposited, so that the
+mass commonly becomes much more solid, passing from the state of
+detritus to that of more or less solid rock. When yet more deeply
+buried, and thereby brought into a realm of greater warmth, or perhaps
+when penetrated by dikes and thereby heated, these changes go yet
+further. More of the material is commonly rearranged by solution and
+redeposition, so that limestone may be converted into <span class='pagenum'><a name="Page_365" id="Page_365">[Pg 365]</a></span>crystalline
+marble, granular sandstones into firm masses, known as quartzites, and
+clays into the harder form of slate. Where the changes go to the
+extreme point, rocks originally distinctly bedded probably may be so
+taken to pieces and made over that all traces of their stratification
+may be destroyed, all fossils obliterated, and the stone transformed
+into mica schist, or granite or other crystalline rock. It may be
+injected into the overlying strata in the form of dikes, or it may be
+blown forth into the air through volcanoes. Involved in
+mountain-folding, after being more or less changed in the manner
+described, the beds may become tangled together like the rumpled
+leaves of a book, or even with the complexity of snarled thread. All
+these changes of condition makes it difficult for the geologist to
+unravel the succession of strata so that he may know the true order of
+the rocks, and read from them the story of the successive geological
+periods. This task, though incomplete, has by the labours of many
+thousand men been so far advanced that we are now able to divide the
+record into chapters, the divisions of the geologic ages, and to give
+some account of the succession of events, organic and geographic,
+which have occurred since life began to write its records.</p>
+
+
+<h2 class="subtitle smcap">Earthquakes.</h2>
+
+<p>In ordinary experience we seem to behold the greater part of the earth
+which meets our eyes as fixed in its position. A better understanding
+shows us that nothing in this world is immovable. In the realm of the
+inorganic world the atoms and molecules even in solid bodies have to
+be conceived as endowed with ceaseless though ordered motions. Even
+when matter is built into the solid rock, it is doubtful whether any
+grain of it ever comes really to rest. Under the strains which arise
+from the contraction of the earth's interior and the chemical changes
+which the rocks undergo, each bit is subject to ever-changing
+<span class='pagenum'><a name="Page_366" id="Page_366">[Pg 366]</a></span>thrusts, which somewhat affect its position. If we in any way could
+bring a grain of sand from any stratum under a microscope, so that we
+could perceive its changes of place, we should probably find that it
+was endlessly swaying this way and that, with reference to an ideally
+fixed point, such as the centre of the earth. But even that centre,
+whether of gravity or of figure, is probably never at rest.</p>
+
+<p>Earth movements may be divided into two groups&mdash;those which arise from
+the bodily shifting of matter, which conveys the particles this way or
+that, or, as we say, change their place, and those which merely
+produce vibration, in which the particles, after their vibratory
+movement, return to their original place. For purposes of illustration
+the first, or translatory motion, may be compared to that which takes
+place when a bell is carried along upon a locomotive or a ship; and
+the second, or vibratory movement, to what takes place when the bell
+is by a blow made to ring. It is with these ringing movements, as we
+may term them, that we find ourselves concerned when we undertake the
+study of earthquakes.</p>
+
+<p>It is desirable that the reader should preface his study of
+earthquakes by noting the great and, at the same time, variable
+elasticity of rocks. In the extreme form this elasticity is very well
+shown when a toy marble, which is made of a close-textured rock, such
+as that from which it derives its name, is thrown upon a pavement
+composed of like dense material. Experiment will show that the little
+sphere can often be made to bounce to the height of twenty feet
+without breaking. If, then, with the same energy the marble is thrown
+upon a brick floor, the rebound will be very much diminished. It is
+well to consider what happens to produce the rebound. When the sphere
+strikes the floor it changes its shape, becoming shorter in the axis
+at right angles to the point which was struck, and at the same instant
+expanded along the equator of that axis. The flattening remains for
+only a <span class='pagenum'><a name="Page_367" id="Page_367">[Pg 367]</a></span>small fraction of a second; the sphere vibrates so that it
+stretches along the line on which it previously shortened, and, as
+this movement takes place with great swiftness, it may be said to
+propel itself away from the floor. At the same time a similar movement
+goes on in the rock of the floor, and, where the rate of vibration is
+the same, the two kicks are coincident, and so the sphere is impelled
+violently away from the point of contact. Where the marble comes in
+contact with brick, in part because of the lesser elasticity of that
+material, due to its rather porous structure, and partly because it
+does not vibrate at the same rate as the marble, the expelling blow is
+much less strong.</p>
+
+<p>All rocks whatever, even those which appear as incoherent sands, are
+more or less set into vibratory motion whenever they are struck by a
+blow. In the crust of the earth various accidents occur which may
+produce that sudden motion which we term a blow. When we have examined
+into the origin of these impulses, and the way in which they are
+transmitted through the rocks, we obtain a basis for understanding
+earthquake shocks. The commonest cause of the jarrings in the earth is
+found in the formation of fractures, known as faults. If the reader
+has ever been upon a frozen lake at a time when the weather was
+growing colder, and the ice, therefore, was shrinking, he may have
+noted the rending sound and the slight vibration which comes with the
+formation of a crack traversing the sheet of ice. At such a time he
+feels a movement which is an earthquake, and which represents the
+simpler form of those tremors arising from the sudden rupture of fault
+planes. If he has a mind to make the experiment, he may hang a bullet
+by a thread from a small frame which rests upon the ice, and note that
+as the vibration occurs the little pendulum sways to and fro, thus
+indicating the oscillations of the ice. The same instrument will move
+in an identical manner when affected by a quaking in the rocks.</p>
+
+<p><span class='pagenum'><a name="Page_368" id="Page_368">[Pg 368]</a></span></p><p>Where the rocks are set in vibration by a rent which is formed in
+them, the phenomena are more complicated, and often on a vastly larger
+scale than in the simple conditions afforded by a sheet of ice. The
+rocks on either side of the rupture generally slide over each other,
+and the opposing masses are rent in their friction upon one another;
+the result is, not only the first jar formed by the initial fracture,
+but a great many successive movements from the other breakages which
+occur. Again, in the deeper parts of the crust, the fault fissures are
+often at the moment of their formation filled by a violent inrush of
+liquid rock. This, as it swiftly moves along, tears away masses from
+the walls, and when it strikes the end of the opening delivers a blow
+which may be of great violence. The nature of this stroke may be
+judged by the familiar instance where the relatively slow-flowing
+stream from a hydrant pipe is suddenly choked by closing the stopcock.
+Unless the plumber provides a cushion of air to diminish the energy of
+the blow, it is often strong enough to shake the house. Again, when
+steam or other gases are by a sudden diminution of pressure enabled to
+expand, they may deliver a blow which is exactly like that caused by
+the explosion of gunpowder, which, even when it rushes against the
+soft cushion of the air, may cause a jarring that may be felt as well
+as heard to a great distance. Such movements very frequently occur in
+the eruptions of volcanoes; they cause a quivering of the earth, which
+may be felt for a great distance from the immediate seat of the
+disturbance.</p>
+
+<p>When by any of the sudden movements which have been above described a
+jar is applied to the rocks, the wave flies through the more or less
+elastic mass until the energy involved in it is exhausted. This may
+not be brought about until the motion has travelled for the distance
+of hundreds of miles. In the great earthquake of 1755, known as the
+Lisbon shock, the records make it seem probable that the movement was
+felt over one eighth <span class='pagenum'><a name="Page_369" id="Page_369">[Pg 369]</a></span>part of the earth's surface. Such great
+disturbances probably bring about a motion of the rocks near the point
+of origin, which may be expressed in oscillations having an amplitude
+of one to two feet; but in the greater number of earthquakes the
+maximum swing probably does not exceed the tenth of that amount. Very
+sensible shaking, even such as may produce considerable damage to
+buildings, are caused by shocks in which the earth vibrates with less
+than an inch of swing.</p>
+
+<p>When a shock originates, the wave in the rocks due to the compression
+which the blow inflicts runs at a speed varying with the elasticity of
+the substance, but at the rate of about fifteen hundred feet a second.
+The movements of this wave are at right angles to the seat of the
+originating disturbance, so that the shock may come to the surface in
+a line forming any angle between the vertical and the nearly
+horizontal. Where, as in a volcanic eruption, the shock originates
+with an explosion, these waves go off in circles. Where, however, as
+is generally the case, the shock originates in a fault plane, which
+may have a length and depth of many miles, the movement has an
+elliptical form.</p>
+
+<p>If the earthquake wave ran through a uniform and highly elastic
+substance, such as glass, it would move everywhere with equal speed,
+and, in the case of the greater disturbances, the motion might be felt
+over the whole surface of the earth. But as the motion takes place
+through rocks of varying elasticity, the rate at which it journeys is
+very irregular. Moving through materials of one density, and with a
+rate of vibration determined by those conditions, the impulse is with
+difficulty communicated to strata which naturally vibrate at another
+speed. In many cases, as where a shock passing through dense
+crystalline strata encounters a mass of soft sandstone, the wave, in
+place of going on, is reflected back toward its point of origin. These
+earthquake echoes sometimes give rise to very destructive movements.
+It often happens that <span class='pagenum'><a name="Page_370" id="Page_370">[Pg 370]</a></span>before the original tremors of a shock have
+passed away from a point on the surface the reflex movements rush in,
+making a very irregular motion, which may be compared to that of the
+waves in a cross-sea.</p>
+
+<p>The foregoing account of earthquake action will serve to prepare the
+reader for an understanding of those very curious and important
+effects which these accidents produce in and on the earth. Below the
+surface the sensible action of earthquake shocks is limited. It has
+often been observed that people in mines hardly note a swaying which
+may be very conspicuous to those on the surface, the reason for this
+being that underground, where the rocks are firmly bound together, all
+those swingings which are due to the unsupported position of such
+objects as buildings, columnar rocks, trees, and the waters of the
+earth, are absent. The effect of the movements which earthquakes
+impress on the under earth is mainly due to the fact that in almost
+every part of the crust tensions or strains of other kinds are
+continually forming. These may for ages prove without effect until the
+earth is jarred, when motions will suddenly take place which in a
+moment may alter the conditions of the rocks throughout a wide field.
+In a word, a great earthquake caused by the formation of an extensive
+fault is likely to produce any number of slight dislocations, each of
+which is in turn shock-making, sending its little wave to complicate
+the great oscillation. Nor does the perturbing effect of these jarring
+movements cease with the fractures which they set up and the new
+strains which are in turn developed by the motions which they induce.
+The alterations of the rocks which are involved in chemical changes
+are favoured by such motions. It is a familiar experience that a
+vessel of water, if kept in the state of repose, may have its
+temperature lowered three or four degrees below the freezing point
+without becoming frozen. If the side of the vessel is then tapped with
+the finger, so as to send a slight quake through the mass, it will
+instantly congeal. Molecular <span class='pagenum'><a name="Page_371" id="Page_371">[Pg 371]</a></span>rearrangements are thus favoured by
+shocks, and the consequences of those which run through the earth are,
+from a chemical point of view, probably important.</p>
+
+<p>The reader may help himself to understand something of the complicated
+problem of earth tensions, and the corresponding movements of the
+rocks, by considering certain homely illustrations. He may observe how
+the soil cracks as it shrinks in times of drought, the openings
+closing when it rains. In a similar way the frozen earth breaks open,
+sometimes with a shock which is often counted as an earthquake. Again,
+the ashes in a sifter or the gravel on a sieve show how each shaking
+may relieve certain tensions established by gravity, while they create
+others which are in turn to be released by the next shock. An ordinary
+dwelling house sways and strains with the alternations of temperature
+and moisture to which it is subjected in the round of climatal
+alterations. Now and then we note the movements in a cracking sound,
+but by far the greater part of them escape observation.</p>
+
+<p>With this sketch of the mechanism of earthquake shocks we now turn to
+consider their effects upon the surface of the earth. From a
+geological point of view, the most important effect of earthquake
+shocks is found in the movement of rock masses down steep slopes,
+which is induced by the shaking. Everywhere on the land the agents of
+decay and erosion tend to bring heavy masses into position where
+gravitation naturally leads to their downfall, but where they may
+remain long suspended, provided they are not disturbed. Thus, wherever
+there are high and steep cliffs, great falls of rock are likely to
+occur when the earthquake movements traverse the under earth. In more
+than one instance observers, so placed that they commanded a view of
+distant mountains, have noticed the downfall of precipices in the path
+of the shock before the trembling affected the ground on which they
+stood. In the famous earthquake of 1783, which devastated southern
+Italy, the Prince of Scylla persuaded his <span class='pagenum'><a name="Page_372" id="Page_372">[Pg 372]</a></span>people to take refuge in
+their boats, hoping that they might thereby escape the destruction
+which threatened them on the land. No sooner were the unhappy folk on
+the water than the fall of neighbouring cliffs near the sea produced a
+great wave, which overwhelmed the vessels.</p>
+
+<p>Where the soil lies upon steep slopes, in positions in which it has
+accumulated during ages of tranquillity, a great shock is likely to
+send it down into the valleys in vast landslides. Thus, in the
+earthquake of 1692, the Blue Mountains of Jamaica were so violently
+shaken that the soil and the forests which stood on it were
+precipitated into the river beds, so that many tree-clad summits
+became fields of bare rock. The effect of this action is immensely to
+increase the amount of detritus which the streams convey to the sea.
+After the great Jamaica shock, above noted, the rivers for a while
+ceased to flow, their waters being stored in the masses of loose
+material. Then for weeks they poured forth torrents of mud and the
+<i>d&eacute;bris</i> of vegetation&mdash;materials which had to be swept away as the
+streams formed new channels.</p>
+
+<p>In all regions where earthquake movements are frequent, and the shock
+of considerable violence, the trained observer notes that the surfaces
+of bare rock are singularly extensive, the fact being that many of
+these areas, where the slope lies at angles of from ten to thirty
+degrees, which in an unshaken region would be thickly soil-covered,
+are deprived of the coating by the downward movement of the waste
+which the disturbances bring about. A familiar example of this action
+may be had by watching the workmen engaged in sifting sand, by casting
+the material on a sloping grating. The work could not be done but for
+an occasional blow applied to the sifter. An arrangement for such a
+jarring motion is commonly found in various ore-dressing machines,
+where the object is to move fragments of matter over a sloping
+surface.</p>
+
+<p>Even where the earth is so level that an earthquake shock does not
+cause a sliding motion of the materials, <span class='pagenum'><a name="Page_373" id="Page_373">[Pg 373]</a></span>such as above described,
+other consequences of the shaking may readily be noted. As the motion
+runs through the mass, provided the movement be one of considerable
+violence, crevices several feet in width, and sometimes having the
+length of miles, are often formed. In most cases these fissures,
+opened by one pulsation of the shock, are likely to be closed by the
+return movement, which occurs the instant thereafter. The consequences
+of this action are often singular, and in cases constitute the most
+frightful elements of a shock which the sufferer beholds. In the great
+earthquake of 1811, which ravaged the section of the Mississippi
+Valley between the mouth of the Ohio and Vicksburg, these crevices
+were so numerously formed that the pioneers protected themselves from
+the danger of being caught in their jaws by felling trees so that they
+lay at right angles to the direction in which the rents extended,
+building on these timbers platforms to support their temporary
+dwelling places. The records of earthquakes supply many instances in
+which people have been caught in these earth fissures, and in a single
+case it is recorded that a man who disappeared into the cavity was in
+a moment cast forth in the rush of waters which in this, as in many
+other cases, spouts forth as the walls of the opening come together.</p>
+
+<p>Sometimes these rents are attended by a dislocation, which brings the
+earth on one side much higher than on the other. The step thus
+produced may be many miles in length, and may have a height of twenty
+feet or more. It needs no argument to show that we have here the top
+of a fault such as produced the shock, or it may be one of a secondary
+nature, such as any earthquake is likely to bring about in the strata
+which it traverses. In certain cases two faults conjoin their action,
+so that a portion of the surface disappears beneath the earth,
+entombing whatever may have stood on the vanished site. Thus in the
+great shock known as that of Lisbon, which occurred in 1755, the stone
+quay along the harbour, where many thou<span class='pagenum'><a name="Page_374" id="Page_374">[Pg 374]</a></span>sand people had sought refuge
+from the falling buildings of the city, suddenly sank down with the
+multitude, and the waters closed over it; no trace of the people or of
+the structure was to be found after the shock was over. There is a
+story to the effect that during the same earthquake an Arab village in
+northern Africa sank down, the earth on either side closing over it,
+so that no trace of the habitations remained. In both these instances
+the catastrophes are best explained by the diagram.</p>
+
+<div class="figleft" style="width: 299px;">
+<img src="images/f21.jpg" width="299" height="282" alt="Fig. 21.&mdash;Diagram showing how a portion of the earth&#39;s
+surface may be sunk by faulting. Fig. A shows the original position;
+B, the position after faulting; b b&#39; and c c&#39; the planes of the
+faults; the arrows the direction of the movement." title="" />
+<span class="figcaption">Fig. 21.&mdash;Diagram showing how a portion of the earth&#39;s
+surface may be sunk by faulting. Fig. A shows the original position;
+B, the position after faulting; b b&#39; and c c&#39; the planes of the
+faults; the arrows the direction of the movement.</span>
+</div>
+
+<p>In the earthquake of 1811 the alluvial plains on either side of the
+Mississippi at many points sank down so that arable land was converted
+into lakes; the area of these depressions probably amounted to some
+hundred square miles. The writer, on examining these sunken lands,
+found that the subsidences had occurred where the old moats or
+abandoned channels of the great river had been filled in with a
+mixture of decaying timber and river silt. When violently shaken, this
+loose-textured <i>d&eacute;bris</i> naturally settled down, so that it formed a
+basin occupied by a crescent-shaped lake. The same process of settling
+plentifully goes on wherever the rocks are still in an uncemented
+state. The result is often the production of changes which lead to the
+expulsion of gases. Thus, in the Charleston earthquake of 1883, the
+surface over an area <span class='pagenum'><a name="Page_375" id="Page_375">[Pg 375]</a></span>of many hundred square miles was pitted with
+small craters, formed by the uprush of water impelled by its contained
+gases. These little water volcanoes&mdash;for such we may call
+them&mdash;sometimes occur to the number of a dozen or more on each acre of
+ground in the violently shaken district. They indicate one result of
+the physical and chemical alterations which earthquake shocks bring
+about. As earthquakes increase in violence their effect upon the soil
+becomes continually greater, until in the most violent shocks all the
+loose materials on the surface of the earth may be so shaken about as
+to destroy even the boundaries of fields. After the famous earthquake
+of Riobamba, which occurred on the west coast of South America in
+1797, the people of the district in which the town of that name was
+situated were forced to redivide their land, the original boundaries
+having disappeared. Fortunately, shocks of this description are
+exceedingly rare. They occur in only a few parts of the world.</p>
+
+<p>Certain effects of earthquakes where the shock emerges beneath the sea
+have been stated in the account of volcanic eruptions (see page <a href="#Page_299">299</a>).
+We may therefore note here only certain of the more general facts.
+While passing through the deep seas, this wave may have a height of
+not more than two or three feet and a width of some score miles. As it
+rolls in upon the shore the front of the undulation is retarded by the
+friction of the bottom in such a measure that its speed is diminished,
+while the following part of the waves, being less checked, crowds up
+toward this forward part. The result is, that the surge mounts ever
+higher and higher as it draws near the shore, upon which it may roll
+as a vast wave having the height of fifty feet or more and a width
+quite unparalleled by any wave produced from wind action. Waves of
+this description are most common in the Pacific Ocean. Although but
+occasional, the damage which they may inflict is very great. As the
+movement approaches the shore, vessels, however well anchored, are
+dragged away <span class='pagenum'><a name="Page_376" id="Page_376">[Pg 376]</a></span>to seaward by the great back lash of the wave, a
+phenomenon which may be perceived even in the case of the ordinary
+surf. Thus forced to seaward, the crews of the ships may find their
+vessels drawn out for the distance of some miles, until they come near
+the face of the advancing billow. This, as it approaches the shore,
+straightens up to the wall-fronted form, and then topples upon the
+land. Those vessels which are not at once crushed down by the blow are
+generally hurled far inland by the rush of waters. In the great
+Jamaica earthquake of 1692 a British man-of-war was borne over the
+tops of certain warehouses and deposited at a distance from the shore.</p>
+
+<p>Owing to the fact that water is a highly elastic material, the shocks
+transmitted to it from the bottom are sent onward with their energy
+but little diminished. While the impulse is very violent, these
+oscillations may prove damaging to shipping. The log-books of mariners
+abound in stories of how vessels were dismasted or otherwise badly
+shaken by a sudden blow received in the midst of a quiet sea. The
+impression commonly conveyed to the sailors is that the craft has
+struck upon a rock. The explanation is that an earthquake jar, in
+traversing the water, has delivered its blow to the ship. As the speed
+of this jarring movement is very much greater than that of any
+ordinary wave, the blow which it may strike may be most destructive.
+There seems, indeed, little reason to doubt that a portion of the
+vessels which are ever disappearing in the wilderness of the ocean are
+lost by the crushing effect of these quakings which pass through the
+waters of the deep.</p>
+
+<p>We have already spoken of the earthquake shock as an oscillation. It
+is a quality of all bodies which oscillate under the influence of a
+blow, such as originates in earthquake shocks, to swing to and fro,
+after the manner of the metal in a bell or a tuning fork, in a
+succession of movements, each less than the preceding, until the
+impulse is worn out, or rather, we should in strict sense <span class='pagenum'><a name="Page_377" id="Page_377">[Pg 377]</a></span>say,
+changed to other forms of energy. The result is, that even in the
+slightest earthquake shock the earth moves not once to and fro, but
+very many times. In a considerable shock the successive diminishing
+swingings amount to dozens before they become so slight as to elude
+perception. Although the first swaying is the strongest, and generally
+the most destructive, the quick to-and-fro motions are apt to continue
+and to complete the devastation which the first brings about. The
+vibrations due to any one shock take place with great rapidity. They
+may, indeed, be compared to those movements which we perceive in the
+margin of a large bell when it has received a heavy blow from the
+clapper. The reader has perhaps seen that for a moment the rim of the
+bell vibrates with such rapidity that it has a misty look&mdash;that is,
+the motions elude the sight. It is easy to see that a shaking of this
+kind is particularly calculated to disrupt any bodies which stand free
+in the air and are supported only at their base.</p>
+
+<p>In what we may call the natural architecture of the earth, the
+pinnacles and obelisks, such as are formed in many high countries, the
+effect of these shakings is destructive, and, as we have seen, even
+the firmer-placed objects, such as the strong-walled cliffs and steep
+slopes of earth, break down under the assaults. It is therefore no
+matter of surprise that the buildings which man erects, where they are
+composed of masonry, suffer greatly from these tremblings. In almost
+all cases human edifices are constructed without regard to other
+problems of strength than those which may be measured by their weight
+and the resistance to fracture from gravitation alone. They are not
+built with expectation of a quaking, but of a firm-set earth.</p>
+
+<p>The damage which earthquakes do to buildings is in most cases due to
+the fact that they sway their walls out of plumb, so that they are no
+longer in position to support the weight which they have to bear. The
+amount of this swaying is naturally very much greater than that <span class='pagenum'><a name="Page_378" id="Page_378">[Pg 378]</a></span>which
+the earth itself experiences in the movement. A building of any height
+with its walls unsupported by neighbouring structures may find its
+roof rocked to and fro through an arc which has a length of feet,
+while its base moves only through a length of inches. The reader may
+see an example of this nature if he will poise a thin book or a bit of
+plank a foot long on top of a small table; then jarring the table so
+that it swings through a distance of say a quarter of an inch, he will
+see that the columnar object swings at its top through a much greater
+distance, and is pretty sure to be overturned.</p>
+
+<p>Where a building carries a load in its upper parts, such as may be
+afforded by its heavy roof or the stores which it contains, the effect
+of an earthquake shock such as carries the earth to and fro becomes
+much more destructive than it might otherwise be. This weight lags
+behind when the earth slips forward in the first movement of the
+oscillation, with the effect that the walls of the building are pretty
+sure to be thrust so far beyond the perpendicular that they give way
+and are carried down by the weight which they bore. It has often been
+remarked in earthquake shocks that tall columns, even where composed
+of many blocks, survive a shock which overturns lower buildings where
+thin walls support several floors, on each of which is accumulated a
+considerable amount of weight. In the case of the column, the strains
+are even, and the whole structure may rock to and fro without toppling
+over. As the energy of the undulations diminish, it gradually regains
+the quiet state without damage. In the ordinary edifice the irregular
+disposition of the weight does not permit the uniform movement which
+may insure safety. Thus, if the city of Washington should ever be
+violently shaken, the great obelisk, notwithstanding that it is five
+hundred feet high, may survive a disturbance which would wreck the
+lower and more massive edifices which lie about it.</p>
+
+<p>Where, as is fortunately rarely the case, the great shock <span class='pagenum'><a name="Page_379" id="Page_379">[Pg 379]</a></span>comes to
+the earth in a vertical direction, the effect upon all movable objects
+is in the highest measure disastrous. In such a case buildings are
+crushed as if by the stroke of a giant's hand. The roofs and floors
+are at one stroke thrown to the foundations, and all the parts of the
+walls which are not supported by strong masonry continuous from top to
+bottom are broken to pieces. In such cases it has been remarked that
+the bodies of men are often thrown considerable distances. It is
+asserted, indeed, that in the Riobamba shock they were cast upward to
+the height of more than ninety feet. It is related that the solo
+survivor of a congregation which had hastened at the outset of the
+disturbance into a church was thrown by the greatest and most
+destructive shock upward and through a window the base of which was at
+the height of more than twenty feet from the ground.</p>
+
+<p>It is readily understood that an earthquake shock may enter a building
+in any direction between the vertical and the horizontal. As the
+movement exhausts itself in passing from the place of its origin, the
+horizontal shocks are usually of least energy. Those which are
+accurately vertical are only experienced where the edifices are placed
+immediately over the point where the motion originates. It follows,
+therefore, that the destructive work of earthquakes is mainly
+performed in that part of the field where the motion is, as regards
+its direction, between the vertical and the horizontal&mdash;a position in
+which the edifice is likely to receive at once the destructive effect
+arising from the sharp upward thrust of the vertical movement and the
+oscillating action of that which is in a horizontal direction. Against
+strains of this description, where the movements have an amplitude of
+more than a few inches, no ordinary masonry edifice can be made
+perfectly safe; the only tolerable security is attained where the
+building is of well-framed timber, which by its elasticity permits a
+good deal of motion without destructive consequences. Even such
+buildings, however, <span class='pagenum'><a name="Page_380" id="Page_380">[Pg 380]</a></span>those of the strongest type, may be ruined by the
+greater earthquakes. Thus, in the Mississippi Valley earthquake of
+1811, the log huts of the frontiersmen, which are about as strong as
+any buildings can be made, were shaken to pieces by the sharp and
+reiterated shocks.</p>
+
+<p>It is by no means surprising to find that the style of architecture
+adopted in earthquake countries differs from that which is developed
+in regions where the earth is firm-set. The people generally learn
+that where their buildings must meet the trials of earthquakes they
+have to be low and strong, framed in the manner of fortifications, to
+withstand the assault of this enemy. We observe that Gothic
+architecture, where a great weight of masonry is carried upon slender
+columns and walls divided by tall windows, though it became the
+dominant style in the relatively stable lands of northern Europe,
+never gained a firm foothold in those regions about the Mediterranean
+which are frequently visited by severe convulsions of the earth. There
+the Grecian or the Romanesque styles, which are of a much more massive
+type, retain their places and are the fashions to the present day.
+Even this manner of building, though affording a certain security
+against slight tremblings, is not safe in the greater shocks. Again
+and again large areas in southern Italy have been almost swept of
+their buildings by the destructive movements which occur in that
+realm. The only people who have systematically adapted their
+architectural methods to earthquake strains are the Japanese, who in
+certain districts where such risks are to be encountered construct
+their dwellings of wood, and place them upon rollers, so that they may
+readily move to and fro as the shock passes beneath them. In a measure
+the people of San Francisco have also provided against this danger by
+avoiding dangerous weights in the upper parts of their buildings, as
+well as the excessive height to which these structures are lifted in
+some of our American towns.</p>
+
+<p>Earthquakes of sensible energy appear to be limited <span class='pagenum'><a name="Page_381" id="Page_381">[Pg 381]</a></span>to particular
+parts of the earth's crust. The regions, indeed, where within the
+period of human history shocks of devastating energy have occurred do
+not include more than one fifteenth part of the earth's surface. There
+is a common notion that these movements are most apt to happen in
+volcanic regions. It is, indeed, true that sensible shocks commonly
+attend the explosions from great craters, but the records clearly show
+that these movements are very rarely of destructive energy. Thus in
+the regions about the base of Vesuvius and of &AElig;tna, the two volcanoes
+of which most is known, the shocks have never been productive of
+extensive disaster. In fact, the reiterated slight jarrings which
+attend volcanic action appear to prevent the formation of those great
+and slowly accumulated strains which in their discharge produce the
+most violent tremblings of the earth. The greatest and most continuous
+earthquake disturbances of history&mdash;that before noted in the early
+days of this century, in the Mississippi Valley, where shocks of
+considerable violence continued for two years&mdash;came about in a field
+very far removed from active volcanoes. So, too, the disturbances
+beneath the Atlantic floor which originated the shocks that led to the
+destruction of Lisbon, and many other similar though less violent
+movements, are developed in a field apparently remote from living
+volcanoes. Eastern New England, which has been the seat of several
+considerable earthquakes, is about as far away from active vents as
+any place on the habitable globe. We may therefore conclude that,
+while volcanoes necessarily produce shocks resulting from the
+discharge of their gases and the intrusion of lava into the dikes
+which are formed about them, the greater part of the important shocks
+are in no wise connected with volcanic explosions.</p>
+
+<p>With the exception of the earthquake in the Mississippi Valley, all
+the great shocks of which we have a record have occurred in or near
+regions where the rocks have been extensively disturbed by
+mountain-building <span class='pagenum'><a name="Page_382" id="Page_382">[Pg 382]</a></span>forces, and where the indications lead us to
+believe that dislocations of strata, such as are competent to rive the
+beds asunder, may still be in progress. This, taken in connection with
+the fact that many of these shocks are attended by the formation of
+fault planes, which appear on the surface, lead us to the conclusion
+that earthquakes of the stronger kind are generally formed by the
+riving of fissures, which may or may not be developed upward to the
+surface. This view is supported by many careful observations on the
+effect which certain great earthquakes have exercised on the buildings
+which they have ravaged. The distinguished observer, Mr. Charles
+Mallet, who visited the seat of the earthquake which, in 1854,
+occurred in the province of Calabria in Italy, with great labour and
+skill determined the direction in which the shock moved through some
+hundreds of edifices on which it left the marks of its passage.
+Platting these lines of motion, he found that they were all referred
+to a vertical plane lying at the depth of some miles beneath the
+surface, and extending for a great distance in a north and south
+direction. This method of inquiry has been applied to other fields,
+with the result that in the case of all the instances which have been
+subjected to this inquiry the seat of the shock has been traced to
+such a plane, which can best be accounted for by the supposition of a
+fault.</p>
+
+<p>The method pursued by Mr. Mallet in his studies of the origin of
+earthquakes, and by those who have continued his inquiry, may be
+briefly indicated as follows: Examining disrupted buildings, it is
+easy to determine those which have been wrecked by a shock that
+emerged from the earth in a vertical direction. In these cases, though
+tall walls may remain standing, the roofs and floors are thrown into
+the cellars. With a dozen such instances the plane of what is called
+the seismic vertical is established (<i>seismos</i> is the Greek for
+earthquake). Then on either side of this plane, which indicates the
+line but not the depth of the disturbance, other observations may <span class='pagenum'><a name="Page_383" id="Page_383">[Pg 383]</a></span>be
+made which give the clew to the depth. Thus a building may be found
+where the northwest corner at its upper part has been thrown off. Such
+a rupture was clearly caused by an upward but oblique movement, which
+in the first half of the oscillation heaved the structure upwardly
+into the northwest, and then in the second half, or rebound, drew the
+mass of the building away from the unsupported corner, allowing that
+part of the masonry to fly off and fall to the ground. Constructing a
+line at right angles to the plane of the fracture, it will be found to
+intersect the plane, the position of which has been in part determined
+by finding the line where it intersects the earth, or the seismic
+vertical before noted. Multiplying such observations on either side of
+the last-mentioned line, the attitude of the underground parts of the
+plane, as well as the depth to which it attained, can be approximately
+determined.</p>
+
+<p>It is worth while to consider the extent to which earthquake shocks
+may affect the general quality of the people who dwell in countries
+where these disturbances occur with such frequency and violence as to
+influence their lives. There can be no question that wherever
+earthquakes occur in such a measure as to produce widespread terror,
+where, recurring from time to time, they develop in men a sense of
+abiding insecurity, they become potent agents of degradation. All the
+best which men do in creating a civilization rests upon a sense of
+confidence that their efforts may be accumulated from year to year,
+and that even after death the work of each man may remain as a
+heritage to his kind. It is likely, indeed, that in certain realms, as
+in southern Italy, a part of the failure of the people to advance in
+culture is due to their long experience of such calamities, and the
+natural expectation that they will from time to time recur. In a
+similar way the Spanish settlements in Central and South America,
+which lie mostly in lands that are subject to disastrous shocks, may
+have been retarded by <span class='pagenum'><a name="Page_384" id="Page_384">[Pg 384]</a></span>the despair, as well as the loss of property
+and life, which these accidents have so frequently inflicted upon
+them. It will not do, however, to attribute too much to such
+terrestrial influences. By far the most important element in
+determining the destiny of a people is to be found in their native
+quality, that which they owe to their ancestors of distant
+generations. In this connection it is well to consider the history of
+the Icelandic people, where a small folk has for a thousand years been
+exposed to a range and severity of trials, such as earthquakes,
+volcanic explosions, and dearth of harvests may produce, and all these
+in a measure that few if any other countries experience.
+Notwithstanding these misfortunes, the Icelanders have developed and
+maintained a civilization which in all else, except its material
+results, on the average transcends that which has been won by any
+other folk in modern times. If a people have the determining spirit
+which leads to high living, they can successfully face calamities far
+greater than those which earthquakes inflict.</p>
+
+<p>It was long supposed that the regions where earthquakes are not
+noticeable by the unaided senses were exempt from all such
+disturbances. The observations which seismologists have made in recent
+years point to the conclusion that no part of the earth's surface is
+quite exempt from movements which, though not readily perceived, can
+be made visible by the use of appropriate instruments. With an
+apparatus known as the horizontal pendulum it is possible to observe
+vibrations which do not exceed in amplitude the hundredth part of an
+inch. This mechanism consists essentially of a slender bar supported
+near one end by two wires, one from above, the other from below. It
+may readily be conceived that any measurable movement will cause the
+longer end of the rod to sway through a considerable arc. Wherever
+such a pendulum has been carefully observed in any district, it has
+been found that it indicates the occurrence of slight <span class='pagenum'><a name="Page_385" id="Page_385">[Pg 385]</a></span>tremors. Even
+certain changes of the barometer, which alter the weight of the
+atmosphere that rests upon the earth to the amount indicated by an
+inch in the height of the mercury column, appears in all cases to
+create such tremors. Many of these slight shocks may be due to the
+effect of more violent quakings, which have run perhaps for thousands
+of miles from their point of origin, and have thus been reduced in the
+amplitude of their movement. Others are probably due to the slight
+motion brought about through the chemical changes of the rocks, which
+are continuously going on. The ease with which even small motions are
+carried to a great distance may be judged by the fact that when the
+ground is frozen the horizontal pendulum will indicate the jarring due
+to a railway train at the distance of a mile or more from the track.</p>
+
+<p>In connection with the earth jarring, it would be well to note the
+occurrence of another, though physically different, kind of movement,
+which we may term earth swayings, or massive movements, which slowly
+dislocate the vertical, and doubtless also the horizontal, position of
+points upon its surface. It has more than once been remarked that in
+mountain countries, where accurate sights have been taken, the heights
+of points between the extremities of a long line appear somewhat to
+vary in the course of a term of years. Thus at a place in the
+Apennines, where two buildings separated by some miles of distance are
+commonly intervisible over the crest of a neighbouring peak, it has
+happened that a change of level of some one of the points has made it
+impossible to see the one edifice from the other. Knowing as we do
+that the line of the seacoast is ever-changing, uprising taking place
+at some points and down-sinking at others, it seems not unlikely that
+these irregular swayings are of very common occurrence. Moreover,
+astronomers are beginning to remark the fact that their observatories
+appear not to remain permanently in the same position&mdash;that <span class='pagenum'><a name="Page_386" id="Page_386">[Pg 386]</a></span>is, they
+do not have exactly the same latitude and longitude. Certain of these
+changes have recently been explained by the discovery of a new and
+hitherto unnoted movement of the polar axis. It is not improbable,
+however, that the irregular swaying of the earth's crust, due to the
+folding of strata and to the alterations in the volume of rocks which
+are continually going on, may have some share in bringing about these
+dislocations.</p>
+
+<p>Measured by the destruction which was wrought to the interests of man,
+earthquakes deserve to be reckoned among the direst calamities of
+Nature. Since the dawn of history the records show us that the
+destruction of life which is to be attributed to them is to be counted
+by the millions. A catalogue of the loss of life in the accidents of
+this description which have occurred during the Christian era has led
+the writer to suppose that probably over two million persons have
+perished from these shocks in the last nineteen centuries.
+Nevertheless, as compared with other agents of destruction, such as
+preventable disease, war, or famine, the loss which has been inflicted
+by earth movements is really trifling, and almost all of it is due to
+an obstinate carelessness in the construction of buildings without
+reference to the risks which are known to exist in earthquake-ridden
+countries.</p>
+
+<p>Although all our exact knowledge concerning the distribution of
+earthquakes is limited to the imperfect records of two or three
+thousand years, it is commonly possible to measure in a general way
+the liability to such accidents which may exist in any country by a
+careful study of the details of its topography. In almost every large
+area the process of erosion naturally leaves quantities of rock,
+either in the form of detached columns or as detrital accumulations
+deposited on steep slopes. These features are of relatively slow
+formation, and it is often possible to determine that they have been
+in their positions for a time which is to be measured by thousands of
+years. Thus, on inspecting a country such as North America, <span class='pagenum'><a name="Page_387" id="Page_387">[Pg 387]</a></span>where the
+historic records cover but a brief time, we may on inquiry determine
+which portions of its area have long been exempt from powerful shocks.
+Where natural obelisks and steep taluses abound&mdash;features which would
+have disappeared if the region had been moved by great shocks&mdash;we may
+be sure that the field under inspection has for a great period been
+exempt from powerful shaking. Judged by this standard, we may safely
+say that the region occupied by the Appalachian Mountains has been
+exempt from serious trouble. So, too, the section of the Cordilleras
+lying to the east of what is commonly called the Great Basin, between
+the Rocky Mountains and the Sierra Nevada, has also enjoyed a long
+reign of peace. In glaciated countries the record is naturally less
+clear than in those parts of the world which have been subjected to
+long-continued, slow decay of the rocks. Nevertheless, in those fields
+boulders are often found poised in position which they could not have
+maintained if subjected to violent shaking. Judged by this evidence,
+we may say that a large part of the northern section of this
+continent, particularly the area about the Great Lakes, has been
+exempt from considerable shocks since the glacier passed away.</p>
+
+<p>The shores which are subject to the visitations of the great marine
+waves, caused by earthquake shocks occurring beneath the bottom of the
+neighbouring ocean, are so swept by those violent inundations that
+they lose many features which are often found along coasts that have
+been exempted from such visitations. Thus wherever we find extensive
+and delicately moulded dunes, poised stones, or slender pinnacled
+rocks along a coast, we may be sure that since these features were
+formed the district has not been swept by these great waves.</p>
+
+<p><span class='pagenum'><a name="Page_388" id="Page_388">[Pg 388]</a></span></p>
+<div class="figcenter" style="width: 429px;">
+<img src="images/f22.jpg" width="429" height="543" alt="Fig. 22.&mdash;Poised rocks indicating a long exemption from
+strong earthquakes in the places where such features occur." title="" />
+<span class="figcaption">Fig. 22.&mdash;Poised rocks indicating a long exemption from
+strong earthquakes in the places where such features occur.</span>
+</div>
+
+<p>Around the northern Atlantic we almost everywhere find the glacial
+waste here and there accumulated near the margin of the sea in the
+complicated sculptured outlines which are assumed by kame sands and
+gravels. From a study of these features just above the level of high
+tide, the writer has become convinced that the North Atlantic district
+has long been exempt from the assaults of other waves than those which
+are produced during heavy storms.<span class='pagenum'><a name="Page_389" id="Page_389">[Pg 389]</a></span> At the present time the waves
+formed by earthquakes appear to be of destructive violence only on the
+west coast of South America, where they roll in from a region of the
+Pacific lying to the south of the equator and a few hundred miles from
+the shore of the continent, which appears to be the seat of
+exceedingly violent shocks. A similar field occurs in the Atlantic
+between the Lesser Antilles and the Spanish peninsula, but no great
+waves have come thence since the time of the Lisbon earthquake. The
+basin of the Caribbean and the region about Java appear to be also
+fields where these disturbances may be expected, though in each but
+one wave of this nature has been recorded. Therefore we may regard
+these secondary results of a submarine earthquake as seldom phenomena.</p>
+
+
+<h2 class="subtitle smcap">Duration of Geological Time.</h2>
+
+<p>Although it is beyond the power of man to conceive any such lapses of
+time as have taken place in the history of this earth, it is
+interesting, and in certain ways profitable, to determine as near as
+possible in the measure of years the duration of the events which are
+recorded in the rocks. Some astronomers, basing their conclusions on
+the heat-containing power of matter, and on the rate at which energy
+in this form flows from the sun, have come to the conclusion that our
+planet could not have been in independent existence for more than
+about twenty million years. The geologist, however, resting his
+conclusions on the records which are the subject of his inquiry, comes
+on many different lines to an opinion which traverses that entertained
+by some distinguished astronomers. The ways in which the student of
+the earth arrives at this opinion will now be set forth.</p>
+
+<p>By noting the amount of sediment carried forth to the sea by the
+rivers, the geologist finds that the lands of the earth&mdash;those, at
+least, which are protected by their natural envelopes of
+vegetation&mdash;are wearing down at a <span class='pagenum'><a name="Page_390" id="Page_390">[Pg 390]</a></span>rate which pretty certainly does
+not exceed one foot in about five thousand years, or two hundred feet
+in a million years. Discovering at many places on the earth's surface
+deposits which originally had a thickness of five thousand feet or
+more, which have been worn down to the depths of thousands of feet in
+a single rather brief section of geological time, the student readily
+finds himself prepared to claim that a period of from five to ten
+million years has often been required for the accomplishment of but a
+very small part of the changes which he knows to have occurred on this
+earth.</p>
+
+<p>As the geologist follows down through the sections of the stratified
+rocks, and from the remains of strata determines the erosion which has
+borne away the greater part of the thick deposits which have been
+exposed to erosion, he comes upon one of those breaks in the
+succession, or encounters what is called an unconformity, as when
+horizontal strata lie against those which are tilted. In many cases he
+may observe that at this time there was a great interval unrepresented
+by deposits at the place where his observations are made, yet a great
+lapse of time is indicated by the fact that a large amount of erosion
+took place in the interval between the two sets of beds.</p>
+
+<p>Putting together the bits of record, and assuming that the rate of
+erosion accomplished by the agents which operate on the land has
+always been about the same, the geologist comes to the conclusion that
+the section of the rocks from the present day to the lowest strata of
+the Laurentian represents in the time required for their formation not
+less than a hundred million years; more likely twice that duration. To
+this argument objection is made by some naturalists that the agents of
+erosion may have been more active in the past than they are at
+present. They suggest that the rainfall may have been much greater or
+the tides higher than they now are. Granting all that can be claimed
+on this score, we note the fact that the rate of erosion evidently
+does not increase in <span class='pagenum'><a name="Page_391" id="Page_391">[Pg 391]</a></span>anything like a proportionate way with the
+amount of rainfall. Where a country is protected by its natural
+coating of vegetation, the rain is delivered to the streams without
+making any considerable assault upon the surface of the earth, however
+large the fall may be. Moreover, the tides have little direct cutting
+power; they can only remove detritus which other agents have brought
+into a condition to be borne away. The direct cutting power of the
+tidal movement does not seem to be much greater in the Bay of Fundy,
+where the maximum height of the waves amounts to fifty feet, than on
+the southern coast of Massachusetts, where the range is not more than
+five. So far as the observer can judge, the climatal conditions and
+the other influences which affect the wear of rocks have not greatly
+varied in the past from what they are at the present day. Now and then
+there have been periods of excessive erosion; again, ages in which
+large fields were in the conditions of exceeding drought. It is,
+however, a fair presumption that these periods in a way balance each
+other, and that the average state was much like that which we find at
+present.</p>
+
+<p>If after studying the erosive phenomena exhibited in the structure of
+the earth the student takes up the study of the accumulations of
+strata, and endeavours to determine the time required for the laying
+down of the sediments, he finds similar evidence of the earth's great
+antiquity. Although the process of deposition, which has given us the
+rocks visible in the land masses, has been very much interrupted, the
+section which is made by grouping the observations made in various
+fields shows that something like a maximum thickness of a hundred and
+fifty thousand feet of beds has been accumulated in that part of
+geologic time during which strata were being laid down in the fields
+that are subjected to our study. Although in these rocks there are
+many sets of beds which were rapidly formed, the greater part of them
+have been accumulated with exceeding slowness. Many fine shales, <span class='pagenum'><a name="Page_392" id="Page_392">[Pg 392]</a></span>such
+as those which plentifully occur in the Devonian beds of this country,
+must have required a thousand years or more for the deposition of the
+materials that now occupy an inch in depth. In those sections a single
+foot of the rock may well represent a period of ten thousand years. In
+many of the limestones the rate of accumulation could hardly have been
+more speedy. The reckoning has to be rough, but the impression which
+such studies make upon the mind of the unprejudiced observer is to the
+effect that the thirty miles or so of sedimentary deposits could not
+have been formed in less than a hundred million years. In this
+reckoning it should be noted that no account is taken of those great
+intervals of unrecorded time, such as elapsed between the close of the
+Laurentian and the beginning of the Cambrian periods.</p>
+
+<p>There is a third way in which we may seek an interpretation of
+duration from the rocks. In each successive stage of the earth's
+history, in different measure in the various ages, mountains were
+formed which in time, during their exposure to the conditions of the
+land, were worn down to their roots and covered by deposits
+accumulated during the succeeding ages. A score or more of these
+successively constructed series of elevations may readily be observed.
+Of old, it was believed that mountain ranges were suddenly formed, but
+there is, however, ample evidence to prove that these disturbed
+portions of the strata were very gradually dislocated, the rate of the
+mountainous growth having been, in general, no greater in the past
+than it is at the present day, when, as we know full well, the
+movements are going on so slowly that they escape observation. Only
+here and there, as an attendant on earthquake shocks or other related
+movements of the crust, do we find any trace of the upward march which
+produces these elevations. Although not a subject for exact
+measurements, these features of mountain growth indicate a vast lapse
+of time, during which the elevations were formed and worn away.</p>
+
+<p><span class='pagenum'><a name="Page_393" id="Page_393">[Pg 393]</a></span></p><p>Yet another and very different method by which we may obtain some
+gauge of the depths of the past is to be found in the steps which have
+led organic life from its lowest and earliest known forms to the
+present state of advancement. Taking the changes of species which have
+occurred since the beginning of the last ice epoch, we find that the
+changes which have been made in the organic life have been very small;
+no naturalist who has obtained a clear idea of the facts will question
+the statement that they are not a thousandth part of the alterations
+which have occurred since the Laurentian time. The writer is of the
+opinion that they do not represent the ten thousandth part of those
+vast changes. These changes are limited in the main to the
+disappearance of a few forms, and to slight modifications in those
+previously in existence which have survived to the present day. So far
+as we can judge, no considerable step in the organic series has taken
+place in this last great period of the earth's history, although it
+has been a period when, as before noted, all the conditions have
+combined to induce rapid modifications in both animals and plants. If,
+then, we can determine the duration of this period, we may obtain a
+gauge of some general value.</p>
+
+<p>Although we can not measure in any accurate way the duration of the
+events which have taken place since the last Glacial period began to
+wane, a study of the facts seems to show that less than a hundred
+thousand years can not well be assumed for this interval. Some of the
+students who have approached the subject are disposed to allow a
+period of at least twice this length as necessary for the perspective
+which the train of events exhibits. Reckoning on the lowest estimate,
+and counting the organic changes which take place during the age as
+amounting to the thousandth part of the organic changes since the
+Laurentian age, we find ourselves in face once again of that
+inconceivable sum which was indicated by the physical record.</p>
+
+<p><span class='pagenum'><a name="Page_394" id="Page_394">[Pg 394]</a></span></p><p>Here, again, the critics assert that there may have been periods in
+the history of the earth when the changes of organic life occurred in
+a far swifter manner than in this last section of the earth's history.
+This supposition is inadmissible, for it rests on no kind of proof; it
+is, moreover, contraindicated by the evident fact that the advance in
+the organic series has been more rapid in recent time than at any
+stage of the past. In a word, all the facts with which the geologist
+deals are decidedly against the assumption that terrestrial changes in
+the organic or the inorganic world ever proceed in a spasmodic manner.
+Here and there, and from time to time, local revolutions of a violent
+nature undoubtedly occur, but, so far as we may judge from the aspect
+of the present or the records of the past, these accidents are
+strictly local; the earth has gone forward in its changes much as it
+is now advancing. Its revolutions have been those of order rather than
+those of accident.</p>
+
+<p>The first duty of the naturalist is to take Nature as he finds it. He
+must avoid supposing any methods of action which are not clearly
+indicated in the facts that he observes. The history of his own and of
+all other sciences clearly shows that danger is always incurred where
+suppositions as to peculiar methods of action are introduced into the
+interpretation. It required many centuries of labour before the
+students of the earth came to adopt the principle of explaining the
+problems with which they had to deal by the evidence that the earth
+submitted to them. Wherever they trusted to their imaginations for
+guidance, they fell into error. Those who endeavour to abbreviate our
+conception of geologic time by supposing that in the olden days the
+order of events was other than that we now behold are going counter to
+the best traditions of the science.</p>
+
+<p>Although the aspect of the record of life since the beginning of the
+Cambrian time indicates a period of at least a hundred million years,
+it must not be supposed <span class='pagenum'><a name="Page_395" id="Page_395">[Pg 395]</a></span>that this is the limit of the time required
+for the development of the organic series. All the important types of
+animals were already in existence in that ancient period with the
+exception of the vertebrates, the remains of which have apparently now
+been traced down to near the Cambrian level. In other words, at the
+stage where we first find evidence of living beings the series to
+which they belong had already climbed very far above the level of
+lifeless matter. Few naturalists will question the statement that half
+the work of organic advance had been accomplished at the beginning of
+the Cambrian rocks. The writer is of the opinion that the development
+which took place before that age must have required a much longer
+period than has elapsed from that epoch to the present day. We thus
+come to the conclusion that the measurement of duration afforded by
+organic life indicates a yet more lengthened claim of events, and
+demands more time than appears to be required for the formation of the
+stratified rocks.</p>
+
+<p>The index of duration afforded by the organic series is probably more
+trustworthy than that which is found in the sedimentary strata, and
+this for the reason that the records of those strata have been
+subjected to numerous and immeasurable breaks, while the development
+of organic life has of necessity been perfectly continuous. The one
+record can at any point be broken without interrupting the sequences;
+the other does not admit of any breaches in the continuity.</p>
+
+
+<h2 class="subtitle smcap">The Moon.</h2>
+
+<p>Set over against the earth&mdash;related to, yet contrasted with it in many
+ways&mdash;the moon offers a most profitable object to the student of
+geology. He should often turn to it for those lessons which will be
+briefly noted.</p>
+
+<p>In the beginning of their mutual history the materials of earth and
+moon doubtless formed one vaporous body which had been parted from the
+concentrating mass <span class='pagenum'><a name="Page_396" id="Page_396">[Pg 396]</a></span>of the sun in the manner noted in the sketch of
+the history of the solar system. After the earth-moon body had
+gathered into a nebulous sphere, it is most likely that a ring
+resembling that still existing about Saturn was formed about the
+earth, which in time consolidated into the satellite. Thenceforth the
+two bodies were parted, except for the gravitative attraction which
+impelled them to revolve about their common centre of gravity, and
+except for the light and heat they might exchange with one another.</p>
+
+<p>The first stages after the parting of the spheres of earth and moon
+appear to have been essentially the same in each body. Concentrating
+upon their centres, they became in time fluid by heat; further on,
+they entered the rigid state&mdash;in a word, they froze&mdash;at least in their
+outer parts. At this point in their existence their histories utterly
+diverge; or rather, we may say, the development of the earth continued
+in a vast unfolding, while that of the moon appears to have been
+absolutely arrested in ways which we will now describe.</p>
+
+<p>With the naked eye we see on the moon a considerable variation in the
+light of different parts of its surface; we discern that the darker
+patches appear to be rudely circular, and that they run together on
+their margins. Seeing this little, the ancients fancied that our
+satellite had seas and lands like the earth. The first telescopes did
+not dispel their fancies; even down to the early part of this century
+there were astronomers who believed the moon to be habitable; indeed,
+they thought to find evidence that it was the dwelling place of
+intelligent beings who built cities, and who tried to signal their
+intellectual kindred of this planet. When, however, strong glasses
+were applied to the exploration, these pleasing fancies were rudely
+dispelled.</p>
+
+<p>Seen with a telescope of the better sort, the moon reveals itself to
+be in large part made up of circular depressions, each surrounded by a
+ringlike wall, with nearly <span class='pagenum'><a name="Page_397" id="Page_397">[Pg 397]</a></span>level but rough places between. The
+largest of these walled areas is some four hundred miles in diameter;
+thence they grade down to the smallest pits which the glass can
+disclose, which are probably not over as many feet across. The writer,
+from a careful study of these pits, has come to the conclusion that
+the wider are the older and the smaller the last formed. The rude
+elevations about these pits&mdash;some of which rise to the height of ten
+thousand feet or more&mdash;constitute the principal topographic reliefs of
+the lunar surface. Besides the pits above mentioned, there are
+numerous fractures in the surface of the plains and ringlike ridges;
+on the most of these the walls have separated, forming trenches not
+unlike what we find in the case of some terrestrial breaks such as
+have been noted about volcanoes and elsewhere. It may be that the
+so-called canals of Mars are of the same nature.</p>
+
+<div class="figright" style="width: 320px;">
+<img src="images/f23.jpg" width="320" height="309" alt="Fig. 23.&mdash;Lunar mountains near the Gulf of Iris." title="" />
+<span class="figcaption">Fig. 23.&mdash;Lunar mountains near the Gulf of Iris.</span>
+</div>
+
+<p>The most curious feature on the moon's surface are the bands of
+lighter colour, which, radiating from certain of the volcanolike
+pits&mdash;those of lesser size and probably of latest origin&mdash;extend in
+some cases for five hundred miles or more across the surface. These
+light bands have never been adequately explained. It seems most likely
+that they are stains along the sides of cracks, such as are sometimes
+observed about volcanoes.</p>
+
+<p>The eminent peculiarity of the moon is that it is destitute of any
+kind of gaseous or aqueous envelope. That there is no distinct
+atmosphere is clearly shown by the <span class='pagenum'><a name="Page_398" id="Page_398">[Pg 398]</a></span>perfectly sharp and sudden way in
+which the light of a star disappears when it goes behind the moon and
+the clear lines of the edge of the satellite in a solar eclipse. The
+same evidence shows that there is no vapour of water; moreover, a
+careful search which the writer has made shows that the surface has
+none of those continuous down grades which mark the work of water
+flowing over the land. Nearly all of the surface consists of shallow
+or deep pits, such as could not have been formed by water action. We
+therefore have not only to conclude that the moon is waterless, but
+that it has been in this condition ever since the part that is turned
+toward us was shaped.</p>
+
+<p>As the moon, except for the slight movement termed its "libration,"
+always turns the same face to us, so that we see in all only about
+four sevenths of its surface, it has naturally been conjectured that
+the unseen side, which is probably some miles lower than that turned
+toward us, might have a different character from that which we behold.
+There are reasons why this is improbable. In the first place, we see
+on the extreme border of the moon, when the libration turns one side
+the farthest around toward the earth, the edge of a number of the
+great walled pits such as are so plenty on the visible area; it is
+fair to assume that these rings are completed in the invisible realm.
+On this basis we can partly map about a third of the hidden side.
+Furthermore, there are certain bands of light which, though appearing
+on the visible side, evidently converge to some points on the other.
+It is reasonable to suppose that, as all other bands radiate from
+walled pits, these also start from such topographic features. In this
+way certain likenesses of the hidden area to that which is visible is
+established, thus making it probable that the whole surface of the
+satellite has the same character.</p>
+
+<p>Clearly as the greater part of the moon is revealed to us&mdash;so clearly,
+indeed, that it is possible to map any elevation of its surface that
+attains the height of five hundred feet&mdash;the interpretation of its
+features in the light <span class='pagenum'><a name="Page_399" id="Page_399">[Pg 399]</a></span>of geology is a matter of very great
+difficulty. The main points seem to be tolerably clear; they are as
+follows: The surface of the moon as we see it is that which was formed
+when that body, passing from the state of fluidity from heat, formed a
+solid crust. The pits which we observe on its surface are the
+depressions which were formed as the mass gradually ceased to boil.
+The later formed of these openings are the smaller, as would be the
+case in such a slowing down of a boiling process.</p>
+
+<p>As the diameter of the moon is only about one fourth of that of the
+earth, its bulk is only about one sixteenth of that of its planet;
+consequently, it must have cooled to the point of solidification ages
+before the larger sphere attained that state. It is probable that the
+same changeless face that we see looked down for millions of years on
+an earth which was still a seething, fiery mass. In a word, all that
+vast history which is traceable in the rocks beneath our feet&mdash;which
+is in progress in the seas and lands and is to endure for an
+inconceivable time to come&mdash;has been denied our satellite, for the
+reason that it had no air with which to entrap the solar heat and no
+water to apply the solar energy to evolutionary processes. The heat
+which comes upon the moon as large a share for each equal area as it
+comes upon the earth flies at once away from the airless surface, at
+most giving it a temporary warmth, but instituting no geological work
+unless it be a little movement from the expansion and contraction of
+the rocks. During the ages in which the moon has remained thus
+lifeless the earth, owing to its air and water, has applied a vast
+amount of solar energy to geological work in the development and
+redevelopment of its geological features and to the processes of
+organic life. We thus see the fundamental importance of the volatile
+envelopes of our sphere, how absolutely they have determined its
+history.</p>
+
+<p>It would be interesting to consider the causes which led to the
+absence of air and water on the moon, but this <span class='pagenum'><a name="Page_400" id="Page_400">[Pg 400]</a></span>matter is one of the
+most debatable of all that relates to that sphere; we shall therefore
+have to content ourselves with the above brief statements as to the
+vast and far-acting effects which have arisen from the non-existence
+of those envelopes on our nearest neighbour of the heavens.</p>
+
+
+<h2 class="subtitle smcap">Methods in studying Geology.</h2>
+
+<p>So far as possible the preceding pages, by the method adopted in the
+presentation of facts, will serve to show the student the ways in
+which he may best undertake to trace the order of events exhibited in
+the phenomena of the earth. Following the plan pursued, we shall now
+consider certain special points which need to be noted by those who
+would adopt the methods of the geologist.</p>
+
+<p>At the outset of his studies it may be well for the inquirer to note
+the fact that familiarity with the world about him leads the man in
+all cases to a certain neglect and contempt of all the familiar
+presentations of Nature. We inevitably forget that those points of
+light in the firmament are vast suns, and we overlook the fact that
+the soil beneath our feet is not mere dirt, but a marvellous
+structure, more complicated in its processes than the chemist's
+laboratory, from which the sustenance of our own and all other lives
+is drawn. We feel our own bodies as dear but commonplace possessions,
+though we should understand them as inheritances from the
+inconceivable past, which have come to us through tens of thousands of
+different species and hundreds of millions of individual ancestors. We
+must overlook these things in our common life. If we could take them
+into account, each soul would carry the universe as an intellectual
+burden.</p>
+
+<p>It is, however, well from time to time to contemplate the truth, and
+to force ourselves to see that all this apparently simple and ordinary
+medley of the world about us is a part of a vast procession of events,
+coming forth from the darkness of the past and moving on beyond the
+<span class='pagenum'><a name="Page_401" id="Page_401">[Pg 401]</a></span>light of the present day. Even in his professional work the
+naturalist of necessity falls into the commonplace way of regarding
+the facts with which he deals. If he be an astronomer, he catalogues
+the stars with little more sense of the immensities than the man who
+keeps a shop takes account of his wares. Nevertheless, the real profit
+of all learning is in the largeness of the understanding which it
+develops in man. The periods of growth in knowledge are those in which
+the mind, enriched by its store, enlarges its conception while it
+escapes from commonplace ways of thought. With this brief mention of
+what is by far the most important principle of guidance which the
+student can follow, we will turn to the questions of method that the
+student need follow in his ordinary work.</p>
+
+<p>With almost all students a difficulty is encountered which hinders
+them in acquiring any large views as to the world about them. This is
+due to the fact that they can not make and retain in memory clear
+pictures of the things they see. They remember words rather than
+things&mdash;in fact, the training in language, which is so large a part of
+an education, tends ever to diminish the element of visual memory. The
+first task of the student who would become a naturalist is to take his
+knowledge from the thing, and to remember it by the mental picture of
+the thing. In all education in Nature, whether the student is guided
+by his own understanding or that of the teacher, a first and very
+continuous aim should be to enforce the habit of recalling very
+distinct images of all objects which it is desired to remember. To
+this end the student should practise himself by looking intently upon
+a landscape or any other object; then, turning away, he should try to
+recall what he has beheld. After a moment the impression by the sight
+should be repeated, and the study of the memory renewed. The writer
+knows by his own experience that even in middle-aged people, where it
+is hard to breed new habits, such deliberate training can greatly
+increase the capacity of the memory for taking in and repro<span class='pagenum'><a name="Page_402" id="Page_402">[Pg 402]</a></span>ducing
+images which are deemed of importance. Practice of this kind should
+form a part of every naturalist's daily routine. After a certain time,
+it need not be consciously done. The movements of thought and action
+will, indeed, become as automatic as those which the trained fencer
+makes with his foil.</p>
+
+<p>Along with the habit of visualizing memories, and of storing them
+without the use of words, the student should undertake to enlarge his
+powers of conceiving spaces and directions as they exist in the field
+about him. Among savages and animals below the grade of man, this
+understanding of spacial relations is very clear and strong. It
+enables the primitive man to find his way through the trackless
+forest, and the carrier pigeon to recover his mate and dwelling place
+from the distance of hundreds of miles away. In civilized men,
+however, the habit of the home and street and the disuse of the
+ancient freedom has dulled, and in some instances almost destroyed,
+all sense of this shape of the external world. The best training to
+recover this precious capacity will now be set forth.</p>
+
+<p>The student should begin by drawing a map on a true scale, however
+roughly the work may be done, of those features of the earth about him
+with which he is necessarily most familiar. The task may well be begun
+with his own dwelling or his schoolroom. Thence it may be extended so
+as to include the plan of the neighbouring streets or fields. At
+first, only directions and distances should be platted. After a time
+to these indications should be added on the map lines indicating in a
+general way contours or the lines formed by horizontal planes
+intersecting the area subject to delineation. After attaining certain
+rude skill in such work, the student may advantageously make
+excursions to districts which he can see only in a hurried way. As he
+goes, he should endeavour to note on a sketch map the positions of the
+hills and streams and the directions of the roads. A year of holiday
+practice in such work will, if the tasks occupy somewhere <span class='pagenum'><a name="Page_403" id="Page_403">[Pg 403]</a></span>about a
+hundred hours of his time, serve greatly to extend or reawaken what
+may be called the topographic sense, and enable him to place in terms
+of space the observations of Nature which he may make.</p>
+
+<p>In his more detailed work the student should select some particular
+field for his inquiry. If he be specially interested in geologic
+phenomena, he will best begin by noting two classes of facts&mdash;those
+exhibited in the rocks as they actually appear in the state of repose
+as shown in the outcrops of his neighbourhood, and those shown in the
+active manifestations of geological work, the decay of the rocks and
+the transportation of their waste, or, if the conditions favour, the
+complicated phenomena of the seashores.</p>
+
+<p>As soon as the student begins to observe, he should begin to make a
+record of his studies. To the novice in any science written, and
+particularly sketched, notes are of the utmost importance. These,
+whether in words or in drawings, should be made in face of the facts;
+they should, indeed, be set down at the close of an observation,
+though not until the observer feels that the object he is studying has
+yielded to him all which it can at that time give. It is well to
+remark that where a record is made at the outset of a study the
+student is apt to feel that he is in some way pledged to shape all he
+may see to fit that which he has first written. In his early
+experience as a teacher, the writer was accustomed to have students
+compare their work of observation and delineation with that done by
+trained men on the same ground. It now seems to him best for the
+beginner at first to avoid all such reference of his own work to that
+of others. So great is the need of developing independent motive that
+it is better at the outset to make many blunders than to secure
+accuracy by trust in a leader. The skilful teacher can give fitting
+words of caution which may help a student to find the true way, but
+any reference of his undertakings to masterpieces is sure to breed a
+servile habit. Therefore such <span class='pagenum'><a name="Page_404" id="Page_404">[Pg 404]</a></span>comparisons are fitting only after the
+habit of free work has been well formed. The student who can afford
+the help of a master, or, better, the assistance of many, such as some
+of our universities offer, should by all means avail himself of this
+resource. More than any other science, geology, because of the
+complexity of the considerations with which it has to deal, depends
+upon methods of labour which are to a great extent traditional, and
+which can not, indeed, be well transmitted except in the personal way.
+In the distinctly limited sciences, such as mathematics, physics, or
+even those which deal with organic bodies, the methods of work can be
+so far set forth in printed directions that the student may to a great
+extent acquire sound ways of work without the help of a teacher.</p>
+
+<p>Although there is a vast and important literature concerning geology,
+the greater part of it is of a very special nature, and will convey to
+the beginner no substantial information whatever. It is not until he
+has become familiar with the field with which he is enabled to deal in
+the actual way that he can transfer experience thus acquired to other
+grounds. Therefore beyond the pleasing views which he may obtain by
+reading certain general works on the science, the student should at
+the outset of his inquiry limit his work as far as possible to his
+field of practice, using a good text-book, such as Dana's Manual of
+Geology, as a source of suggestions as to the problems which his field
+may afford.</p>
+
+<p>The main aim of the student in this, as in other branches of inquiry,
+is to gain practice in following out the natural series of actions. To
+the primitive man the phenomenal world presents itself as a mere
+phantasmagoria, a vast show in which the things seen are only related
+to each other by the fact that they come at once into view. The end of
+science is to divine the order of this host, and the ways in which it
+is marshalled in its onward movement and the ends to which its march
+appears to be directed. So far as the student observes well, and thus
+gains a clear <span class='pagenum'><a name="Page_405" id="Page_405">[Pg 405]</a></span>notion of separated facts, he is in a fair way to
+gather the data of knowledge which may be useful; but the real value
+of these discernments is not gained until the observations go
+together, so as to make something with a perspective. Until the store
+of separate facts is thus arranged, it is merely crude material for
+thought; it is not in the true meaning science, any more than a store
+of stone and mortar is architecture. When the student has developed an
+appetite for the appreciation of order and sources of energy in
+phenomena, he has passed his novitiate, and becomes one of that happy
+body of men who not only see what is perceived by the mass of their
+fellows, but are enabled to look through those chains of action which,
+when comprehended, serve to rationalize and ennoble all that the
+senses of man, aided by the instruments which he has devised, tell us
+concerning the visible world.</p>
+
+
+
+
+<p><span class='pagenum'><a name="Page_406" id="Page_406">[Pg 406]</a></span></p><hr style="width: 65%;" />
+<h1>INDEX.</h1>
+<p>
+<span style="margin-left: 2em;">&AElig;tna, Mount, <a href="#Page_381">381</a>.</span><br />
+
+<span style="margin-left: 2em;">Agriculture,</span><br />
+<span style="margin-left: 3em;">American, <a href="#Page_346">346</a>;</span><br />
+<span style="margin-left: 3em;">in England, winning swamp lands for, <a href="#Page_335">335</a>;</span><br />
+<span style="margin-left: 3em;">recent developments of, <a href="#Page_345">345</a>.</span><br />
+
+<span style="margin-left: 2em;">Alaska, changes on the coast of, <a href="#Page_96">96</a>.</span><br />
+
+<span style="margin-left: 2em;">Ants taking food underground, <a href="#Page_319">319</a>;</span><br />
+<span style="margin-left: 3em;">work of the, on the soil, <a href="#Page_318">318</a>.</span><br />
+
+<span style="margin-left: 2em;">Apsides, revolution of the, <a href="#Page_61">61</a>, <a href="#Page_62">62</a>.</span><br />
+
+<span style="margin-left: 2em;">Arabians, chemical experiments of the, <a href="#Page_13">13</a>.</span><br />
+
+<span style="margin-left: 2em;">Arches, natural, in cavern districts, <a href="#Page_258">258</a>.</span><br />
+
+<span style="margin-left: 2em;">Artesian wells, <a href="#Page_258">258</a>, <a href="#Page_259">259</a>.</span><br />
+
+<span style="margin-left: 2em;">Arts, advance of Italian fine, <a href="#Page_19">19</a>.</span><br />
+
+<span style="margin-left: 2em;">Asteroids, <a href="#Page_53">53</a>;</span><br />
+<span style="margin-left: 3em;">motions of, about their centres and about the sun, <a href="#Page_53">53</a>.</span><br />
+
+<span style="margin-left: 2em;">Astronomers, the solar system and the early, <a href="#Page_79">79</a>.</span><br />
+
+<span style="margin-left: 2em;">Astronomy, <a href="#Page_31">31</a>-<a href="#Page_80">80</a>;</span><br />
+<span style="margin-left: 3em;">growth of, since the time of Galileo, <a href="#Page_33">33</a>, <a href="#Page_34">34</a>;</span><br />
+<span style="margin-left: 3em;">the first science, <a href="#Page_10">10</a>.</span><br />
+
+<span style="margin-left: 2em;">Atmosphere, 97-<a href="#Page_206">206</a>;</span><br />
+<span style="margin-left: 3em;">along the tropical belt, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">as a medium of communication between different regions, <a href="#Page_99">99</a>;</span><br />
+<span style="margin-left: 3em;">deprived of water, containing little heat, <a href="#Page_105">105</a>;</span><br />
+<span style="margin-left: 3em;">beginning of the science of the, <a href="#Page_117">117</a>;</span><br />
+<span style="margin-left: 3em;">counter-trade movements of the, <a href="#Page_105">105</a>;</span><br />
+<span style="margin-left: 3em;">envelope of the earth, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">expansion of, in a hollow wall during the passage of a storm, <a href="#Page_114">114</a>;</span><br />
+<span style="margin-left: 3em;">heat-carrying power of the, <a href="#Page_105">105</a>;</span><br />
+<span style="margin-left: 3em;">heights to which it extends, <a href="#Page_99">99</a>;</span><br />
+<span style="margin-left: 3em;">in water, <a href="#Page_99">99</a>;</span><br />
+<span style="margin-left: 3em;">movements no direct influence on the surface of the earth, <a href="#Page_122">122</a>;</span><br />
+<span style="margin-left: 3em;">movements of the, qualified by the condition which it encounters, <a href="#Page_118">118</a>;</span><br />
+<span style="margin-left: 3em;">of mountains, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">of the seashore, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">of the earth, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">of the sun, <a href="#Page_73">73</a>;</span><br />
+<span style="margin-left: 3em;">snow as an evidence of, <a href="#Page_65">65</a>;</span><br />
+<span style="margin-left: 3em;">supplying needs of underground creatures, <a href="#Page_331">331</a>;</span><br />
+<span style="margin-left: 3em;">uprushes of, <a href="#Page_101">101</a>, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">upward strain of the, next the earth, <a href="#Page_107">107</a>;</span><br />
+<span style="margin-left: 3em;">weight and motion of the, <a href="#Page_120">120</a>, <a href="#Page_121">121</a>.</span><br />
+
+<span style="margin-left: 2em;">Atmospheric circulation of the soil, <a href="#Page_330">330</a>, <a href="#Page_331">331</a>;</span><br />
+<span style="margin-left: 3em;">envelopes, <a href="#Page_97">97</a>.</span><br />
+
+<span style="margin-left: 2em;">Aurora borealis, <a href="#Page_168">168</a>.</span><br />
+
+<span style="margin-left: 2em;">Avalanches, <a href="#Page_210">210</a>-<a href="#Page_213">213</a>;</span><br />
+<span style="margin-left: 3em;">dreaded, in the Alpine regions, <a href="#Page_212">212</a>;</span><br />
+<span style="margin-left: 3em;">great, in the Swiss Oberland, <a href="#Page_211">211</a>, <a href="#Page_212">212</a>;</span><br />
+<span style="margin-left: 3em;">rocky, <a href="#Page_175">175</a>-<a href="#Page_177">177</a>.</span><br />
+
+<span style="margin-left: 2em;">Axis,</span><br />
+<span style="margin-left: 3em;">imaginary changes in the earth's, <a href="#Page_59">59</a>;</span><br />
+<span style="margin-left: 3em;">of the earth's rotation, <a href="#Page_58">58</a>;</span><br />
+<span style="margin-left: 3em;">polar, inclined position of, <a href="#Page_58">58</a>;</span><br />
+<span style="margin-left: 3em;">polar, nodding movement of the axes, <a href="#Page_54">54</a>;</span><br />
+<span style="margin-left: 3em;">rotations of the planetary spheres on their axes, <a href="#Page_56">56</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Barometer, causes of changes in the, <a href="#Page_117">117</a>, <a href="#Page_118">118</a>.</span><br />
+
+<span style="margin-left: 2em;">Basalts, <a href="#Page_309">309</a>.</span><br />
+
+<span style="margin-left: 2em;">Beaches, <a href="#Page_93">93</a>, <a href="#Page_142">142</a>, <a href="#Page_144">144</a>;</span><br />
+<span style="margin-left: 3em;">boulder, <a href="#Page_142">142</a>, <a href="#Page_143">143</a>;</span><br />
+<span style="margin-left: 3em;">pebbly, <a href="#Page_142">142</a>;</span><br />
+<span style="margin-left: 3em;">sand, <a href="#Page_144">144</a>.</span><br />
+
+<span style="margin-left: 2em;">Beetles, work of, on the soil, <a href="#Page_318">318</a>, <a href="#Page_319">319</a>.</span><br />
+
+<span style="margin-left: 2em;">Belief of the early astronomers about the solar system, <a href="#Page_79">79</a>.</span><br />
+
+<span style="margin-left: 2em;"><i>Bergschrund</i>, the, <a href="#Page_214">214</a>.</span><br />
+
+<span class='pagenum'><a name="Page_408" id="Page_408">[Pg 408]</a></span>
+<span style="margin-left: 2em;">Birds and mammals contributing to the fertility of the soil, <a href="#Page_319">319</a>.</span><br />
+
+<span style="margin-left: 2em;">"Blanketing," <a href="#Page_269">269</a>.</span><br />
+
+<span style="margin-left: 2em;">Bogs,</span><br />
+<span style="margin-left: 3em;">climbing, <a href="#Page_331">331</a>-<a href="#Page_334">334</a>;</span><br />
+<span style="margin-left: 3em;">lake, <a href="#Page_331">331</a>-<a href="#Page_333">333</a>;</span><br />
+<span style="margin-left: 3em;">peat, <a href="#Page_334">334</a>, <a href="#Page_335">335</a>;</span><br />
+<span style="margin-left: 3em;">quaking, <a href="#Page_334">334</a>.</span><br />
+
+<span style="margin-left: 2em;">Botany, rapid advance in, <a href="#Page_14">14</a>, <a href="#Page_15">15</a>.</span><br />
+
+<span style="margin-left: 2em;">Boulders, <a href="#Page_217">217</a>, <a href="#Page_220">220</a>.</span><br />
+
+<span style="margin-left: 2em;">Breakers, <a href="#Page_135">135</a>, <a href="#Page_137">137</a>, <a href="#Page_139">139</a>.</span><br />
+
+<span style="margin-left: 2em;">Bridges, natural, <a href="#Page_257">257</a>, <a href="#Page_258">258</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Canals of Mars, <a href="#Page_67">67</a>.</span><br />
+
+<span style="margin-left: 2em;">Ca&ntilde;on, newly formed river cutting a, <a href="#Page_195">195</a>.</span><br />
+
+<span style="margin-left: 2em;">Cataracts, <a href="#Page_193">193</a>.</span><br />
+
+<span style="margin-left: 2em;">Caves, <a href="#Page_253">253</a>-<a href="#Page_258">258</a>, <a href="#Page_261">261</a>;</span><br />
+<span style="margin-left: 3em;">architecture of, <a href="#Page_255">255</a>-<a href="#Page_258">258</a>;</span><br />
+<span style="margin-left: 3em;">hot-water, <a href="#Page_261">261</a>;</span><br />
+<span style="margin-left: 3em;">mammoth cave, <a href="#Page_258">258</a>;</span><br />
+<span style="margin-left: 3em;">stalactites and stalagmites on the roof and floor of, <a href="#Page_257">257</a>.</span><br />
+
+<span style="margin-left: 2em;">Chasms, <a href="#Page_140">140</a>, <a href="#Page_141">141</a>.</span><br />
+
+<span style="margin-left: 2em;">Chemistry, <a href="#Page_6">6</a>, <a href="#Page_12">12</a>, <a href="#Page_14">14</a>;</span><br />
+<span style="margin-left: 3em;">advance of, <a href="#Page_12">12</a>;</span><br />
+<span style="margin-left: 3em;">modern, evolving from the studies of alchemists, <a href="#Page_13">13</a>, <a href="#Page_14">14</a>.</span><br />
+
+<span style="margin-left: 2em;">Chromosphere, <a href="#Page_73">73</a>.</span><br />
+
+<span style="margin-left: 2em;">Civilization of the Icelanders, <a href="#Page_384">384</a>.</span><br />
+
+<span style="margin-left: 2em;">Cliffs, sea-beaten, <a href="#Page_132">132</a>, <a href="#Page_141">141</a>, <a href="#Page_142">142</a>.</span><br />
+
+<span style="margin-left: 2em;">Climate,</span><br />
+<span style="margin-left: 3em;">changes of, due to modifications of the ocean streams, <a href="#Page_153">153</a>;</span><br />
+<span style="margin-left: 3em;">effect of the ocean on the, <a href="#Page_147">147</a>;</span><br />
+<span style="margin-left: 3em;">of the Gulf Stream, <a href="#Page_149">149</a>, <a href="#Page_150">150</a>.</span><br />
+
+<span style="margin-left: 2em;">Clouds, <a href="#Page_159">159</a>;</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_162">162</a>, <a href="#Page_163">163</a>;</span><br />
+<span style="margin-left: 3em;">shape of, <a href="#Page_163">163</a>;</span><br />
+<span style="margin-left: 3em;">water of, usually frozen, <a href="#Page_207">207</a>;</span><br />
+<span style="margin-left: 3em;">cloud-making, laws of, <a href="#Page_161">161</a>, <a href="#Page_162">162</a>.</span><br />
+
+<span style="margin-left: 2em;">Coast,</span><br />
+<span style="margin-left: 3em;">changes on the Scandinavian, <a href="#Page_96">96</a>;</span><br />
+<span style="margin-left: 3em;">line, effect of tide on the, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">of Greenland, <a href="#Page_226">226</a>;</span><br />
+<span style="margin-left: 3em;">of New Jersey sinking, <a href="#Page_95">95</a>;</span><br />
+<span style="margin-left: 3em;">marine, changes in, <a href="#Page_95">95</a>.</span><br />
+
+<span style="margin-left: 2em;">Cold in Siberia, <a href="#Page_243">243</a>.</span><br />
+
+<span style="margin-left: 2em;">Comets, <a href="#Page_47">47</a>, <a href="#Page_50">50</a>;</span><br />
+<span style="margin-left: 3em;">collisions of, <a href="#Page_50">50</a>;</span><br />
+<span style="margin-left: 3em;">kinship of meteorites and, <a href="#Page_48">48</a>;</span><br />
+<span style="margin-left: 3em;">omens of calamity to the ancients, <a href="#Page_50">50</a>;</span><br />
+<span style="margin-left: 3em;">the great, of 1811, <a href="#Page_49">49</a>, <a href="#Page_50">50</a>.</span><br />
+
+<span style="margin-left: 2em;">Cones. See under <span class="smcap">Volcanoes</span>.</span><br />
+
+<span style="margin-left: 2em;">Conflict between religion and science, <a href="#Page_20">20</a>, <a href="#Page_22">22</a>;</span><br />
+<span style="margin-left: 3em;">between the Protestant countries and the followers of science, <a href="#Page_20">20</a>.</span><br />
+
+<span style="margin-left: 2em;">Continental shelves, <a href="#Page_125">125</a>.</span><br />
+
+<span style="margin-left: 2em;">Continents and oceans, <a href="#Page_83">83</a>;</span><br />
+<span style="margin-left: 3em;">changes in position of, <a href="#Page_91">91</a>;</span><br />
+<span style="margin-left: 3em;">cyclones of the, <a href="#Page_111">111</a>;</span><br />
+<span style="margin-left: 3em;">forms of, <a href="#Page_90">90</a>;</span><br />
+<span style="margin-left: 3em;">proofs that they have endured for many years, <a href="#Page_92">92</a>;</span><br />
+<span style="margin-left: 3em;">shape of, <a href="#Page_84">84</a>, <a href="#Page_96">96</a>.</span><br />
+
+<span style="margin-left: 2em;">Coral reefs, <a href="#Page_153">153</a>, <a href="#Page_353">353</a>.</span><br />
+
+<span style="margin-left: 2em;">Corona, realm of the, <a href="#Page_73">73</a>.</span><br />
+
+<span style="margin-left: 2em;">Craters. See under <span class="smcap">Volcanoes</span>.</span><br />
+
+<span style="margin-left: 2em;">Crevasse, a barrier to the explorer, <a href="#Page_218">218</a>.</span><br />
+
+<span style="margin-left: 2em;">Crevice water, <a href="#Page_250">250</a>.</span><br />
+
+<span style="margin-left: 2em;">Curds, <a href="#Page_214">214</a>.</span><br />
+
+<span style="margin-left: 2em;">Currents,</span><br />
+<span style="margin-left: 3em;">coral reefs in Florida affecting the velocity of, <a href="#Page_153">153</a>;</span><br />
+<span style="margin-left: 3em;">equatorial, <a href="#Page_150">150</a>;</span><br />
+<span style="margin-left: 3em;">of the Gulf Stream, <a href="#Page_147">147</a>-<a href="#Page_149">149</a>;</span><br />
+<span style="margin-left: 3em;">hot and cold, of the sea, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">ocean, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">oceanic action of trade winds on, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">effect on migration of, <a href="#Page_157">157</a>;</span><br />
+<span style="margin-left: 3em;">icebergs indicating, <a href="#Page_243">243</a>;</span><br />
+<span style="margin-left: 3em;">surface, history of, <a href="#Page_172">172</a>;</span><br />
+<span style="margin-left: 3em;">uprushing, near the equator, <a href="#Page_106">106</a>.</span><br />
+
+<span style="margin-left: 2em;">Cyclones, <a href="#Page_111">111</a>;</span><br />
+<span style="margin-left: 3em;">cause of, <a href="#Page_111">111</a>;</span><br />
+<span style="margin-left: 3em;">of North America, <a href="#Page_111">111</a>;</span><br />
+<span style="margin-left: 3em;">secondary storms of, <a href="#Page_112">112</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Deltas, <a href="#Page_173">173</a>, <a href="#Page_187">187</a>.</span><br />
+
+<span style="margin-left: 2em;">Deposits, vein, <a href="#Page_260">260</a>, <a href="#Page_261">261</a>.</span><br />
+
+<span style="margin-left: 2em;">Deserts, interior, <a href="#Page_158">158</a>.</span><br />
+
+<span style="margin-left: 2em;">Dew, <a href="#Page_159">159</a>, <a href="#Page_160">160</a>;</span><br />
+<span style="margin-left: 3em;">a concomitant of cloudless skies, <a href="#Page_160">160</a>,</span><br />
+<span style="margin-left: 4em;">and vegetation, <a href="#Page_160">160</a>;</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_159">159</a>-<a href="#Page_161">161</a>.</span><br />
+
+<span style="margin-left: 2em;">Diablerets, <a href="#Page_174">174</a>.</span><br />
+
+<span style="margin-left: 2em;">Diagram of a vein, <a href="#Page_260">260</a>;</span><br />
+<span style="margin-left: 3em;">showing development of swamp, <a href="#Page_335">335</a>;</span><br />
+<span style="margin-left: 3em;">how a portion of the earth's surface may be sunk by faulting, <a href="#Page_374">374</a>;</span><br />
+<span style="margin-left: 3em;">growth of mangroves, <a href="#Page_340">340</a>;</span><br />
+<span style="margin-left: 3em;">the effect of the position of the fulcrum point in the movement of the land masses, <a href="#Page_94">94</a>.</span><br />
+
+<span style="margin-left: 2em;">Diameter of our sphere at the equator, <a href="#Page_62">62</a>;</span><br />
+<span style="margin-left: 3.5em;">of the earth, <a href="#Page_82">82</a>.</span><br />
+
+<span style="margin-left: 2em;">Dikes, <a href="#Page_192">192</a>, <a href="#Page_293">293</a>; <a href="#Page_305">305</a>-<a href="#Page_310">310</a>;</span><br />
+<span style="margin-left: 3em;">abounding in volcanic cones, <a href="#Page_305">305</a>;</span><br />
+<span style="margin-left: 3em;">cutting through coal, <a href="#Page_306">306</a>;</span><br />
+<span class='pagenum'><a name="Page_409" id="Page_409">[Pg 409]</a></span>
+<span style="margin-left: 3em;">driven upward, <a href="#Page_307">307</a>;</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_305">305</a>, <a href="#Page_310">310</a>;</span><br />
+<span style="margin-left: 3em;">material of, <a href="#Page_307">307</a>, <a href="#Page_308">308</a>;</span><br />
+<span style="margin-left: 3em;">representing movements of softened rock, <a href="#Page_309">309</a>;</span><br />
+<span style="margin-left: 3em;">their relation to volcanic cones, <a href="#Page_307">307</a>;</span><br />
+<span style="margin-left: 3em;">variations of the materials of, <a href="#Page_307">307</a>, <a href="#Page_308">308</a>;</span><br />
+<span style="margin-left: 3em;">waterfalls produced by, <a href="#Page_192">192</a>;</span><br />
+<span style="margin-left: 3em;">zone of, <a href="#Page_306">306</a>.</span><br />
+
+<span style="margin-left: 2em;">Dismal Swamp, <a href="#Page_95">95</a>, <a href="#Page_333">333</a>.</span><br />
+
+<span style="margin-left: 2em;">Distances,</span><br />
+<span style="margin-left: 3em;">general idea of, <a href="#Page_27">27</a>;</span><br />
+<span style="margin-left: 3em;">good way to study, <a href="#Page_27">27</a>, <a href="#Page_28">28</a>;</span><br />
+<span style="margin-left: 3em;">training soldiers to measure, <a href="#Page_28">28</a>.</span><br />
+
+<span style="margin-left: 2em;">Doldrums, <a href="#Page_104">104</a>, <a href="#Page_109">109</a>;</span><br />
+<span style="margin-left: 3em;">doldrum of the equator, <a href="#Page_109">109</a>;</span><br />
+<span style="margin-left: 3em;">of the hurricane, <a href="#Page_109">109</a>.</span><br />
+
+<span style="margin-left: 2em;">Drainage, imperfect, of a country affected by glaciers, <a href="#Page_242">242</a>.</span><br />
+
+<span style="margin-left: 2em;">Dunes, <a href="#Page_123">123</a>, <a href="#Page_124">124</a>, <a href="#Page_325">325</a>, <a href="#Page_326">326</a>, <a href="#Page_387">387</a>;</span><br />
+<span style="margin-left: 3em;">moulded, <a href="#Page_387">387</a>.</span><br />
+
+<span style="margin-left: 2em;">Duration of geological time, <a href="#Page_389">389</a>.</span><br />
+
+<span style="margin-left: 2em;">Dust accumulations from wind, in China, <a href="#Page_122">122</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Earth,</span><br />
+<span style="margin-left: 3em;">a flattened sphere, <a href="#Page_82">82</a>;</span><br />
+<span style="margin-left: 3em;">air envelope of the, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">amount of heat falling from the sun on the, <a href="#Page_41">41</a>;</span><br />
+<span style="margin-left: 3em;">antiquity of the, <a href="#Page_391">391</a>;</span><br />
+<span style="margin-left: 3em;">atmosphere of the, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">attracting power of the, <a href="#Page_127">127</a>;</span><br />
+<span style="margin-left: 3em;">axis of the rotation of the, <a href="#Page_58">58</a>;</span><br />
+<span style="margin-left: 3em;">composition of the atmosphere of the, <a href="#Page_98">98</a>;</span><br />
+<span style="margin-left: 3em;">crust of the, affected by weight, <a href="#Page_93">93</a>;</span><br />
+<span style="margin-left: 3em;">deviation of the path of the, varied, <a href="#Page_61">61</a>;</span><br />
+<span style="margin-left: 3em;">diameter of the, <a href="#Page_82">82</a>;</span><br />
+<span style="margin-left: 4em;">of the, affected by loss of heat, <a href="#Page_131">131</a>;</span><br />
+<span style="margin-left: 3em;">difference in altitude of the surface of the, <a href="#Page_83">83</a>;</span><br />
+<span style="margin-left: 3em;">discovery that it was globular, <a href="#Page_31">31</a>, <a href="#Page_32">32</a>;</span><br />
+<span style="margin-left: 3em;">effect of imaginary changes in the relations of sun and, <a href="#Page_59">59</a>;</span><br />
+<span style="margin-left: 3em;">effect of the interior heat of the, <a href="#Page_309">309</a>, <a href="#Page_310">310</a>;</span><br />
+<span style="margin-left: 3em;">effect of the sun on the, <a href="#Page_60">60</a>, <a href="#Page_61">61</a>;</span><br />
+<span style="margin-left: 3em;">formerly in a fluid state, <a href="#Page_82">82</a>;</span><br />
+<span style="margin-left: 3em;">imaginary view of the, from the moon, <a href="#Page_81">81</a>;</span><br />
+<span style="margin-left: 3em;">important feature of the surface of the, <a href="#Page_83">83</a>;</span><br />
+<span style="margin-left: 3em;">jarring caused by faults, <a href="#Page_367">367</a>;</span><br />
+<span style="margin-left: 3em;">surface of the, determined by heat and light from the sun, <a href="#Page_57">57</a>;</span><br />
+<span style="margin-left: 3em;">most important feature of the surface of the, <a href="#Page_83">83</a>;</span><br />
+<span style="margin-left: 3em;">motion of the, affecting the direction of trade winds, <a href="#Page_103">103</a>;</span><br />
+<span style="margin-left: 3em;">movements, <a href="#Page_366">366</a>;</span><br />
+<span style="margin-left: 3em;">natural architecture of the, <a href="#Page_377">377</a>;</span><br />
+<span style="margin-left: 3em;">no part of the, exempt from movement, <a href="#Page_384">384</a>;</span><br />
+<span style="margin-left: 3em;">parting of the moon and, <a href="#Page_396">396</a>;</span><br />
+<span style="margin-left: 3em;">path of the, around the sun, <a href="#Page_55">55</a>, <a href="#Page_56">56</a>, <a href="#Page_59">59</a>, <a href="#Page_60">60</a>;</span><br />
+<span style="margin-left: 3em;">revolving from east to west, <a href="#Page_103">103</a>;</span><br />
+<span style="margin-left: 3em;">shrinking of the, from daily escape of heat, <a href="#Page_89">89</a>;</span><br />
+<span style="margin-left: 3em;">soil-covering of the, <a href="#Page_343">343</a>;</span><br />
+<span style="margin-left: 3em;">study of the, <a href="#Page_81">81</a>-<a href="#Page_96">96</a>;</span><br />
+<span style="margin-left: 3em;">swaying, <a href="#Page_385">385</a>;</span><br />
+<span style="margin-left: 3em;">tensions, problem of, <a href="#Page_371">371</a>;</span><br />
+<span style="margin-left: 3em;">tremors, caused by chemical changes in the rocks, <a href="#Page_385">385</a>;</span><br />
+<span style="margin-left: 3em;">tropical belt of the, <a href="#Page_74">74</a>;</span><br />
+<span style="margin-left: 3em;">viewed from the surface of the moon, <a href="#Page_311">311</a>, <a href="#Page_312">312</a>;</span><br />
+<span style="margin-left: 3em;">water store of the, <a href="#Page_125">125</a>.</span><br />
+
+<span style="margin-left: 2em;">Earthquakes, <a href="#Page_277">277</a>, <a href="#Page_278">278</a>, <a href="#Page_280">280</a>, <a href="#Page_356">356</a>, <a href="#Page_358">358</a>, <a href="#Page_370">370</a>-<a href="#Page_384">384</a>, <a href="#Page_388">388</a>-<a href="#Page_390">390</a>;</span><br />
+<span style="margin-left: 3em;">accidents of, <a href="#Page_358">358</a>;</span><br />
+<span style="margin-left: 3em;">action of, <a href="#Page_356">356</a>;</span><br />
+<span style="margin-left: 3em;">agents of degradation, <a href="#Page_383">383</a>, <a href="#Page_384">384</a>;</span><br />
+<span style="margin-left: 3em;">basis of, <a href="#Page_367">367</a>;</span><br />
+<span style="margin-left: 3em;">certain limitations to, <a href="#Page_380">380</a>, <a href="#Page_381">381</a>;</span><br />
+<span style="margin-left: 3em;">Charleston, of 1883, <a href="#Page_374">374</a>, <a href="#Page_375">375</a>;</span><br />
+<span style="margin-left: 3em;">countries, architecture in, <a href="#Page_381">381</a>;</span><br />
+<span style="margin-left: 3em;">echoes, <a href="#Page_369">369</a>, <a href="#Page_370">370</a>;</span><br />
+<span style="margin-left: 3em;">damages of, <a href="#Page_377">377</a>, <a href="#Page_390">390</a>;</span><br />
+<span style="margin-left: 3em;">effect of,</span><br />
+<span style="margin-left: 4em;">on the soil, <a href="#Page_375">375</a>;</span><br />
+<span style="margin-left: 4em;">the surface of the earth, <a href="#Page_371">371</a>;</span><br />
+<span style="margin-left: 3em;">formed by riving of fissures, <a href="#Page_382">382</a>;</span><br />
+<span style="margin-left: 3em;">great, occurring where rocks have been disturbed by mountain-building, <a href="#Page_381">381</a>, <a href="#Page_382">382</a>;</span><br />
+<span style="margin-left: 3em;">Herculaneum and Pompeii destroyed by an, <a href="#Page_277">277</a>, <a href="#Page_280">280</a>;</span><br />
+<span style="margin-left: 3em;">Italian, in 1783, <a href="#Page_371">371</a>, <a href="#Page_372">372</a>;</span><br />
+<span style="margin-left: 3em;">important, not connected with volcanic explosions, <a href="#Page_381">381</a>;</span><br />
+<span style="margin-left: 3em;">Jamaica, in 1692, <a href="#Page_372">372</a>, <a href="#Page_376">376</a>;</span><br />
+<span style="margin-left: 3em;">Lisbon, in 1755, <a href="#Page_368">368</a>, <a href="#Page_369">369</a>, <a href="#Page_373">373</a>, <a href="#Page_374">374</a>, <a href="#Page_381">381</a>;</span><br />
+<span style="margin-left: 3em;">maximum swing of, <a href="#Page_369">369</a>;</span><br />
+<span style="margin-left: 3em;">measuring the liability to, <a href="#Page_386">386</a>, <a href="#Page_387">387</a>;</span><br />
+<span style="margin-left: 3em;">mechanism of, <a href="#Page_370">370</a>, <a href="#Page_371">371</a>;</span><br />
+<span style="margin-left: 3em;">method of the study of, followed by Mr. Charles Mallet, <a href="#Page_382">382</a>, <a href="#Page_383">383</a>;</span><br />
+<span style="margin-left: 3em;">Mississippi, in 1811, <a href="#Page_373">373</a>, <a href="#Page_374">374</a>, <a href="#Page_380">380</a>, <a href="#Page_381">381</a>;</span><br />
+<span style="margin-left: 3em;">movement of the earth during, <a href="#Page_377">377</a>;</span><br />
+<span style="margin-left: 3em;">originating from a fault plane, <a href="#Page_367">367</a>, <a href="#Page_369">369</a>, <a href="#Page_370">370</a>;</span><br />
+<span style="margin-left: 3em;">originating from the seas, <a href="#Page_358">358</a>, <a href="#Page_375">375</a>;</span><br />
+<span style="margin-left: 3em;">oscillation of, <a href="#Page_376">376</a>;</span><br />
+<span class='pagenum'><a name="Page_410" id="Page_410">[Pg 410]</a></span>
+<span style="margin-left: 3em;">poised rocks indicating a long exemption from strong, <a href="#Page_388">388</a>;</span><br />
+<span style="margin-left: 3em;">Riobamba, in 1797, <a href="#Page_375">375</a>;</span><br />
+<span style="margin-left: 3em;">shocks of, and their effect upon people, <a href="#Page_383">383</a>;</span><br />
+<span style="margin-left: 3em;">the direct calamities of Nature, <a href="#Page_386">386</a>;</span><br />
+<span style="margin-left: 3em;">waves of, <a href="#Page_389">389</a>.</span><br />
+
+<span style="margin-left: 2em;">Earthworms, <a href="#Page_317">317</a>-<a href="#Page_319">319</a>;</span><br />
+<span style="margin-left: 3em;">taking food underground, <a href="#Page_319">319</a>.</span><br />
+
+<span style="margin-left: 2em;">Eclipses, record of ancient, <a href="#Page_130">130</a>.</span><br />
+
+<span style="margin-left: 2em;">Electrical action in the formation of rain and snow, <a href="#Page_164">164</a>.</span><br />
+
+<span style="margin-left: 2em;">Elevations of seas and lands, <a href="#Page_83">83</a>.</span><br />
+
+<span style="margin-left: 2em;">Energy indestructible, <a href="#Page_23">23</a>.</span><br />
+
+<span style="margin-left: 2em;">Envelope, lower, of the sun, <a href="#Page_74">74</a>.</span><br />
+
+<span style="margin-left: 2em;">Equator,</span><br />
+<span style="margin-left: 3em;">diameter of our sphere at the, <a href="#Page_62">62</a>;</span><br />
+<span style="margin-left: 3em;">doldrum of the, <a href="#Page_109">109</a>;</span><br />
+<span style="margin-left: 3em;">updraught under the, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">uprushing current near the, <a href="#Page_106">106</a>.</span><br />
+
+<span style="margin-left: 2em;">Equinoxes, precession of the, <a href="#Page_61">61</a>, <a href="#Page_62">62</a>.</span><br />
+
+<span style="margin-left: 2em;"><i>Eskers</i>, <a href="#Page_221">221</a>.</span><br />
+
+<span style="margin-left: 2em;">Expansion of air contained in a hollow wall during the passage of the storm, <a href="#Page_114">114</a>.</span><br />
+
+<span style="margin-left: 2em;">Experiment, illustrating consolidation of disseminated materials of the sun and planets, <a href="#Page_40">40</a>.</span><br />
+
+<span style="margin-left: 2em;">Falls. See <span class="smcap">Waterfalls</span>.</span><br />
+
+<span style="margin-left: 2em;">Fault planes, <a href="#Page_382">382</a>.</span><br />
+
+<span style="margin-left: 2em;">Feldspar, <a href="#Page_324">324</a>.</span><br />
+
+<span style="margin-left: 2em;">Floods, <a href="#Page_180">180</a>, <a href="#Page_197">197</a>;</span><br />
+<span style="margin-left: 3em;">rarity of, in New England, <a href="#Page_121">121</a>;</span><br />
+<span style="margin-left: 3em;">river, frequent east of Rocky Mountains, <a href="#Page_198">198</a>.</span><br />
+
+<span style="margin-left: 2em;">F&ouml;hns, <a href="#Page_121">121</a>.</span><br />
+
+<span style="margin-left: 2em;">Forests, salicified, <a href="#Page_124">124</a>.</span><br />
+
+<span style="margin-left: 2em;">Fossilization, <a href="#Page_354">354</a>-<a href="#Page_356">356</a>.</span><br />
+
+<span style="margin-left: 2em;">Fulcrum point, <a href="#Page_95">95</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Galactic plane, <a href="#Page_45">45</a>.</span><br />
+
+<span style="margin-left: 2em;">Galongoon, eruption of, <a href="#Page_294">294</a>.</span><br />
+
+<span style="margin-left: 2em;">Geological work of water, <a href="#Page_168">168</a>-<a href="#Page_206">206</a>.</span><br />
+
+<span style="margin-left: 2em;">Glacial action in the valleys of Switzerland, <a href="#Page_224">224</a>;</span><br />
+<span style="margin-left: 3em;">periods, <a href="#Page_63">63</a>, <a href="#Page_243">243</a>, <a href="#Page_246">246</a>;</span><br />
+<span style="margin-left: 3em;">in the northern hemisphere, <a href="#Page_246">246</a>;</span><br />
+<span style="margin-left: 3em;">waste, <a href="#Page_324">324</a>.</span><br />
+
+<span style="margin-left: 2em;">Glaciation,</span><br />
+<span style="margin-left: 3em;">effect of,</span><br />
+<span style="margin-left: 4em;">in North America, <a href="#Page_241">241</a>;</span><br />
+<span style="margin-left: 4em;">in Central America, <a href="#Page_234">234</a>;</span><br />
+<span style="margin-left: 4em;">South America, <a href="#Page_234">234</a>.</span><br />
+
+<span style="margin-left: 2em;">Glaciers, <a href="#Page_207">207</a>-<a href="#Page_249">249</a>;</span><br />
+<span style="margin-left: 3em;">action of ice in forming, <a href="#Page_230">230</a>-<a href="#Page_232">232</a>;</span><br />
+<span style="margin-left: 3em;">Alaskan, <a href="#Page_216">216</a>;</span><br />
+<span style="margin-left: 3em;">continental, <a href="#Page_225">225</a>, <a href="#Page_239">239</a>, <a href="#Page_240">240</a>;</span><br />
+<span style="margin-left: 3em;">discharge of, <a href="#Page_220">220</a>;</span><br />
+<span style="margin-left: 3em;">exploring, <a href="#Page_220">220</a>;</span><br />
+<span style="margin-left: 3em;">extensive, in Greenland and Scandinavia, <a href="#Page_244">244</a>;</span><br />
+<span style="margin-left: 3em;">former, of North America, <a href="#Page_232">232</a>, <a href="#Page_234">234</a>;</span><br />
+<span style="margin-left: 3em;">map of, and moraines near Mont Blanc, <a href="#Page_217">217</a>;</span><br />
+<span style="margin-left: 3em;">motions of, <a href="#Page_213">213</a>;</span><br />
+<span style="margin-left: 3em;">retreat of the, <a href="#Page_228">228</a>, <a href="#Page_230">230</a>, <a href="#Page_235">235</a>;</span><br />
+<span style="margin-left: 3em;">secrets of the under ice of, <a href="#Page_221">221</a>;</span><br />
+<span style="margin-left: 3em;">speed of a, <a href="#Page_224">224</a>;</span><br />
+<span style="margin-left: 3em;">study of, in the Swiss valleys, <a href="#Page_222">222</a>;</span><br />
+<span style="margin-left: 3em;">testimony of the rocks regarding, <a href="#Page_228">228</a>;</span><br />
+<span style="margin-left: 3em;">when covered with winter snows, <a href="#Page_216">216</a>;</span><br />
+<span style="margin-left: 3em;">valley, <a href="#Page_216">216</a>.</span><br />
+
+<span style="margin-left: 2em;">Gombridge, 1830, <a href="#Page_74">74</a>.</span><br />
+
+<span style="margin-left: 2em;">Gravitation, law of, <a href="#Page_4">4</a>.</span><br />
+
+<span style="margin-left: 2em;">Greeks' idea of the heavens, <a href="#Page_31">31</a>;</span><br />
+<span style="margin-left: 3em;">not mechanically inventive, <a href="#Page_22">22</a>.</span><br />
+
+<span style="margin-left: 2em;">Gulf Stream, current of the, <a href="#Page_147">147</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Heat,</span><br />
+<span style="margin-left: 3em;">amount of, daily escaping from the earth, <a href="#Page_89">89</a>;</span><br />
+<span style="margin-left: 3em;">amount of, falling from the sun on the earth, <a href="#Page_41">41</a>;</span><br />
+<span style="margin-left: 3em;">belief of the ancients regarding, <a href="#Page_42">42</a>;</span><br />
+<span style="margin-left: 3em;">dominating effect on air currents of tropical, <a href="#Page_104">104</a>;</span><br />
+<span style="margin-left: 3em;">energy with which it leaves the sun, <a href="#Page_41">41</a>;</span><br />
+<span style="margin-left: 3em;">internal,</span><br />
+<span style="margin-left: 4em;">of the earth, <a href="#Page_88">88</a>, <a href="#Page_89">89</a>;</span><br />
+<span style="margin-left: 4em;">of the earth's interior, <a href="#Page_309">309</a>, <a href="#Page_310">310</a>;</span><br />
+<span style="margin-left: 3em;">sun, effect on the atmosphere of the, <a href="#Page_100">100</a>;</span><br />
+<span style="margin-left: 3em;">Prof. Newcomb's belief regarding the, of the sun, <a href="#Page_52">52</a>;</span><br />
+<span style="margin-left: 3em;">radiation of the earth's, causing winds, <a href="#Page_101">101</a>;</span><br />
+<span style="margin-left: 3em;">solar, <a href="#Page_41">41</a>;</span><br />
+<span style="margin-left: 3em;">tropical, and air currents, <a href="#Page_104">104</a>.</span><br />
+
+<span style="margin-left: 2em;">Hills, sand, <a href="#Page_123">123</a>.</span><br />
+
+<span style="margin-left: 2em;">Horizontal pendulum, <a href="#Page_384">384</a>.</span><br />
+
+<span style="margin-left: 2em;">Horse latitudes, <a href="#Page_104">104</a>.</span><br />
+
+<span style="margin-left: 2em;">"Horses," <a href="#Page_261">261</a>.</span><br />
+
+<span style="margin-left: 2em;">Hurricanes, <a href="#Page_107">107</a>, <a href="#Page_110">110</a>, <a href="#Page_317">317</a>;</span><br />
+<span style="margin-left: 3em;">commencement of, <a href="#Page_107">107</a>;</span><br />
+<span style="margin-left: 3em;">doldrum of, <a href="#Page_109">109</a>;</span><br />
+<span style="margin-left: 3em;">felt near the sea, <a href="#Page_110">110</a>;</span><br />
+<span style="margin-left: 3em;">in the tropics, <a href="#Page_110">110</a>.</span><br />
+
+<span style="margin-left: 2em;">Hypothesis,</span><br />
+<span style="margin-left: 3em;">nebular, <a href="#Page_34">34</a>, <a href="#Page_35">35</a>, <a href="#Page_39">39</a>, <a href="#Page_52">52</a>, <a href="#Page_56">56</a>;</span><br />
+<span style="margin-left: 3em;">working, <a href="#Page_4">4</a>, <a href="#Page_5">5</a>.</span><br />
+
+
+<span class='pagenum'><a name="Page_411" id="Page_411">[Pg 411]</a></span><span style="margin-left: 2em;">Ice action,</span><br />
+<span style="margin-left: 3em;">effect of intense, <a href="#Page_222">222</a>, <a href="#Page_223">223</a>;</span><br />
+<span style="margin-left: 3em;">in forming glaciers, <a href="#Page_230">230</a>, <a href="#Page_232">232</a>;</span><br />
+<span style="margin-left: 3em;">recent studies in Greenland of, <a href="#Page_239">239</a>;</span><br />
+<span style="margin-left: 3em;">depth of, in Greenland, <a href="#Page_227">227</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on river channels, <a href="#Page_196">196</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on stream beds, <a href="#Page_196">196</a>;</span><br />
+<span style="margin-left: 3em;">expanding when freezing, <a href="#Page_237">237</a>;</span><br />
+<span style="margin-left: 3em;">epoch, <a href="#Page_92">92</a>, <a href="#Page_93">93</a>, <a href="#Page_246">246</a>;</span><br />
+<span style="margin-left: 3em;">floating, <a href="#Page_242">242</a>;</span><br />
+<span style="margin-left: 3em;">made soils rarely fertile, <a href="#Page_241">241</a>;</span><br />
+<span style="margin-left: 3em;">mass, greatest, in Greenland, <a href="#Page_226">226</a>, <a href="#Page_227">227</a>;</span><br />
+<span style="margin-left: 3em;">moulded by pressure, <a href="#Page_215">215</a>;</span><br />
+<span style="margin-left: 3em;">streams,</span><br />
+<span style="margin-left: 4em;">continental, <a href="#Page_225">225</a>, <a href="#Page_226">226</a>;</span><br />
+<span style="margin-left: 4em;">of the mountains, <a href="#Page_225">225</a>;</span><br />
+<span style="margin-left: 4em;">of the Himalayan Mountains, <a href="#Page_234">234</a>.</span><br />
+
+<span style="margin-left: 2em;">Icebergs, <a href="#Page_242">242</a>, <a href="#Page_243">243</a>;</span><br />
+<span style="margin-left: 3em;">indicating oceanic currents, <a href="#Page_243">243</a>.</span><br />
+
+<span style="margin-left: 2em;">Iceland, volcanic eruptions in, <a href="#Page_297">297</a>, <a href="#Page_298">298</a>.</span><br />
+
+<span style="margin-left: 2em;">Instruments, first, astronomical, <a href="#Page_10">10</a>, <a href="#Page_11">11</a>.</span><br />
+
+<span style="margin-left: 2em;">Inventions, mechanical, aiding science, <a href="#Page_22">22</a>.</span><br />
+
+<span style="margin-left: 2em;">Islands, <a href="#Page_84">84</a>, <a href="#Page_272">272</a>;</span><br />
+<span style="margin-left: 3em;">continental, <a href="#Page_84">84</a>;</span><br />
+<span style="margin-left: 3em;">in the deeper seas made up of volcanic ejections, <a href="#Page_272">272</a>;</span><br />
+<span style="margin-left: 3em;">volcanic, <a href="#Page_272">272</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Jack-o'-lantern, <a href="#Page_167">167</a>.</span><br />
+
+<span style="margin-left: 2em;">Jupiter,</span><br />
+<span style="margin-left: 3em;">gaseous wraps of, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">path of the earth affected by, <a href="#Page_59">59</a>, <a href="#Page_60">60</a>;</span><br />
+<span style="margin-left: 3em;">the largest planet of the sun, <a href="#Page_69">69</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Kames, <a href="#Page_325">325</a>.</span><br />
+
+<span style="margin-left: 2em;">Kant, Immanuel, and nebular hypothesis, <a href="#Page_34">34</a>.</span><br />
+
+<span style="margin-left: 2em;">Kaolin, <a href="#Page_324">324</a>.</span><br />
+
+<span style="margin-left: 2em;">Klondike district, cold in, <a href="#Page_243">243</a>, <a href="#Page_244">244</a>.</span><br />
+
+<span style="margin-left: 2em;">Krakatoa,</span><br />
+<span style="margin-left: 3em;">eruption of, <a href="#Page_298">298</a>-<a href="#Page_300">300</a>;</span><br />
+<span style="margin-left: 4em;">effect of, on the sea, <a href="#Page_299">299</a>;</span><br />
+<span style="margin-left: 4em;">effect of, on the sun, <a href="#Page_300">300</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Lacolites, <a href="#Page_306">306</a>.</span><br />
+
+<span style="margin-left: 2em;">Lacustrine beds, <a href="#Page_351">351</a>.</span><br />
+
+<span style="margin-left: 2em;">Lagoons, salt deposits found in, <a href="#Page_200">200</a>.</span><br />
+
+<span style="margin-left: 2em;">Lake basins,</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_200">200</a>, <a href="#Page_201">201</a>;</span><br />
+<span style="margin-left: 3em;">bogs, <a href="#Page_331">331</a>, <a href="#Page_333">333</a>, <a href="#Page_334">334</a>;</span><br />
+<span style="margin-left: 3em;">deposits, <a href="#Page_350">350</a>, <a href="#Page_351">351</a>.</span><br />
+
+<span style="margin-left: 2em;">Lakes, <a href="#Page_199">199</a>-<a href="#Page_206">206</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on the river system, <a href="#Page_205">205</a>;</span><br />
+<span style="margin-left: 3em;">fresh-water, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">formed from caverns, <a href="#Page_202">202</a>;</span><br />
+<span style="margin-left: 3em;">great, changing their outlets, <a href="#Page_205">205</a>;</span><br />
+<span style="margin-left: 3em;">of extinct volcanoes, <a href="#Page_203">203</a>;</span><br />
+<span style="margin-left: 3em;">temporary features of the land, <a href="#Page_203">203</a>;</span><br />
+<span style="margin-left: 3em;">volcanic, <a href="#Page_203">203</a>.</span><br />
+
+<span style="margin-left: 2em;">Lands,</span><br />
+<span style="margin-left: 3em;">great, relatively unchangeable, <a href="#Page_96">96</a>;</span><br />
+<span style="margin-left: 3em;">table, <a href="#Page_91">91</a>;</span><br />
+<span style="margin-left: 3em;">movements resulting in change of coast line, <a href="#Page_351">351</a>, <a href="#Page_352">352</a>;</span><br />
+<span style="margin-left: 3em;">shape of the seas and, <a href="#Page_83">83</a>, <a href="#Page_84">84</a>;</span><br />
+<span style="margin-left: 3em;">accounting for the changes in the attitude of the, <a href="#Page_95">95</a>;</span><br />
+<span style="margin-left: 3em;">and water, divisions of, <a href="#Page_84">84</a>;</span><br />
+<span style="margin-left: 3em;">dry, surface of, <a href="#Page_85">85</a>;</span><br />
+<span style="margin-left: 3em;">general statement as to the division of the, <a href="#Page_83">83</a>, <a href="#Page_84">84</a>;</span><br />
+<span style="margin-left: 3em;">surface, shape of the, <a href="#Page_85">85</a>;</span><br />
+<span style="margin-left: 3em;">triangular forms of great, <a href="#Page_90">90</a>.</span><br />
+
+<span style="margin-left: 2em;">Latitudes, horse, troublesome to mariners, <a href="#Page_104">104</a>.</span><br />
+
+<span style="margin-left: 2em;">Laplace and nebular hypothesis, <a href="#Page_34">34</a>.</span><br />
+
+<span style="margin-left: 2em;">Lava, <a href="#Page_266">266</a>-<a href="#Page_268">268</a>, <a href="#Page_270">270</a>, <a href="#Page_271">271</a>, <a href="#Page_292">292</a>, <a href="#Page_293">293</a>, <a href="#Page_295">295</a>, <a href="#Page_296">296</a>, <a href="#Page_303">303</a>, <a href="#Page_304">304</a>;</span><br />
+<span style="margin-left: 3em;">flow of, invading a forest, <a href="#Page_268">268</a>;</span><br />
+<span style="margin-left: 3em;">from Vesuvius, <a href="#Page_293">293</a>;</span><br />
+<span style="margin-left: 3em;">of 1669, <a href="#Page_295">295</a>, <a href="#Page_296">296</a>;</span><br />
+<span style="margin-left: 3em;">temperature of, <a href="#Page_295">295</a>, <a href="#Page_296">296</a>;</span><br />
+<span style="margin-left: 3em;">incipient, <a href="#Page_304">304</a>;</span><br />
+<span style="margin-left: 3em;">outbreaks of, <a href="#Page_292">292</a>, <a href="#Page_303">303</a>;</span><br />
+<span style="margin-left: 3em;">stream eaves, <a href="#Page_292">292</a>, <a href="#Page_293">293</a>.</span><br />
+
+<span style="margin-left: 2em;">Law, natural,</span><br />
+<span style="margin-left: 3em;">Aristotle and, <a href="#Page_3">3</a>;</span><br />
+<span style="margin-left: 3em;">of gravitation, <a href="#Page_4">4</a>;</span><br />
+<span style="margin-left: 3em;">of the conservation of energy, <a href="#Page_23">23</a>.</span><br />
+
+<span style="margin-left: 2em;">Leaves, radiation of, <a href="#Page_160">160</a>.</span><br />
+
+<span style="margin-left: 2em;">Length of days affected by tidal action, <a href="#Page_131">131</a>.</span><br />
+
+<span style="margin-left: 2em;">Level surfaces, <a href="#Page_91">91</a>.</span><br />
+
+<span style="margin-left: 2em;">Life, organic, evolution of, <a href="#Page_15">15</a>, <a href="#Page_16">16</a>.</span><br />
+
+<span style="margin-left: 2em;">Light, belief of the ancients regarding, <a href="#Page_42">42</a>.</span><br />
+
+<span style="margin-left: 2em;">Lightning, <a href="#Page_24">24</a>, <a href="#Page_164">164</a>-<a href="#Page_168">168</a>;</span><br />
+<span style="margin-left: 3em;">noise from, <a href="#Page_166">166</a>;</span><br />
+<span style="margin-left: 3em;">proceeding from the earth to the clouds, <a href="#Page_165">165</a>;</span><br />
+<span style="margin-left: 3em;">protection of buildings from, <a href="#Page_165">165</a>;</span><br />
+<span style="margin-left: 3em;">stroke, wearing-out effect of, <a href="#Page_165">165</a>.</span><br />
+
+<span style="margin-left: 2em;">Limestones, <a href="#Page_353">353</a>, <a href="#Page_357">357</a>, <a href="#Page_358">358</a>, <a href="#Page_360">360</a>, <a href="#Page_364">364</a>;</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_357">357</a>, <a href="#Page_360">360</a>.</span><br />
+
+<span style="margin-left: 2em;">Lisbon, earthquake of, 1755, <a href="#Page_368">368</a>, <a href="#Page_369">369</a>.</span><br />
+
+<span style="margin-left: 2em;">Lowell, Mr. Percival, observations on Venus, <a href="#Page_64">64</a>.</span><br />
+
+<span style="margin-left: 2em;">Lunar mountains near the Gulf of Iris, <a href="#Page_397">397</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Mackerel sky, <a href="#Page_35">35</a>.</span><br />
+
+<span class='pagenum'><a name="Page_412" id="Page_412">[Pg 412]</a></span><span style="margin-left: 2em;">Mallet, Mr. Charles, and the study of earthquakes, <a href="#Page_382">382</a>, <a href="#Page_383">383</a>.</span><br />
+
+<span style="margin-left: 2em;">Man as an inventor of tools, <a href="#Page_10">10</a>.</span><br />
+
+<span style="margin-left: 2em;">Mangroves, <a href="#Page_340">340</a>;</span><br />
+<span style="margin-left: 3em;">diagram showing mode of growth, <a href="#Page_340">340</a>;</span><br />
+<span style="margin-left: 3em;">marshes of, <a href="#Page_339">339</a>.</span><br />
+
+<span style="margin-left: 2em;">Map of glaciers and moraines near Mont Blanc, <a href="#Page_217">217</a>;</span><br />
+<span style="margin-left: 3em;">of Ipswich marshes, <a href="#Page_338">338</a>.</span><br />
+
+<span style="margin-left: 2em;">Mapping with contour lines, <a href="#Page_27">27</a>.</span><br />
+
+<span style="margin-left: 2em;">Maps,</span><br />
+<span style="margin-left: 3em;">desirable, for the study of celestial geography, <a href="#Page_77">77</a>;</span><br />
+<span style="margin-left: 3em;">geographic sketch, <a href="#Page_26">26</a>, <a href="#Page_27">27</a>.</span><br />
+
+<span style="margin-left: 2em;">Marching sands jeopardizing agriculture, <a href="#Page_123">123</a>.</span><br />
+
+<span style="margin-left: 2em;">Marine animals, sustenance of, <a href="#Page_361">361</a>-<a href="#Page_363">363</a>;</span><br />
+<span style="margin-left: 3em;">deposits, <a href="#Page_325">325</a>-<a href="#Page_327">327</a>, <a href="#Page_349">349</a>, <a href="#Page_356">356</a>;</span><br />
+<span style="margin-left: 3em;">marshes, <a href="#Page_336">336</a>-<a href="#Page_340">340</a>;</span><br />
+<span style="margin-left: 3em;">waves caused by earthquakes, <a href="#Page_387">387</a>.</span><br />
+
+<span style="margin-left: 2em;">Mars, <a href="#Page_65">65</a>-<a href="#Page_67">67</a>, <a href="#Page_84">84</a>, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">belief that it has an atmosphere, <a href="#Page_65">65</a>;</span><br />
+<span style="margin-left: 3em;">canals of, <a href="#Page_67">67</a>;</span><br />
+<span style="margin-left: 3em;">gaseous wraps of, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">more efficient telescopes required for the study of, <a href="#Page_67">67</a>;</span><br />
+<span style="margin-left: 3em;">nearer to the earth than other planets, <a href="#Page_65">65</a>.</span><br />
+
+<span style="margin-left: 2em;">Marshes,</span><br />
+<span style="margin-left: 3em;">mangrove, <a href="#Page_339">339</a>;</span><br />
+<span style="margin-left: 3em;">map of Ipswich, <a href="#Page_338">338</a>;</span><br />
+<span style="margin-left: 3em;">marine, <a href="#Page_336">336</a>-<a href="#Page_340">340</a>;</span><br />
+<span style="margin-left: 3em;">deposits found in, <a href="#Page_336">336</a>;</span><br />
+<span style="margin-left: 3em;">of North America, <a href="#Page_337">337</a>;</span><br />
+<span style="margin-left: 3em;">on the coast of New England, <a href="#Page_339">339</a>;</span><br />
+<span style="margin-left: 3em;">phenomena of, <a href="#Page_167">167</a>, <a href="#Page_168">168</a>;</span><br />
+<span style="margin-left: 3em;">tidal, good earth for tillage, <a href="#Page_337">337</a>;</span><br />
+<span style="margin-left: 3em;">tidal, of North America, <a href="#Page_340">340</a>.</span><br />
+
+<span style="margin-left: 2em;">Mercury, <a href="#Page_55">55</a>, <a href="#Page_63">63</a>, <a href="#Page_78">78</a>;</span><br />
+<span style="margin-left: 3em;">nearest to the sun, <a href="#Page_63">63</a>;</span><br />
+<span style="margin-left: 3em;">time in which it completes the circle of its year, <a href="#Page_55">55</a>.</span><br />
+
+<span style="margin-left: 2em;">Meteorites, <a href="#Page_47">47</a>, <a href="#Page_48">48</a>;</span><br />
+<span style="margin-left: 3em;">kinship of comets and, <a href="#Page_48">48</a>.</span><br />
+
+<span style="margin-left: 2em;">Meteors, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">falling, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">composition of, <a href="#Page_48">48</a>;</span><br />
+<span style="margin-left: 3em;">flashing, <a href="#Page_39">39</a>, <a href="#Page_40">40</a>, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">speed of, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">inflamed by friction with air, <a href="#Page_99">99</a>.</span><br />
+
+<span style="margin-left: 2em;">Methods in studying geology, <a href="#Page_400">400</a>.</span><br />
+
+<span style="margin-left: 2em;">Milky Way, <a href="#Page_45">45</a>;</span><br />
+<span style="margin-left: 3em;">voyage along the path of the, <a href="#Page_44">44</a>, <a href="#Page_45">45</a>.</span><br />
+
+<span style="margin-left: 2em;">Mineral crusts, <a href="#Page_328">328</a>, <a href="#Page_329">329</a>;</span><br />
+<span style="margin-left: 3em;">deposits, <a href="#Page_308">308</a>.</span><br />
+
+<span style="margin-left: 2em;">Moon, <a href="#Page_38">38</a>, <a href="#Page_395">395</a>-<a href="#Page_400">400</a>;</span><br />
+<span style="margin-left: 3em;">absence of air and water on the, <a href="#Page_399">399</a>;</span><br />
+<span style="margin-left: 3em;">attended by satellites, <a href="#Page_57">57</a>;</span><br />
+<span style="margin-left: 3em;">attraction which it exercises on the earth, <a href="#Page_62">62</a>;</span><br />
+<span style="margin-left: 3em;">curious feature of the, <a href="#Page_397">397</a>;</span><br />
+<span style="margin-left: 3em;">destitute of gaseous or aqueous envelope, <a href="#Page_397">397</a>;</span><br />
+<span style="margin-left: 3em;">diameter of the, <a href="#Page_399">399</a>;</span><br />
+<span style="margin-left: 3em;">imaginary view of the earth from the, <a href="#Page_81">81</a>;</span><br />
+<span style="margin-left: 3em;">"libration" of the, <a href="#Page_398">398</a>;</span><br />
+<span style="margin-left: 3em;">made up of circular depressions, <a href="#Page_396">396</a>, <a href="#Page_397">397</a>;</span><br />
+<span style="margin-left: 3em;">movements of the, <a href="#Page_78">78</a>;</span><br />
+<span style="margin-left: 3em;">no atmosphere in the, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">parting of the earth and, <a href="#Page_396">396</a>;</span><br />
+<span style="margin-left: 3em;">position of the, in relation to the earth, <a href="#Page_62">62</a>;</span><br />
+<span style="margin-left: 3em;">tidal action and the, <a href="#Page_131">131</a>;</span><br />
+<span style="margin-left: 3em;">tides of the, <a href="#Page_126">126</a>, <a href="#Page_127">127</a>;</span><br />
+<span style="margin-left: 3em;">why does the sun not act in the same manner as the, <a href="#Page_78">78</a>.</span><br />
+
+<span style="margin-left: 2em;">Moraines, <a href="#Page_216">216</a>, <a href="#Page_218">218</a>, <a href="#Page_229">229</a>, <a href="#Page_230">230</a>;</span><br />
+<span style="margin-left: 3em;">map of glaciers and, near Mont Blanc, <a href="#Page_217">217</a>;</span><br />
+<span style="margin-left: 3em;">movements of the, <a href="#Page_216">216</a>-<a href="#Page_218">218</a>;</span><br />
+<span style="margin-left: 3em;">terminal, <a href="#Page_228">228</a>.</span><br />
+
+<span style="margin-left: 2em;"><i>Moulin</i>, <a href="#Page_219">219</a>.</span><br />
+
+<span style="margin-left: 2em;">Mount &AElig;tna, <a href="#Page_288">288</a>-<a href="#Page_310">310</a>;</span><br />
+<span style="margin-left: 3em;">lava yielding, <a href="#Page_290">290</a>, <a href="#Page_293">293</a>, <a href="#Page_294">294</a>;</span><br />
+<span style="margin-left: 3em;">lava stream caves of, <a href="#Page_292">292</a>, <a href="#Page_293">293</a>;</span><br />
+<span style="margin-left: 3em;">more powerful than Vesuvius, <a href="#Page_297">297</a>;</span><br />
+<span style="margin-left: 3em;">peculiarities of, <a href="#Page_291">291</a>, <a href="#Page_292">292</a>;</span><br />
+<span style="margin-left: 3em;">size of, <a href="#Page_289">289</a>-<a href="#Page_291">291</a>;</span><br />
+<span style="margin-left: 3em;">turning of the torrents of, <a href="#Page_295">295</a>.</span><br />
+
+<span style="margin-left: 2em;">Mountain-building, <a href="#Page_90">90</a>-<a href="#Page_93">93</a>, <a href="#Page_304">304</a>;</span><br />
+<span style="margin-left: 3em;">folding, <a href="#Page_86">86</a>, <a href="#Page_87">87</a>, <a href="#Page_90">90</a>, <a href="#Page_365">365</a>;</span><br />
+<span style="margin-left: 4em;">attributed to cooling of the earth, <a href="#Page_88">88</a>;</span><br />
+<span style="margin-left: 3em;">growth, <a href="#Page_392">392</a>;</span><br />
+<span style="margin-left: 3em;">Swiss falls, <a href="#Page_174">174</a>;</span><br />
+<span style="margin-left: 3em;">torrents, energy of, <a href="#Page_177">177</a>.</span><br />
+
+<span style="margin-left: 2em;">Mountains, <a href="#Page_85">85</a>, <a href="#Page_86">86</a>, <a href="#Page_89">89</a>, <a href="#Page_90">90</a>-<a href="#Page_93">93</a>; <a href="#Page_174">174</a>-<a href="#Page_178">178</a>;</span><br />
+<span style="margin-left: 3em;">form and structure of, <a href="#Page_86">86</a>;</span><br />
+<span style="margin-left: 3em;">partly caused by escape of heat from the earth, <a href="#Page_89">89</a>;</span><br />
+<span style="margin-left: 3em;">sections of, <a href="#Page_87">87</a>.</span><br />
+
+<span style="margin-left: 2em;">Mount Nuova, formation of, <a href="#Page_284">284</a>.</span><br />
+
+<span style="margin-left: 2em;">Mount Vesuvius, <a href="#Page_263">263</a>-<a href="#Page_285">285</a>, <a href="#Page_288">288</a>, <a href="#Page_289">289</a>, <a href="#Page_293">293</a>, <a href="#Page_302">302</a>, <a href="#Page_381">381</a>;</span><br />
+<span style="margin-left: 3em;">description of the eruption of, in <span class="smcap">a.d.</span> 79, <a href="#Page_277">277</a>-<a href="#Page_280">280</a>;</span><br />
+<span style="margin-left: 3em;">diagrammatic sections through, showing changes in the form of the cone, <a href="#Page_283">283</a>;</span><br />
+<span style="margin-left: 3em;">eruption of, in 1056, <a href="#Page_281">281</a>;</span><br />
+<span style="margin-left: 3em;">in 1882-'83, <a href="#Page_264">264</a>, <a href="#Page_266">266</a>;</span><br />
+<span style="margin-left: 3em;">eruption of, in 1872, <a href="#Page_282">282</a>;</span><br />
+<span style="margin-left: 3em;">eruptions of, increased since 1636, <a href="#Page_282">282</a>;</span><br />
+<span style="margin-left: 3em;">flow of lava from, <a href="#Page_285">285</a>;</span><br />
+<span style="margin-left: 3em;">likely to enter on a period of inaction, <a href="#Page_282">282</a>, <a href="#Page_283">283</a>;</span><br />
+<span class='pagenum'><a name="Page_413" id="Page_413">[Pg 413]</a></span>
+<span style="margin-left: 3em;">outbreak of, in 1882-'83, <a href="#Page_264">264</a>, <a href="#Page_266">266</a>.</span><br />
+<span style="margin-left: 2em;">Naples, prosperity of the city, <a href="#Page_289">289</a>.</span><br />
+
+<span style="margin-left: 2em;">Nebular hypothesis, <a href="#Page_34">34</a>, <a href="#Page_35">35</a>, <a href="#Page_39">39</a>, <a href="#Page_52">52</a>.</span><br />
+
+<span style="margin-left: 2em;">Neptune, <a href="#Page_70">70</a>.</span><br />
+
+<span style="margin-left: 2em;"><i>N&eacute;v&eacute;</i>, the, <a href="#Page_214">214</a>;</span><br />
+<span style="margin-left: 3em;">no ice-cutting in the region of the, <a href="#Page_224">224</a>.</span><br />
+
+<span style="margin-left: 2em;">Newcomb's (Prof.) belief regarding the heat of the sun, <a href="#Page_52">52</a>.</span><br />
+
+<span style="margin-left: 2em;">Niagara Falls, <a href="#Page_191">191</a>, <a href="#Page_192">192</a>, <a href="#Page_204">204</a>;</span><br />
+<span style="margin-left: 3em;">cutting back of, <a href="#Page_204">204</a>.</span><br />
+
+<span style="margin-left: 2em;">North America,</span><br />
+<span style="margin-left: 3em;">changes in the form of, <a href="#Page_91">91</a>, <a href="#Page_92">92</a>;</span><br />
+<span style="margin-left: 3em;">triangular form of, <a href="#Page_90">90</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Ocean,</span><br />
+<span style="margin-left: 3em;">average depth of the, <a href="#Page_89">89</a>;</span><br />
+<span style="margin-left: 3em;">climatal effect of the, <a href="#Page_147">147</a>;</span><br />
+<span style="margin-left: 3em;">currents, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on migration, <a href="#Page_156">156</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on organic life, <a href="#Page_154">154</a>;</span><br />
+<span style="margin-left: 3em;">floor, <a href="#Page_85">85</a>, <a href="#Page_93">93</a>;</span><br />
+<span style="margin-left: 3em;">hot and cold currents of the, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">sinking of the, <a href="#Page_93">93</a>, <a href="#Page_94">94</a>;</span><br />
+<span style="margin-left: 3em;">the laboratory of sedimentary deposits, <a href="#Page_351">351</a>;</span><br />
+<span style="margin-left: 3em;">depth of the, <a href="#Page_89">89</a>, <a href="#Page_126">126</a>.</span><br />
+
+<span style="margin-left: 2em;">Oceanic circulation, effect of, on the temperature, <a href="#Page_152">152</a>.</span><br />
+
+<span style="margin-left: 2em;">Oceans and continents, <a href="#Page_83">83</a>.</span><br />
+
+<span style="margin-left: 2em;">Orbit,</span><br />
+<span style="margin-left: 3em;">alterations of the, and the seasons, <a href="#Page_60">60</a>, <a href="#Page_61">61</a>;</span><br />
+<span style="margin-left: 3em;">changing of the, <a href="#Page_59">59</a>-<a href="#Page_63">63</a>;</span><br />
+<span style="margin-left: 3em;">shape of the, <a href="#Page_61">61</a>-<a href="#Page_63">63</a>.</span><br />
+
+<span style="margin-left: 2em;">Organic life, <a href="#Page_315">315</a>, <a href="#Page_317">317</a>, <a href="#Page_321">321</a>, <a href="#Page_352">352</a>, <a href="#Page_353">353</a>, <a href="#Page_363">363</a>;</span><br />
+<span style="margin-left: 3em;">action of, on the soil, <a href="#Page_317">317</a>, <a href="#Page_321">321</a>;</span><br />
+<span style="margin-left: 3em;">advantages of the shore belt to, <a href="#Page_363">363</a>;</span><br />
+<span style="margin-left: 3em;">development of in the sea, <a href="#Page_352">352</a>, <a href="#Page_353">353</a>;</span><br />
+<span style="margin-left: 3em;">effect of ocean currents on, <a href="#Page_154">154</a>;</span><br />
+<span style="margin-left: 3em;">processes of, in the soil, <a href="#Page_315">315</a>;</span><br />
+<span style="margin-left: 3em;">decay of, in the earth, <a href="#Page_321">321</a>.</span><br />
+
+<span style="margin-left: 2em;">Orion, <a href="#Page_46">46</a>.</span><br />
+
+<span style="margin-left: 2em;">Oscillations of the shores of the Bay of Naples, <a href="#Page_287">287</a>.</span><br />
+
+<span style="margin-left: 2em;">Oxbow of a river, <a href="#Page_182">182</a>, <a href="#Page_183">183</a>.</span><br />
+
+<span style="margin-left: 2em;">Oxbows and cut-off, <a href="#Page_182">182</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Pebbles,</span><br />
+<span style="margin-left: 3em;">action of seaweeds on, <a href="#Page_143">143</a>;</span><br />
+<span style="margin-left: 3em;">action of the waves on, <a href="#Page_142">142</a>, <a href="#Page_144">144</a>.</span><br />
+
+<span style="margin-left: 2em;">Photosphere, <a href="#Page_74">74</a>.</span><br />
+
+<span style="margin-left: 2em;">Plains, <a href="#Page_86">86</a>;</span><br />
+<span style="margin-left: 3em;">alluvial, <a href="#Page_91">91</a>, <a href="#Page_179">179</a>, <a href="#Page_182">182</a>, <a href="#Page_184">184</a>-<a href="#Page_186">186</a>, <a href="#Page_325">325</a>;</span><br />
+<span style="margin-left: 3em;">history of, <a href="#Page_91">91</a>;</span><br />
+<span style="margin-left: 3em;">sand, <a href="#Page_325">325</a>.</span><br />
+
+<span style="margin-left: 2em;">Planets, <a href="#Page_38">38</a>;</span><br />
+<span style="margin-left: 3em;">attended by satellites, <a href="#Page_57">57</a>;</span><br />
+<span style="margin-left: 3em;">comparative sizes of the, <a href="#Page_68">68</a>;</span><br />
+<span style="margin-left: 3em;">experiments illustrating consolidation of disseminated materials of the sun and, <a href="#Page_40">40</a>;</span><br />
+<span style="margin-left: 3em;">gaseous wraps of, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">important observations by the ancients of fixed stars and planets, <a href="#Page_43">43</a>;</span><br />
+<span style="margin-left: 3em;">movements of, <a href="#Page_57">57</a>-<a href="#Page_61">61</a>;</span><br />
+<span style="margin-left: 3em;">outer, <a href="#Page_78">78</a>;</span><br />
+<span style="margin-left: 3em;">table of relative masses of sun and, <a href="#Page_77">77</a>.</span><br />
+
+<span style="margin-left: 2em;">Plant life in the Sargassum basins, <a href="#Page_156">156</a>.</span><br />
+
+<span style="margin-left: 2em;">Plants and animals,</span><br />
+<span style="margin-left: 3em;">protection of,</span><br />
+<span style="margin-left: 4em;">by mechanical contrivances, <a href="#Page_364">364</a>;</span><br />
+<span style="margin-left: 4em;">and trees, work of the roots of, on the soil, <a href="#Page_316">316</a>, <a href="#Page_317">317</a>;</span><br />
+<span style="margin-left: 3em;">water-loving, <a href="#Page_181">181</a>;</span><br />
+<span style="margin-left: 3em;">forming climbing bogs, <a href="#Page_332">332</a>.</span><br />
+
+<span style="margin-left: 2em;">Polar axes, nodding movement of, <a href="#Page_54">54</a>.</span><br />
+
+<span style="margin-left: 2em;">Polar snow cap, <a href="#Page_66">66</a>.</span><br />
+
+<span style="margin-left: 2em;">Polyps, <a href="#Page_155">155</a>, <a href="#Page_353">353</a>.</span><br />
+
+<span style="margin-left: 2em;">Pools, circular, <a href="#Page_203">203</a>.</span><br />
+
+<span style="margin-left: 2em;">Prairies, <a href="#Page_340">340</a>, <a href="#Page_342">342</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Radiation of heat, <a href="#Page_159">159</a>.</span><br />
+
+<span style="margin-left: 2em;">Rain, <a href="#Page_152">152</a>, <a href="#Page_156">156</a>, <a href="#Page_164">164</a>, <a href="#Page_168">168</a>, <a href="#Page_170">170</a>, <a href="#Page_328">328</a>, <a href="#Page_330">330</a>;</span><br />
+<span style="margin-left: 3em;">circuit of the, <a href="#Page_156">156</a>-<a href="#Page_168">168</a>;</span><br />
+<span style="margin-left: 3em;">drops, force of, <a href="#Page_169">169</a>, <a href="#Page_170">170</a>;</span><br />
+<span style="margin-left: 3em;">spheroidal form of, <a href="#Page_170">170</a>;</span><br />
+<span style="margin-left: 3em;">electrical action in the formation of snow and, <a href="#Page_164">164</a>;</span><br />
+<span style="margin-left: 3em;">work of the, <a href="#Page_171">171</a>.</span><br />
+
+<span style="margin-left: 2em;">Realm, unseen solar, <a href="#Page_75">75</a>.</span><br />
+
+<span style="margin-left: 2em;">Reeds, <a href="#Page_332">332</a>.</span><br />
+
+<span style="margin-left: 2em;">Religion,</span><br />
+<span style="margin-left: 3em;">conflict between science and, <a href="#Page_20">20</a>, <a href="#Page_22">22</a>;</span><br />
+<span style="margin-left: 3em;">struggle between paganism and, <a href="#Page_21">21</a>.</span><br />
+
+<span style="margin-left: 2em;">Rivers and <i>d&eacute;bris</i>, <a href="#Page_183">183</a>;</span><br />
+<span style="margin-left: 3em;">changes in the course of, in alluvial plain, <a href="#Page_182">182</a>;</span><br />
+<span style="margin-left: 3em;">deposition of, accelerated by tree-planting, <a href="#Page_181">181</a>;</span><br />
+<span style="margin-left: 3em;">great, always clear, <a href="#Page_205">205</a>;</span><br />
+<span style="margin-left: 3em;">inundation of the Mississippi, eating away land, <a href="#Page_182">182</a>;</span><br />
+<span style="margin-left: 3em;">muds, <a href="#Page_222">222</a>;</span><br />
+<span style="margin-left: 3em;">newly formed, cutting a ca&ntilde;on, <a href="#Page_195">195</a>;</span><br />
+<span style="margin-left: 3em;">of snow-ice, <a href="#Page_211">211</a>;</span><br />
+<span style="margin-left: 3em;">origin of a normal, <a href="#Page_173">173</a>;</span><br />
+<span style="margin-left: 3em;">oxbow of a, <a href="#Page_182">182</a>, <a href="#Page_183">183</a>;</span><br />
+<span style="margin-left: 3em;">sinking of, <a href="#Page_199">199</a>;</span><br />
+<span style="margin-left: 3em;">swinging movement of, <a href="#Page_179">179</a>-<a href="#Page_181">181</a>;</span><br />
+<span style="margin-left: 3em;">river-valleys, <a href="#Page_193">193</a>, <a href="#Page_194">194</a>;</span><br />
+<span class='pagenum'><a name="Page_414" id="Page_414">[Pg 414]</a></span>
+<span style="margin-left: 3em;">diversity in the form of <a href="#Page_188">188</a>-<a href="#Page_191">191</a>.</span><br />
+
+<span style="margin-left: 2em;">Rocks, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">accidents from falling, <a href="#Page_174">174</a>;</span><br />
+<span style="margin-left: 3em;">cut away by sandstones, <a href="#Page_188">188</a>;</span><br />
+<span style="margin-left: 3em;">divided by crevices, <a href="#Page_252">252</a>;</span><br />
+<span style="margin-left: 3em;">duration of events recorded in, <a href="#Page_389">389</a>, <a href="#Page_390">390</a>,</span><br />
+<span style="margin-left: 3em;">ejection of, material, <a href="#Page_311">311</a>;</span><br />
+<span style="margin-left: 3em;">falling of, <a href="#Page_174">174</a>-<a href="#Page_176">176</a>;</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_262">262</a>, <a href="#Page_263">263</a>;</span><br />
+<span style="margin-left: 3em;">from the present day to the strata of the Laurentian, <a href="#Page_390">390</a>;</span><br />
+<span style="margin-left: 3em;">migration of, <a href="#Page_291">291</a>;</span><br />
+<span style="margin-left: 3em;">poised, indicating a long exemption from strong earthquakes, <a href="#Page_388">388</a>;</span><br />
+<span style="margin-left: 3em;">rents in, <a href="#Page_252">252</a>, <a href="#Page_253">253</a>;</span><br />
+<span style="margin-left: 3em;">stratification of, <a href="#Page_349">349</a>, <a href="#Page_350">350</a>, <a href="#Page_352">352</a>, <a href="#Page_365">365</a>, <a href="#Page_390">390</a>;</span><br />
+<span style="margin-left: 3em;">testimony of the, in regard to glaciers, <a href="#Page_228">228</a>;</span><br />
+<span style="margin-left: 3em;">under volcanoes, <a href="#Page_303">303</a>;</span><br />
+<span style="margin-left: 3em;">variable elasticity of, <a href="#Page_366">366</a>;</span><br />
+<span style="margin-left: 3em;">vibration of, <a href="#Page_367">367</a>, <a href="#Page_368">368</a>;</span><br />
+<span style="margin-left: 3em;">rock-waste, march of the, <a href="#Page_343">343</a>;</span><br />
+<span style="margin-left: 3em;">water, <a href="#Page_250">250</a>, <a href="#Page_267">267</a>.</span><br />
+
+<span style="margin-left: 2em;">Rotation of the earth affected by tides, <a href="#Page_130">130</a>;</span><br />
+<span style="margin-left: 3em;">of the planetary spheres on their axes, <a href="#Page_56">56</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Salicified forests, <a href="#Page_124">124</a>.</span><br />
+
+<span style="margin-left: 2em;">Salt deposits formed in lagoons, <a href="#Page_200">200</a>;</span><br />
+<span style="margin-left: 3em;">found in lakes, <a href="#Page_199">199</a>-<a href="#Page_200">200</a>.</span><br />
+
+<span style="margin-left: 2em;">Sand bars, <a href="#Page_183">183</a>;</span><br />
+<span style="margin-left: 3em;">endurance of, against the waves, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">hills, travelling of, <a href="#Page_123">123</a>;</span><br />
+<span style="margin-left: 3em;">marching, <a href="#Page_123">123</a>;</span><br />
+<span style="margin-left: 3em;">silicious stones cutting away rooks, <a href="#Page_188">188</a>.</span><br />
+
+<span style="margin-left: 2em;">Satellites, <a href="#Page_53">53</a>, <a href="#Page_54">54</a>;</span><br />
+<span style="margin-left: 3em;">motions of, about their centres and about the sun, <a href="#Page_53">53</a>, <a href="#Page_54">54</a>.</span><br />
+
+<span style="margin-left: 2em;">Saturn, <a href="#Page_38">38</a>, <a href="#Page_53">53</a>, <a href="#Page_57">57</a>, <a href="#Page_396">396</a>;</span><br />
+<span style="margin-left: 3em;">cloud bands of, <a href="#Page_70">70</a>;</span><br />
+<span style="margin-left: 3em;">gaseous wraps of, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">path of the earth affected by, <a href="#Page_59">59</a>, <a href="#Page_60">60</a>.</span><br />
+
+<span style="margin-left: 2em;">Savages, primitive, students of Nature, <a href="#Page_1">1</a>.</span><br />
+
+<span style="margin-left: 2em;">Scandinavia, changes on the coasts of, <a href="#Page_96">96</a>.</span><br />
+
+<span style="margin-left: 2em;">Science,</span><br />
+<span style="margin-left: 3em;">advance of, due to mechanical inventions, <a href="#Page_22">22</a>;</span><br />
+<span style="margin-left: 3em;">astronomy beginning with, <a href="#Page_10">10</a>;</span><br />
+<span style="margin-left: 3em;">chemical, characteristics of, <a href="#Page_14">14</a>;</span><br />
+<span style="margin-left: 3em;">conflict between religion and, <a href="#Page_20">20</a>, <a href="#Page_22">22</a>;</span><br />
+<span style="margin-left: 3em;">conflict between the Roman faith and, <a href="#Page_20">20</a>;</span><br />
+<span style="margin-left: 3em;">mechanical inventions as aids to, <a href="#Page_22">22</a>, <a href="#Page_23">23</a>;</span><br />
+<span style="margin-left: 3em;">modern and ancient, <a href="#Page_4">4</a>;</span><br />
+<span style="margin-left: 3em;">natural, <a href="#Page_5">5</a>, <a href="#Page_6">6</a>;</span><br />
+<span style="margin-left: 3em;">of botany in Aristotle's time, <a href="#Page_14">14</a>;</span><br />
+<span style="margin-left: 3em;">of physiology, <a href="#Page_15">15</a>;</span><br />
+<span style="margin-left: 3em;">of zo&ouml;logy in Aristotle's time, <a href="#Page_14">14</a>;</span><br />
+<span style="margin-left: 3em;">resting practically on sight, <a href="#Page_10">10</a>.</span><br />
+
+<span style="margin-left: 2em;">Scientific development,</span><br />
+<span style="margin-left: 3em;">historic outlines of, <a href="#Page_17">17</a>;</span><br />
+<span style="margin-left: 3em;">tools used in measuring and weighing, as an aid to vision, <a href="#Page_12">12</a>.</span><br />
+
+<span style="margin-left: 2em;">Sea,</span><br />
+<span style="margin-left: 3em;">battering action of the, <a href="#Page_140">140</a>;</span><br />
+<span style="margin-left: 3em;">coast ever changing, <a href="#Page_385">385</a>, <a href="#Page_386">386</a>;</span><br />
+<span style="margin-left: 3em;">effect of volcanic eruptions on the, <a href="#Page_299">299</a>;</span><br />
+<span style="margin-left: 3em;">floor deposits of the, affected by volcanoes, <a href="#Page_360">360</a>, <a href="#Page_361">361</a>;</span><br />
+<span style="margin-left: 3em;">in receipt of organic and mineral matter, <a href="#Page_359">359</a>;</span><br />
+<span style="margin-left: 3em;">hot and cold currents of the, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">littoral zone of the, <a href="#Page_351">351</a>, <a href="#Page_352">352</a>;</span><br />
+<span style="margin-left: 3em;">puss, <a href="#Page_142">142</a>;</span><br />
+<span style="margin-left: 3em;">rich in organic life, <a href="#Page_352">352</a>, <a href="#Page_353">353</a>;</span><br />
+<span style="margin-left: 3em;">solvent action of the, <a href="#Page_361">361</a>;</span><br />
+<span style="margin-left: 3em;">strata, formation of, <a href="#Page_354">354</a>;</span><br />
+<span style="margin-left: 3em;">water, minerals in, <a href="#Page_185">185</a>;</span><br />
+<span style="margin-left: 3em;">weeds, <a href="#Page_155">155</a>, <a href="#Page_156">156</a>.</span><br />
+
+<span style="margin-left: 2em;">Seas, dead,</span><br />
+<span style="margin-left: 3em;">originally living lakes, <a href="#Page_200">200</a>;</span><br />
+<span style="margin-left: 3em;">water of, buoyant, <a href="#Page_199">199</a>;</span><br />
+<span style="margin-left: 3em;">eventually the seat of salt deposits, <a href="#Page_199">199</a>-<a href="#Page_201">201</a>;</span><br />
+<span style="margin-left: 3em;">general statement as to division of, <a href="#Page_83">83</a>, <a href="#Page_84">84</a>;</span><br />
+<span style="margin-left: 3em;">shape of the, <a href="#Page_83">83</a>, <a href="#Page_84">84</a>.</span><br />
+
+<span style="margin-left: 2em;">Seashore, air of the, <a href="#Page_98">98</a>.</span><br />
+
+<span style="margin-left: 2em;">Seasons, changing the character of the, <a href="#Page_61">61</a>, <a href="#Page_62">62</a>.</span><br />
+
+<span style="margin-left: 2em;">Sense of hearing, <a href="#Page_9">9</a>, <a href="#Page_10">10</a>;</span><br />
+<span style="margin-left: 3em;">of sight, <a href="#Page_10">10</a>;</span><br />
+<span style="margin-left: 3em;">of smell, <a href="#Page_9">9</a>, <a href="#Page_10">10</a>;</span><br />
+<span style="margin-left: 3em;">of taste, <a href="#Page_9">9</a>, <a href="#Page_10">10</a>;</span><br />
+<span style="margin-left: 3em;">of touch, <a href="#Page_9">9</a>, <a href="#Page_10">10</a>.</span><br />
+
+<span style="margin-left: 2em;"><i>Seracs</i>, <a href="#Page_214">214</a>.</span><br />
+
+<span style="margin-left: 2em;">Shocks, earthquake. See under <span class="smcap">Earthquakes</span>.</span><br />
+
+<span style="margin-left: 2em;">Shore lines, variation of, <a href="#Page_83">83</a>, <a href="#Page_84">84</a>.</span><br />
+
+<span style="margin-left: 2em;">Shores, cliff, <a href="#Page_138">138</a>-<a href="#Page_142">142</a>.</span><br />
+
+<span style="margin-left: 2em;">Sink holes, <a href="#Page_202">202</a>;</span><br />
+<span style="margin-left: 3em;">in limestone districts, <a href="#Page_253">253</a>, <a href="#Page_254">254</a>.</span><br />
+
+<span style="margin-left: 2em;">Skaptar,</span><br />
+<span style="margin-left: 3em;">eruption of, <a href="#Page_297">297</a>, <a href="#Page_298">298</a>;</span><br />
+<span style="margin-left: 3em;">lava from the eruption of, <a href="#Page_298">298</a>.</span><br />
+
+<span style="margin-left: 2em;">Sky, mackerel, <a href="#Page_35">35</a>.</span><br />
+
+<span style="margin-left: 2em;">Snow, <a href="#Page_207">207</a>-<a href="#Page_225">225</a>, <a href="#Page_244">244</a>;</span><br />
+<span style="margin-left: 3em;">as an evidence of atmosphere, <a href="#Page_65">65</a>;</span><br />
+<span class='pagenum'><a name="Page_415" id="Page_415">[Pg 415]</a></span>
+<span style="margin-left: 3em;">blankets, early flowers beginning to blossom under, <a href="#Page_208">208</a>;</span><br />
+<span style="margin-left: 3em;">covering, difference between an annual and perennial, <a href="#Page_210">210</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on plants, <a href="#Page_208">208</a>;</span><br />
+<span style="margin-left: 3em;">electrical action in the formation of rain and, <a href="#Page_164">164</a>;</span><br />
+<span style="margin-left: 3em;">flakes, formation of, <a href="#Page_164">164</a>;</span><br />
+<span style="margin-left: 3em;">red, <a href="#Page_210">210</a>;</span><br />
+<span style="margin-left: 3em;">slides, <a href="#Page_210">210</a>;</span><br />
+<span style="margin-left: 3em;">slides, phenomena of, <a href="#Page_210">210</a>, <a href="#Page_211">211</a>.</span><br />
+
+<span style="margin-left: 2em;">Soil,</span><br />
+<span style="margin-left: 3em;">alluvial, <a href="#Page_321">321</a>, <a href="#Page_322">322</a>;</span><br />
+<span style="margin-left: 3em;">atmospheric circulation of, <a href="#Page_330">330</a>, <a href="#Page_331">331</a>;</span><br />
+<span style="margin-left: 3em;">conditions leading to formation of, <a href="#Page_313">313</a>, <a href="#Page_331">331</a>;</span><br />
+<span style="margin-left: 3em;">continuous motion of the, <a href="#Page_314">314</a>;</span><br />
+<span style="margin-left: 3em;">covering of the earth, <a href="#Page_343">343</a>;</span><br />
+<span style="margin-left: 3em;">decay of the, <a href="#Page_314">314</a>, <a href="#Page_315">315</a>;</span><br />
+<span style="margin-left: 3em;">degradation of the, <a href="#Page_344">344</a>-<a href="#Page_348">348</a>;</span><br />
+<span style="margin-left: 3em;">means for correcting, <a href="#Page_346">346</a>-<a href="#Page_348">348</a>;</span><br />
+<span style="margin-left: 3em;">destruction in grain fields greater than the accumulation, <a href="#Page_344">344</a>;</span><br />
+<span style="margin-left: 3em;">developing on lava and ashes an interesting study, <a href="#Page_343">343</a>;</span><br />
+<span style="margin-left: 3em;">development of, in desert regions, <a href="#Page_340">340</a>;</span><br />
+<span style="margin-left: 3em;">effect of animals and plants on the, <a href="#Page_317">317</a>-<a href="#Page_320">320</a>;</span><br />
+<span style="margin-left: 3em;">effect of earthquakes on the, <a href="#Page_375">375</a>;</span><br />
+<span style="margin-left: 3em;">fertility of the, distinguished from the coating, <a href="#Page_344">344</a>, <a href="#Page_345">345</a>;</span><br />
+<span style="margin-left: 3em;">fertility of, affected by rain, <a href="#Page_327">327</a>;</span><br />
+<span style="margin-left: 3em;">formation of, <a href="#Page_314">314</a>-<a href="#Page_321">321</a>;</span><br />
+<span style="margin-left: 3em;">glacial, characteristics of, <a href="#Page_324">324</a>;</span><br />
+<span style="margin-left: 3em;">glaciated, <a href="#Page_323">323</a>, <a href="#Page_324">324</a>;</span><br />
+<span style="margin-left: 3em;">irrigation of the, <a href="#Page_328">328</a>-<a href="#Page_330">330</a>;</span><br />
+<span style="margin-left: 3em;">local variation of, <a href="#Page_327">327</a>;</span><br />
+<span style="margin-left: 3em;">mineral, <a href="#Page_321">321</a>;</span><br />
+<span style="margin-left: 3em;">of arid regions fertile when subjected to irrigation, <a href="#Page_341">341</a>;</span><br />
+<span style="margin-left: 3em;">of dust or blown sand, <a href="#Page_321">321</a>;</span><br />
+<span style="margin-left: 3em;">of immediate derivation, <a href="#Page_321">321</a>, <a href="#Page_322">322</a>;</span><br />
+<span style="margin-left: 3em;">phenomena, <a href="#Page_313">313</a>;</span><br />
+<span style="margin-left: 3em;">processes of organic life in the, <a href="#Page_315">315</a>;</span><br />
+<span style="margin-left: 3em;">variation in, <a href="#Page_321">321</a>-<a href="#Page_331">331</a>;</span><br />
+<span style="margin-left: 3em;">vegetation protecting the, <a href="#Page_316">316</a>, <a href="#Page_317">317</a>;</span><br />
+<span style="margin-left: 3em;">washing away of the, <a href="#Page_346">346</a>, <a href="#Page_347">347</a>;</span><br />
+<span style="margin-left: 3em;">winning, from the sea, <a href="#Page_337">337</a>;</span><br />
+<span style="margin-left: 3em;">work of ants on the, <a href="#Page_318">318</a>;</span><br />
+<span style="margin-left: 3em;">tiller, duty of the, <a href="#Page_348">348</a>.</span><br />
+
+<span style="margin-left: 2em;">Solar bodies,</span><br />
+<span style="margin-left: 3em;">general conditions of the, <a href="#Page_63">63</a>-<a href="#Page_71">71</a>;</span><br />
+<span style="margin-left: 3em;">forces, action of, on the earth, <a href="#Page_349">349</a>;</span><br />
+<span style="margin-left: 3em;">system, <a href="#Page_52">52</a>, <a href="#Page_56">56</a>;</span><br />
+<span style="margin-left: 3em;">independent from the fixed stars system, <a href="#Page_43">43</a>;</span><br />
+<span style="margin-left: 3em;">original vapour of, <a href="#Page_52">52</a>, <a href="#Page_53">53</a>;</span><br />
+<span style="margin-left: 3em;">singular features of our, <a href="#Page_68">68</a>;</span><br />
+<span style="margin-left: 3em;">tide, <a href="#Page_127">127</a>.</span><br />
+
+<span style="margin-left: 2em;">Spheres,</span><br />
+<span style="margin-left: 3em;">difference in magnitude of, <a href="#Page_51">51</a>;</span><br />
+<span style="margin-left: 3em;">motions of the, <a href="#Page_50">50</a>, <a href="#Page_51">51</a>;</span><br />
+<span style="margin-left: 3em;">planetary, rotation of, on their axes, <a href="#Page_56">56</a>.</span><br />
+
+<span style="margin-left: 2em;">Spots, sun, <a href="#Page_72">72</a>.</span><br />
+
+<span style="margin-left: 2em;">Spouting horn, <a href="#Page_141">141</a>.</span><br />
+
+<span style="margin-left: 2em;">Springs, formation of small, <a href="#Page_252">252</a>.</span><br />
+
+<span style="margin-left: 2em;">Stalactitization, <a href="#Page_256">256</a>.</span><br />
+
+<span style="margin-left: 2em;">Stalagmites and stalactites on the roof and floor of a cavern, <a href="#Page_257">257</a>.</span><br />
+
+<span style="margin-left: 2em;">Stars as dark bodies in the heavens, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">discovery of Fraunhofer and others on, <a href="#Page_23">23</a>, <a href="#Page_38">38</a>;</span><br />
+<span style="margin-left: 3em;">double, <a href="#Page_39">39</a>;</span><br />
+<span style="margin-left: 3em;">and tidal action, <a href="#Page_131">131</a>;</span><br />
+<span style="margin-left: 3em;">earliest study of, <a href="#Page_10">10</a>;</span><br />
+<span style="margin-left: 3em;">fixed, important observations by the ancients of planets and, <a href="#Page_43">43</a>;</span><br />
+<span style="margin-left: 3em;">not isolated suns, <a href="#Page_38">38</a>, <a href="#Page_39">39</a>;</span><br />
+<span style="margin-left: 3em;">variation in the light of, <a href="#Page_46">46</a>;</span><br />
+<span style="margin-left: 3em;">limit of, seen by the naked eye, <a href="#Page_11">11</a>;</span><br />
+<span style="margin-left: 3em;">revolution of one star about another, <a href="#Page_46">46</a>, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">shooting, <a href="#Page_47">47</a>;</span><br />
+<span style="margin-left: 3em;">speed of certain, <a href="#Page_51">51</a>;</span><br />
+<span style="margin-left: 3em;">study of, <a href="#Page_31">31</a>-<a href="#Page_80">80</a>;</span><br />
+<span style="margin-left: 3em;">sudden flashing forth of, due to catastrophe, <a href="#Page_46">46</a>;</span><br />
+<span style="margin-left: 3em;">voyage through the, <a href="#Page_44">44</a>, <a href="#Page_45">45</a>;</span><br />
+<span style="margin-left: 3em;">star, wandering, <a href="#Page_74">74</a>.</span><br />
+
+<span style="margin-left: 2em;">Stellar realm, <a href="#Page_31">31</a>-<a href="#Page_80">80</a>.</span><br />
+
+<span style="margin-left: 2em;">Storms,</span><br />
+<span style="margin-left: 3em;">circular, <a href="#Page_111">111</a>;</span><br />
+<span style="margin-left: 3em;">desert, <a href="#Page_121">121</a>, <a href="#Page_122">122</a>;</span><br />
+<span style="margin-left: 3em;">expansion of air contained in a hollow wall during the passage of, <a href="#Page_114">114</a>;</span><br />
+<span style="margin-left: 3em;">great principle of, <a href="#Page_105">105</a>, <a href="#Page_106">106</a>;</span><br />
+<span style="margin-left: 3em;">in the Sahara, <a href="#Page_121">121</a>;</span><br />
+<span style="margin-left: 3em;">lightning, more frequent in summer, <a href="#Page_167">167</a>;</span><br />
+<span style="margin-left: 3em;">paths of, <a href="#Page_115">115</a>;</span><br />
+<span style="margin-left: 3em;">secondary, of cyclones, <a href="#Page_112">112</a>;</span><br />
+<span style="margin-left: 3em;">spinning, <a href="#Page_115">115</a>;</span><br />
+<span style="margin-left: 3em;">thunder, <a href="#Page_165">165</a>-<a href="#Page_167">167</a>;</span><br />
+<span style="margin-left: 3em;">whirling, <a href="#Page_106">106</a>, <a href="#Page_124">124</a>;</span><br />
+<span style="margin-left: 3em;">whirling peculiarity of, <a href="#Page_108">108</a>, <a href="#Page_109">109</a>.</span><br />
+
+<span style="margin-left: 2em;">Strabo, writings of, <a href="#Page_18">18</a>.</span><br />
+
+<span style="margin-left: 2em;">Sun,</span><br />
+<span style="margin-left: 3em;">atmosphere of the, <a href="#Page_73">73</a>;</span><br />
+<span style="margin-left: 3em;">constitution of the, <a href="#Page_72">72</a>;</span><br />
+<span style="margin-left: 3em;">distance of the earth from the, <a href="#Page_29">29</a>;</span><br />
+<span style="margin-left: 3em;">effect from changes in the, and earth, <a href="#Page_59">59</a>;</span><br />
+<span style="margin-left: 3em;">envelope of the, <a href="#Page_73">73</a>, <a href="#Page_74">74</a>, <a href="#Page_97">97</a>;</span><br />
+<span style="margin-left: 3em;">experiments illustrating consolidation of disseminated materials of planets and, <a href="#Page_40">40</a>;</span><br />
+<span style="margin-left: 3em;">finally, dark and cold, <a href="#Page_42">42</a>;</span><br />
+<span style="margin-left: 3em;">formation of the eight planets of the, <a href="#Page_53">53</a>;</span><br />
+<span style="margin-left: 3em;">heat leaving the, <a href="#Page_41">41</a>;</span><br />
+<span style="margin-left: 3em;">heat of the, <a href="#Page_76">76</a>;</span><br />
+<span style="margin-left: 3em;">imaginary journey from the, into space, <a href="#Page_44">44</a>;</span><br />
+<span style="margin-left: 3em;">mass of the, <a href="#Page_76">76</a>, <a href="#Page_77">77</a>;</span><br />
+<span style="margin-left: 3em;">path of the earth around the, <a href="#Page_55">55</a>;</span><br />
+<span style="margin-left: 3em;">physical condition of the, <a href="#Page_71">71</a>;</span><br />
+<span style="margin-left: 3em;">Prof. Newcomb's belief regarding the heat of the, <a href="#Page_52">52</a>;</span><br />
+<span class='pagenum'><a name="Page_416" id="Page_416">[Pg 416]</a></span>
+<span style="margin-left: 3em;">spots, <a href="#Page_75">75</a>;</span><br />
+<span style="margin-left: 4em;">abundant at certain intervals, <a href="#Page_72">72</a>;</span><br />
+<span style="margin-left: 4em;">difficulty in revealing cause of, <a href="#Page_75">75</a>;</span><br />
+<span style="margin-left: 3em;">structure of the, a problem before the use of the telescope, <a href="#Page_72">72</a>;</span><br />
+<span style="margin-left: 3em;">table of relative masses of, and planets, <a href="#Page_77">77</a>;</span><br />
+<span style="margin-left: 3em;">three stages in the history of the, <a href="#Page_71">71</a>;</span><br />
+<span style="margin-left: 3em;">tides, <a href="#Page_126">126</a>;</span><br />
+<span style="margin-left: 3em;">why does it not act in the same manner as the moon? <a href="#Page_78">78</a>.</span><br />
+
+<span style="margin-left: 2em;">Surfaces, level, <a href="#Page_90">90</a>.</span><br />
+
+<span style="margin-left: 2em;">Surf belt, swayings of the, <a href="#Page_137">137</a>.</span><br />
+
+<span style="margin-left: 2em;">Swamps,</span><br />
+<span style="margin-left: 3em;">diagram showing remains of, <a href="#Page_335">335</a>;</span><br />
+<span style="margin-left: 3em;">Dismal Swamp, <a href="#Page_95">95</a>, <a href="#Page_333">333</a>;</span><br />
+<span style="margin-left: 3em;">drainage of, <a href="#Page_334">334</a>, <a href="#Page_335">335</a>;</span><br />
+<span style="margin-left: 3em;">fresh-water, <a href="#Page_334">334</a>, <a href="#Page_335">335</a>;</span><br />
+<span style="margin-left: 3em;">phenomena of, <a href="#Page_167">167</a>, <a href="#Page_168">168</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Table-lands, <a href="#Page_91">91</a>.</span><br />
+
+<span style="margin-left: 2em;">Table of relative masses of sun and planets, <a href="#Page_77">77</a>.</span><br />
+
+<span style="margin-left: 2em;">Telescopes, <a href="#Page_11">11</a>, <a href="#Page_12">12</a>, <a href="#Page_45">45</a>;</span><br />
+<span style="margin-left: 3em;">first results of, <a href="#Page_72">72</a>;</span><br />
+<span style="margin-left: 3em;">power of, <a href="#Page_11">11</a>;</span><br />
+<span style="margin-left: 3em;">revelations of, <a href="#Page_45">45</a>.</span><br />
+
+<span style="margin-left: 2em;">Temperature,</span><br />
+<span style="margin-left: 3em;">effects of, produced by vibration, <a href="#Page_42">42</a>;</span><br />
+<span style="margin-left: 3em;">in the doldrum belt, <a href="#Page_118">118</a>;</span><br />
+<span style="margin-left: 3em;">of North America, <a href="#Page_118">118</a>;</span><br />
+<span style="margin-left: 3em;">of the Atlantic Ocean, <a href="#Page_118">118</a>.</span><br />
+
+<span style="margin-left: 2em;">Tempests, rate of, <a href="#Page_99">99</a>, <a href="#Page_100">100</a>.</span><br />
+
+<span style="margin-left: 2em;">Thunder, <a href="#Page_166">166</a>;</span><br />
+<span style="margin-left: 3em;">more pronounced in the mountains, <a href="#Page_166">166</a>.</span><br />
+
+<span style="margin-left: 2em;">Thunderstorms, <a href="#Page_165">165</a>, <a href="#Page_166">166</a>;</span><br />
+<span style="margin-left: 3em;">distribution of, <a href="#Page_166">166</a>, <a href="#Page_167">167</a>.</span><br />
+
+<span style="margin-left: 2em;">Tidal action,</span><br />
+<span style="margin-left: 3em;">recent studies of, <a href="#Page_131">131</a>, <a href="#Page_132">132</a>;</span><br />
+<span style="margin-left: 3em;">marshes of North America, <a href="#Page_340">340</a>.</span><br />
+
+<span style="margin-left: 2em;">Tides,</span><br />
+<span style="margin-left: 3em;">carving channels, <a href="#Page_129">129</a>;</span><br />
+<span style="margin-left: 3em;">effecting the earth's rotation, <a href="#Page_130">130</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on marine life, <a href="#Page_130">130</a>;</span><br />
+<span style="margin-left: 3em;">height of, <a href="#Page_128">128</a>, <a href="#Page_129">129</a>;</span><br />
+<span style="margin-left: 3em;">moon and sun, <a href="#Page_126">126</a>, <a href="#Page_127">127</a>;</span><br />
+<span style="margin-left: 3em;">normal run of the, <a href="#Page_127">127</a>;</span><br />
+<span style="margin-left: 3em;">production of, <a href="#Page_131">131</a>;</span><br />
+<span style="margin-left: 3em;">of the trade winds, <a href="#Page_150">150</a>;</span><br />
+<span style="margin-left: 3em;">solar, <a href="#Page_127">127</a>;</span><br />
+<span style="margin-left: 3em;">travelling of, <a href="#Page_127">127</a>, <a href="#Page_128">128</a>.</span><br />
+
+<span style="margin-left: 2em;">Tillage introducing air into the pores of the soil, <a href="#Page_331">331</a>.</span><br />
+
+<span style="margin-left: 2em;">Tornadoes, <a href="#Page_112">112</a>, <a href="#Page_113">113</a>, <a href="#Page_317">317</a>;</span><br />
+<span style="margin-left: 3em;">development of, <a href="#Page_113">113</a>;</span><br />
+<span style="margin-left: 3em;">effect of, on buildings, <a href="#Page_113">113</a>;</span><br />
+<span style="margin-left: 3em;">fiercest in North America, <a href="#Page_113">113</a>;</span><br />
+<span style="margin-left: 3em;">length of, <a href="#Page_115">115</a>;</span><br />
+<span style="margin-left: 3em;">resemblance of, to hurricanes, <a href="#Page_115">115</a>;</span><br />
+<span style="margin-left: 3em;">upsucking action of, <a href="#Page_114">114</a>, <a href="#Page_115">115</a>.</span><br />
+
+<span style="margin-left: 2em;">Torrents, <a href="#Page_177">177</a>-<a href="#Page_179">179</a>, <a href="#Page_204">204</a>.</span><br />
+
+<span style="margin-left: 2em;">Trade winds. See under <span class="smcap">Winds</span>.</span><br />
+
+<span style="margin-left: 2em;">Training in language,</span><br />
+<span style="margin-left: 3em;">diminishing visual memory, <a href="#Page_401">401</a>;</span><br />
+<span style="margin-left: 3em;">soldiers to measure distances, <a href="#Page_28">28</a>;</span><br />
+<span style="margin-left: 4em;">to measure intervals of time, <a href="#Page_28">28</a>;</span><br />
+<span style="margin-left: 3em;">for a naturalist, <a href="#Page_25">25</a>-<a href="#Page_29">29</a>.</span><br />
+
+<span style="margin-left: 2em;">Tunnels, natural, <a href="#Page_257">257</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Uranus, <a href="#Page_70">70</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Valley of Val del Bove formed from disturbances of Mount &AElig;tna, <a href="#Page_294">294</a>.</span><br />
+
+<span style="margin-left: 2em;">Valleys,</span><br />
+<span style="margin-left: 3em;">diversity in the form of river, <a href="#Page_188">188</a>-<a href="#Page_191">191</a>;</span><br />
+<span style="margin-left: 3em;">river, <a href="#Page_193">193</a>.</span><br />
+
+<span style="margin-left: 2em;">Vapour, <a href="#Page_156">156</a>, <a href="#Page_157">157</a>, <a href="#Page_159">159</a>, <a href="#Page_163">163</a>;</span><br />
+<span style="margin-left: 3em;">gravitative attraction of, <a href="#Page_34">34</a>, <a href="#Page_35">35</a>;</span><br />
+<span style="margin-left: 3em;">nebular theory of, <a href="#Page_52">52</a>, <a href="#Page_53">53</a>;</span><br />
+<span style="margin-left: 3em;">original, of the solar system, <a href="#Page_52">52</a>, <a href="#Page_53">53</a>.</span><br />
+
+<span style="margin-left: 2em;">Vegetation,</span><br />
+<span style="margin-left: 3em;">and dew, <a href="#Page_160">160</a>;</span><br />
+<span style="margin-left: 3em;">in a measure, independent of rain, <a href="#Page_160">160</a>;</span><br />
+<span style="margin-left: 3em;">protecting the soil, <a href="#Page_316">316</a>, <a href="#Page_317">317</a>.</span><br />
+
+<span style="margin-left: 2em;">Vein, diagram of a, <a href="#Page_260">260</a>.</span><br />
+
+<span style="margin-left: 2em;">Venus, <a href="#Page_64">64</a>, <a href="#Page_78">78</a>;</span><br />
+<span style="margin-left: 3em;">recent observations of, by Mr. Percival Lowell, <a href="#Page_64">64</a>.</span><br />
+
+<span style="margin-left: 2em;">Vesuvian system, study of the, <a href="#Page_285">285</a>.</span><br />
+
+<span style="margin-left: 2em;">Vesuvius. See <span class="smcap">Mount Vesuvius</span>.</span><br />
+
+<span style="margin-left: 2em;">Visualizing memories, <a href="#Page_402">402</a>, <a href="#Page_403">403</a>.</span><br />
+
+<span style="margin-left: 2em;">Volcanic action, <a href="#Page_268">268</a>-<a href="#Page_276">276</a>.</span><br />
+
+<span style="margin-left: 2em;">Volcanic eruption of <span class="smcap">a.d.</span> 79, <a href="#Page_288">288</a>;</span><br />
+<span style="margin-left: 3em;">important facts concerning, <a href="#Page_276">276</a>-<a href="#Page_279">279</a>;</span><br />
+<span style="margin-left: 3em;">islands, <a href="#Page_272">272</a>;</span><br />
+<span style="margin-left: 3em;">lava a primary feature in, <a href="#Page_266">266</a>;</span><br />
+<span style="margin-left: 3em;">observations of, made from a balloon, <a href="#Page_301">301</a>;</span><br />
+<span style="margin-left: 3em;">peaks along the floor of the sea, <a href="#Page_272">272</a>, <a href="#Page_273">273</a>;</span><br />
+<span style="margin-left: 3em;">possibility of throwing matter beyond control of gravitative energy, <a href="#Page_300">300</a>.</span><br />
+<span class='pagenum'><a name="Page_417" id="Page_417">[Pg 417]</a></span>
+<span style="margin-left: 2em;">Volcanoes, <a href="#Page_125">125</a>, <a href="#Page_203">203</a>, <a href="#Page_263">263</a>;</span><br />
+<span style="margin-left: 3em;">abounding on the sea floor, <a href="#Page_302">302</a>;</span><br />
+<span style="margin-left: 3em;">accidents from eruptions of, <a href="#Page_288">288</a>;</span><br />
+<span style="margin-left: 3em;">along the Pacific coast, <a href="#Page_271">271</a>;</span><br />
+<span style="margin-left: 3em;">ash showers of, maintaining fertility of the soil, <a href="#Page_289">289</a>;</span><br />
+<span style="margin-left: 3em;">distribution of, <a href="#Page_271">271</a>;</span><br />
+<span style="margin-left: 3em;">eruption of, <a href="#Page_286">286</a>-<a href="#Page_294">294</a>, <a href="#Page_368">368</a>;</span><br />
+<span style="margin-left: 3em;">explosions from, coming from a supposed liquid interior of the earth, <a href="#Page_275">275</a>;</span><br />
+<span style="margin-left: 3em;">exporting earth material, <a href="#Page_310">310</a>;</span><br />
+<span style="margin-left: 3em;">little water, <a href="#Page_375">375</a>;</span><br />
+<span style="margin-left: 3em;">Italian, considered collectively, <a href="#Page_296">296</a>, <a href="#Page_297">297</a>;</span><br />
+<span style="margin-left: 3em;">Neapolitan eruptions of and the history of civilization, <a href="#Page_288">288</a>;</span><br />
+<span style="margin-left: 3em;">subsidence of the earth after eruption of, <a href="#Page_287">287</a>, <a href="#Page_291">291</a>;</span><br />
+<span style="margin-left: 3em;">origin of, <a href="#Page_263">263</a>-<a href="#Page_274">274</a>;</span><br />
+<span style="margin-left: 3em;">phenomena of, <a href="#Page_263">263</a>-<a href="#Page_267">267</a>;</span><br />
+<span style="margin-left: 3em;">submarine, <a href="#Page_301">301</a>;</span><br />
+<span style="margin-left: 3em;">travelling of ejections from, <a href="#Page_287">287</a>, <a href="#Page_288">288</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Waters,</span><br />
+<span style="margin-left: 3em;">crevice, <a href="#Page_250">250</a>;</span><br />
+<span style="margin-left: 4em;">of the earth, <a href="#Page_250">250</a>, <a href="#Page_251">251</a>;</span><br />
+<span style="margin-left: 3em;">cutting action of, <a href="#Page_117">117</a>, <a href="#Page_192">192</a>;</span><br />
+<span style="margin-left: 3em;">drift, from the poles, <a href="#Page_151">151</a>;</span><br />
+<span style="margin-left: 3em;">journey of, from the Arctic Circle to the tropics, <a href="#Page_151">151</a>, <a href="#Page_152">152</a>;</span><br />
+<span style="margin-left: 3em;">dynamic value of, <a href="#Page_171">171</a>;</span><br />
+<span style="margin-left: 3em;">expansion of, in rocks, <a href="#Page_270">270</a>;</span><br />
+<span style="margin-left: 3em;">geological work of, <a href="#Page_168">168</a>-<a href="#Page_206">206</a>;</span><br />
+<span style="margin-left: 3em;">in air, <a href="#Page_99">99</a>;</span><br />
+<span style="margin-left: 3em;">of the clouds usually frozen, <a href="#Page_207">207</a>;</span><br />
+<span style="margin-left: 3em;">pure, no power for cutting rocks, <a href="#Page_204">204</a>;</span><br />
+<span style="margin-left: 3em;">rock, <a href="#Page_250">250</a>, <a href="#Page_263">263</a>;</span><br />
+<span style="margin-left: 3em;">sea, minerals in, <a href="#Page_185">185</a>;</span><br />
+<span style="margin-left: 3em;">store of the earth, <a href="#Page_125">125</a>;</span><br />
+<span style="margin-left: 3em;">system of, <a href="#Page_125">125</a>, <a href="#Page_156">156</a>;</span><br />
+<span style="margin-left: 3em;">tropical, <a href="#Page_151">151</a>;</span><br />
+<span style="margin-left: 3em;">velocity of the, under the equator, <a href="#Page_150">150</a>;</span><br />
+<span style="margin-left: 3em;">wearing away rocks, <a href="#Page_178">178</a>, <a href="#Page_179">179</a>;</span><br />
+<span style="margin-left: 3em;">underground, carrying mineral matter to the sea, <a href="#Page_193">193</a>;</span><br />
+<span style="margin-left: 3em;">chemical changes of, leading to changes in rock material, <a href="#Page_262">262</a>, <a href="#Page_263">263</a>;</span><br />
+<span style="margin-left: 3em;">effect of carbonic-acid gas on, <a href="#Page_251">251</a>;</span><br />
+<span style="margin-left: 3em;">operations of the, <a href="#Page_126">126</a>;</span><br />
+<span style="margin-left: 3em;">wearing away rocks, <a href="#Page_178">178</a>, <a href="#Page_179">179</a>;</span><br />
+<span style="margin-left: 3em;">work of, <a href="#Page_250">250</a>.</span><br />
+
+<span style="margin-left: 2em;">Waterfalls, <a href="#Page_189">189</a>-<a href="#Page_193">193</a>;</span><br />
+<span style="margin-left: 3em;">cause of, <a href="#Page_191">191</a>;</span><br />
+<span style="margin-left: 3em;">the Yosemite, <a href="#Page_192">192</a>;</span><br />
+<span style="margin-left: 3em;">Niagara, <a href="#Page_191">191</a>, <a href="#Page_192">192</a>;</span><br />
+<span style="margin-left: 3em;">numerous in the torrent district of rivers, <a href="#Page_192">192</a>;</span><br />
+<span style="margin-left: 3em;">produced by dikes, <a href="#Page_192">192</a>;</span><br />
+<span style="margin-left: 3em;">valuable to manufactures, <a href="#Page_192">192</a>, <a href="#Page_193">193</a>.</span><br />
+
+<span style="margin-left: 2em;">Waterspouts, <a href="#Page_115">115</a>, <a href="#Page_116">116</a>;</span><br />
+<span style="margin-left: 3em;">atmospheric cause of, <a href="#Page_116">116</a>;</span><br />
+<span style="margin-left: 3em;">firing at, <a href="#Page_116">116</a>;</span><br />
+<span style="margin-left: 3em;">life of a, <a href="#Page_116">116</a>;</span><br />
+<span style="margin-left: 3em;">picturesqueness of, <a href="#Page_116">116</a>;</span><br />
+<span style="margin-left: 3em;">the water of fresh, <a href="#Page_117">117</a>.</span><br />
+
+<span style="margin-left: 2em;">Waves, <a href="#Page_128">128</a>, <a href="#Page_129">129</a>, <a href="#Page_132">132</a>, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">action of friction on, <a href="#Page_135">135</a>, <a href="#Page_136">136</a>;</span><br />
+<span style="margin-left: 3em;">break of the, <a href="#Page_136">136</a>;</span><br />
+<span style="margin-left: 3em;">endurance of sand against the, <a href="#Page_145">145</a>;</span><br />
+<span style="margin-left: 3em;">force of, <a href="#Page_133">133</a>, <a href="#Page_136">136</a>, <a href="#Page_139">139</a>;</span><br />
+<span style="margin-left: 3em;">marine, caused by earthquakes, <a href="#Page_387">387</a>;</span><br />
+<span style="margin-left: 3em;">of earthquakes, <a href="#Page_389">389</a>;</span><br />
+<span style="margin-left: 3em;">peculiar features in the action of, <a href="#Page_137">137</a>;</span><br />
+<span style="margin-left: 3em;">size of, <a href="#Page_137">137</a>, <a href="#Page_138">138</a>;</span><br />
+<span style="margin-left: 3em;">stroke of the, <a href="#Page_144">144</a>;</span><br />
+<span style="margin-left: 3em;">surf, <a href="#Page_135">135</a>;</span><br />
+<span style="margin-left: 3em;">tidal height of, <a href="#Page_132">132</a>;</span><br />
+<span style="margin-left: 3em;">undulations of, <a href="#Page_132">132</a>;</span><br />
+<span style="margin-left: 3em;">wind, <a href="#Page_132">132</a>;</span><br />
+<span style="margin-left: 3em;">wind influence of, on the sea, <a href="#Page_134">134</a>, <a href="#Page_135">135</a>;</span><br />
+<span style="margin-left: 3em;">wind-made, <a href="#Page_128">128</a>.</span><br />
+
+<span style="margin-left: 2em;">Ways and means of studying Nature, <a href="#Page_9">9</a>.</span><br />
+
+<span style="margin-left: 2em;">Weeds of the sea, <a href="#Page_155">155</a>.</span><br />
+
+<span style="margin-left: 2em;">Well, artesian, <a href="#Page_258">258</a>, <a href="#Page_259">259</a>.</span><br />
+
+<span style="margin-left: 2em;">Whirling of fluids and gas, <a href="#Page_36">36</a>, <a href="#Page_37">37</a>.</span><br />
+
+<span style="margin-left: 2em;">Whirlwinds in Sahara, <a href="#Page_121">121</a>.</span><br />
+
+<span style="margin-left: 2em;">Will-o'-the-wisp, <a href="#Page_167">167</a>.</span><br />
+
+<span style="margin-left: 2em;">Winds, <a href="#Page_101">101</a>, <a href="#Page_110">110</a>, <a href="#Page_122">122</a>, <a href="#Page_317">317</a>;</span><br />
+<span style="margin-left: 3em;">effect of sand, <a href="#Page_122">122</a>;</span><br />
+<span style="margin-left: 3em;">hurricane, <a href="#Page_110">110</a>;</span><br />
+<span style="margin-left: 3em;">illustration of how they are produced, <a href="#Page_101">101</a>;</span><br />
+<span style="margin-left: 3em;">in Martha's Vineyard, <a href="#Page_120">120</a>;</span><br />
+<span style="margin-left: 3em;">of the forests, work of the, <a href="#Page_317">317</a>;</span><br />
+<span style="margin-left: 3em;">of tornadoes, effect of, <a href="#Page_113">113</a>;</span><br />
+<span style="margin-left: 3em;">on the island of Jamaica, <a href="#Page_119">119</a>, <a href="#Page_120">120</a>;</span><br />
+<span style="margin-left: 3em;">regimen of the, <a href="#Page_119">119</a>;</span><br />
+<span style="margin-left: 3em;">variable falling away in the nighttime, <a href="#Page_100">100</a>;</span><br />
+<span style="margin-left: 3em;">trade, <a href="#Page_102">102</a>-<a href="#Page_105">105</a>; <a href="#Page_145">145</a>, <a href="#Page_146">146</a>, <a href="#Page_150">150</a>;</span><br />
+<span style="margin-left: 3em;">action of, on ocean currents, <a href="#Page_145">145</a>:</span><br />
+<span style="margin-left: 3em;">affected by motion of the earth, <a href="#Page_103">103</a>;</span><br />
+<span style="margin-left: 3em;">belt, motion of the ocean in, <a href="#Page_146">146</a>;</span><br />
+<span style="margin-left: 3em;">flow and counter-flow of the, <a href="#Page_150">150</a>;</span><br />
+<span style="margin-left: 3em;">tide of the, <a href="#Page_150">150</a>;</span><br />
+<span style="margin-left: 3em;">uniform condition of the, <a href="#Page_102">102</a>;</span><br />
+<span style="margin-left: 3em;">waves, work of, <a href="#Page_132">132</a>, <a href="#Page_134">134</a>, <a href="#Page_135">135</a>.</span><br />
+
+<span style="margin-left: 2em;">Witchcraft, belief of, in the early ages, <a href="#Page_21">21</a>.</span><br />
+
+
+<span style="margin-left: 2em;">Zo&ouml;logy, rapid advance in, <a href="#Page_14">14</a>, <a href="#Page_15">15</a>.</span><br />
+</p>
+<hr style="width: 45%"/>
+
+<div class="footnote"><p><a name="Footnote_1_1" id="Footnote_1_1"></a><a href="#FNanchor_1_1"><span class="label">[1]</span></a> Some astronomers, particularly the distinguished Professor
+Newcomb, hold that the sun can not have been supplying heat as at
+present for more than about ten million years, and that all geological
+time must be thus limited. The geologist believes that this reckoning is
+far too short.</p></div>
+
+
+<div class="footnote"><p><a name="Footnote_2_2" id="Footnote_2_2"></a><a href="#FNanchor_2_2"><span class="label">[2]</span></a> See Newcomb's Popular Astronomy, p. 234. Harper Brothers,
+New York.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_3" id="Footnote_3_3"></a><a href="#FNanchor_3_3"><span class="label">[3]</span></a> The present writer has made an extended and careful study
+of marsh and swamp phenomena, and is very familiar with the aspect of
+these fields in the nighttime. He has never been able to see any sign of
+the Jack-o'-lantern light. Looking fixedly into any darkness, such as is
+afforded by the depths of a wood, the eye is apt to imagine the
+appearance of faint lights. Those who have had to do with outpost duty
+in an army know how the anxious sentry, particularly if he is new to the
+soldier's trade, will often imagine that he sees lights before him.
+Sometimes the pickets will be so convinced of the fact that they see
+lights that they will fire upon the fiction of the imaginations. These
+facts make it seem probable that the Jack-o'-lantern and his companion,
+the Will-o'-the-wisp, are stories of the overcredulous.</p></div>
+
+
+<div class="footnote"><p><a name="Footnote_4_4" id="Footnote_4_4"></a><a href="#FNanchor_4_4"><span class="label">[4]</span></a> This principle of the spheroidal form in falling fluids is
+used in making ordinary bird shot. The melted lead drops through
+sievelike openings, the resulting spheres of the metal being allowed to
+fall into water which chills them. Iron shot, used in cutting stone,
+where they are placed between the saw and the surface of the rock, are
+also made in the same manner. The descending fluid divides into drops
+because it is drawn out by the ever-increasing speed of the falling
+particles, which soon make the stream so thin that it can not hold
+together.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_5" id="Footnote_5_5"></a><a href="#FNanchor_5_5"><span class="label">[5]</span></a> In some relatively rare cases salt deposits are formed in
+lagoons along the shores of arid lands, where the sea occasionally
+breaks over the beach into the basin, affording waters which are
+evaporated, leaving their salt behind them.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_6" id="Footnote_6_6"></a><a href="#FNanchor_6_6"><span class="label">[6]</span></a> In certain fields of permanent snow, particularly near their
+boundaries, some very lowly forms of vegetable life may develop on a
+frozen surface, drawing their sustenance from the air, and supplied with
+water by the melting which takes place during the summertime. These
+forms include the rare phenomenon termed red snow.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_7" id="Footnote_7_7"></a><a href="#FNanchor_7_7"><span class="label">[7]</span></a> It is reported that one of these natural bridges of Carter
+County has recently fallen down. This is the natural end of these
+features. As before remarked, they are but the remnants of much more
+extensive roofs which the processes of decay have brought to ruin.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_8" id="Footnote_8_8"></a><a href="#FNanchor_8_8"><span class="label">[8]</span></a> I venture to use this word in place of the phrase
+"lava-yielding" for the reason that the term is needed in the
+description of volcanoes.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_9" id="Footnote_9_9"></a><a href="#FNanchor_9_9"><span class="label">[9]</span></a> In part the excellent record of Vesuvius is due to the fact
+that since the early Christian centuries the priests of St. Januarius,
+the patron of Naples, have been accustomed to carry his relics in
+procession whenever an eruption began. The cessation of the outbreak has
+been written down to the credit of the saint, and thus we are provided
+with a long story of the successive outbreaks.</p></div>
+
+
+
+
+
+
+
+
+
+<pre>
+
+
+
+
+
+End of the Project Gutenberg EBook of Outlines of the Earth's History, by 
+Nathaniel Southgate Shaler
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+The Project Gutenberg EBook of Outlines of the Earth's History, by
+Nathaniel Southgate Shaler
+
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever.  You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at www.gutenberg.org
+
+
+Title: Outlines of the Earth's History
+       A Popular Study in Physiography
+
+Author: Nathaniel Southgate Shaler
+
+Release Date: June 12, 2006 [EBook #18562]
+
+Language: English
+
+Character set encoding: ASCII
+
+*** START OF THIS PROJECT GUTENBERG EBOOK OUTLINES OF THE EARTH'S HISTORY ***
+
+
+
+
+Produced by Brendan Lane, Riikka Talonpoika, Jeroen van
+Luin and the Online Distributed Proofreading Team at
+http://www.pgdp.net
+
+
+
+
+
+[Illustration: _Dunes at Ipswich Light, Massachusetts. Note the
+effect of bushes in arresting the movement of the wind-blown sand._]
+
+
+
+
+                           OUTLINES OF THE
+                           EARTH'S HISTORY
+
+
+                           A POPULAR STUDY
+                           IN PHYSIOGRAPHY
+
+                                 BY
+
+                      NATHANIEL SOUTHGATE SHALER
+
+               PROFESSOR OF GEOLOGY IN HARVARD UNIVERSITY
+                   DEAN OF LAWRENCE SCIENTIFIC SCHOOL
+
+                        ILLUSTRATED WITH INDEX
+
+                          NEW YORK AND LONDON
+                        D. APPLETON AND COMPANY
+
+                              1898, 1910
+
+
+
+
+
+                               PREFACE.
+
+
+The object of this book is to provide the beginner in the study of the
+earth's history with a general account of those actions which can be
+readily understood and which will afford him clear understandings as
+to the nature of the processes which have made this and other
+celestial spheres. It has been the writer's purpose to select those
+series of facts which serve to show the continuous operations of
+energy, so that the reader might be helped to a truer conception of
+the nature of this sphere than he can obtain from ordinary text-books.
+
+In the usual method of presenting the elements of the earth's history
+the facts are set forth in a manner which leads the student to
+conceive that history as in a way completed. The natural prepossession
+to the effect that the visible universe represents something done,
+rather than something endlessly doing, is thus re-enforced, with the
+result that one may fail to gain the largest and most educative
+impression which physical science can afford him in the sense of the
+swift and unending procession of events.
+
+It is well known to all who are acquainted with the history of geology
+that the static conception of the earth--the idea that its existing
+condition is the finished product of forces no longer in action--led
+to prejudices which have long retarded, and indeed still retard, the
+progress of that science. This fact indicates that at the outset of a
+student's work in this field he should be guarded against such
+misconceptions. The only way to attain the end is by bringing to the
+understanding of the beginner a clear idea of successions of events
+which are caused by the forces operating in and on this sphere. Of all
+the chapters of this great story, that which relates to the history of
+the work done by the heat of the sun is the most interesting and
+awakening. Therefore an effort has been made to present the great
+successive steps by which the solar energy acts in the processes of
+the air and the waters.
+
+The interest of the beginner in geology is sure to be aroused when he
+comes to see how very far the history of the earth has influenced the
+fate of men. Therefore the aim has been, where possible, to show the
+ways in which geological processes and results are related to
+ourselves; how, in a word, this earth has been the well-appointed
+nursery of our kind.
+
+All those who are engaged in teaching elementary science learn the
+need of limiting the story they have to tell to those truths which can
+be easily understood by beginners. It is sometimes best, as in stating
+such difficult matters as those concerning the tides, to give
+explanations which are far from complete, and which, as to their mode
+of presentation, would be open to criticism were it not for the fact
+that any more elaborate statements would most likely be
+incomprehensible to the novice, thus defeating the teacher's aim.
+
+It will be observed that no account is here given of the geological
+ages or of the successions of organic life. Chapters on these subjects
+were prepared, but were omitted for the reason that they made the
+story too long, and also because they carried the reader into a field
+of much greater difficulty than that which is found in the physical
+history of the earth.
+
+                                                  N.S.S.
+_March, 1898._
+
+
+
+
+                            CONTENTS.
+
+
+    CHAPTER                                                   PAGE
+
+       I.--INTRODUCTION TO THE STUDY OF NATURE                   1
+      II.--WAYS AND MEANS OF STUDYING NATURE                     9
+     III.--THE STELLAR REALM                                    31
+      IV.--THE EARTH                                            81
+       V.--THE ATMOSPHERE                                       97
+      VI.--GLACIERS                                            207
+     VII.--THE WORK OF UNDERGROUND WATER                       250
+    VIII.--THE SOIL                                            313
+      IX.--THE ROCKS AND THEIR ORDER                           349
+
+
+
+
+                 LIST OF FULL-PAGE ILLUSTRATIONS.
+
+                                                        FACING PAGE
+
+    Dunes at Ipswich Light, Massachusetts            _Frontispiece_
+    Seal Rocks near San Francisco, California                   33
+    Lava stream, in Hawaiian Islands, flowing into the sea      72
+    Waterfall near Gadsden, Alabama                             90
+    South shore, Martha's Vineyard, Massachusetts              121
+    Pocket Creek, Cape Ann, Massachusetts                      163
+    Muir Glacier, Alaska                                       207
+    Front of Muir Glacier                                      240
+    Mount AEtna, seen from near Catania                         201
+    Mountain gorge, Himalayas, India                           330
+
+
+
+
+
+                   OUTLINES OF THE EARTH'S HISTORY.
+
+
+                             CHAPTER I.
+
+               AN INTRODUCTION TO THE STUDY OF NATURE.
+
+
+The object of this book is to give the student who is about to enter
+on the study of natural science some general idea as to the conditions
+of the natural realm. As this field of inquiry is vast, it will be
+possible only to give the merest outline of its subject-matter, noting
+those features alone which are of surpassing interest, which are
+demanded for a large understanding of man's place in this world, or
+which pertain to his duties in life.
+
+In entering on any field of inquiry, it is most desirable that the
+student should obtain some idea as to the ways in which men have been
+led to the knowledge which they possess concerning the world about
+them. Therefore it will be well briefly to sketch the steps by which
+natural science has come to be what it is. By so doing we shall
+perceive how much we owe to the students of other generations; and by
+noting the difficulties which they encountered, and how they avoided
+them, we shall more easily find our own way to knowledge.
+
+The primitive savages, who were the ancestors of all men, however
+civilized they may be, were students of Nature. The remnants of these
+lowly people who were left in different parts of the world show us
+that man was not long in existence before he began to devise some
+explanation concerning the course of events in the outer world.
+Seeing the sun rise and set, the changes of the moon, the alternation
+of the seasons, the incessant movement of the streams and sea, and the
+other more or less orderly successions of events, our primitive
+forefathers were driven to invent some explanation of them. This,
+independently, and in many different times and places, they did in a
+simple and natural way by supposing that the world was controlled by a
+host of intelligent beings, each of which had some part in ordering
+material things. Sometimes these invisible powers were believed to be
+the spirits of great chieftains, who were active when on earth, and
+who after death continued to exercise their power in the larger realms
+of Nature. Again, and perhaps more commonly, these movements of Nature
+were supposed to be due to the action of great though invisible
+beasts, much like those which the savage found about him. Thus among
+our North American Indians the winds are explained by the supposition
+that the air is fanned by the wings of a great unseen bird, whose duty
+it is to set the atmosphere into motion. That no one has ever seen the
+bird doing the work, or that the task is too great for any conceivable
+bird, is to the simple, uncultivated man no objection to this view. It
+is long, indeed, before education brings men to the point where they
+can criticise their first explanations of Nature.
+
+As men in their advance come to see how much nobler are their own
+natures than those of the lower animals, they gradually put aside the
+explanation of events by the actions of beasts, and account for the
+order of the world by the supposition that each and every important
+detail is controlled by some immortal creature essentially like a man,
+though much more powerful than those of their own kind. This stage of
+understanding is perhaps best shown by the mythology of the Greeks,
+where there was a great god over all, very powerful but not
+omnipotent; and beneath him, in endless successions of command,
+subordinate powers, each with a less range of duties and capacities
+than those of higher estate, until at the bottom of the system there
+were minor deities and demigods charged with the management of the
+trees, the flowers, and the springs--creatures differing little from
+man, except that they were immortal, and generally invisible, though
+they, like all the other deities, might at their will display
+themselves to the human beings over whom they watched, and whose path
+in life they guided.
+
+Among only one people do we find that the process of advance led
+beyond this early and simple method of accounting for the processes of
+Nature, bringing men to an understanding such as we now possess. This
+great task was accomplished by the Greeks alone. About twenty-five
+hundred years ago the philosophers of Greece began to perceive that
+the early notion as to the guidance of the world by creatures
+essentially like men could not be accepted, and must be replaced by
+some other view which would more effectively account for the facts.
+This end they attained by steps which can not well be related here,
+but which led them to suppose separate powers behind each of the
+natural series--powers having no relation to the qualities of mankind,
+but ever acting to a definite end. Thus Plato, who represents most
+clearly this advance in the interpretation of facts, imagined that
+each particular kind of plant or animal had its shape inevitably
+determined by something which he termed an idea, a shape-giving power
+which existed before the object was created, and which would remain
+after it had been destroyed, ever ready again to bring matter to the
+particular form. From this stage of understanding it was but a short
+step to the modern view of natural law. This last important advance
+was made by the great philosopher Aristotle, who, though he died about
+twenty-two hundred years ago, deserves to be accounted the first and
+in many ways the greatest of the ancient men of science who were
+informed with the modern spirit.
+
+With Aristotle, as with all his intellectual successors, the
+operations of Nature were conceived as to be accounted for by the
+action of forces which we commonly designate as natural laws, of which
+perhaps the most familiar and universal is that of gravitation, which
+impels all bodies to move toward each other with a degree of intensity
+which is measured by their weight and the distance by which they are
+separated.
+
+For many centuries students used the term law in somewhat the same way
+as the more philosophical believers in polytheism spoke of their gods,
+or as Plato of the ideas which he conceived to control Nature. We see
+by this instance how hard it is to get rid of old ways of thinking.
+Even when the new have been adopted we very often find that something
+of the ancient and discarded notions cling in our phrases. The more
+advanced of our modern philosophers are clear in their mind that all
+we know as to the order of Nature is that, given certain conditions,
+certain consequences inevitably follow.
+
+Although the limitations which modern men of science perceive to be
+put upon their labours may seem at first sight calculated to confine
+our understanding within a narrow field of things which can be seen,
+or in some way distinctly proved to exist, the effect of this
+limitation has been to make science what it is--a realm of things
+known as distinct from things which may be imagined. All the
+difference between ancient science and modern consists in the fact
+that in modern science inquirers demand a businesslike method in the
+interpretation of Nature. Among the Greeks the philosopher who taught
+explanations of any feature in the material world which interested him
+was content if he could imagine some way which would account for the
+facts. It is the modern custom now to term the supposition of an
+explanation a _working hypothesis_, and only to give it the name of
+theory after a very careful search has shown that all the facts which
+can be gathered are in accordance with the view. Thus when Newton made
+his great suggestion concerning the law of gravitation, which was to
+the effect that all bodies attracted each other in proportion to
+their masses, and inversely as the square of their distance from each
+other, he did not rest content, as the old Greeks would have done,
+with the probable truth of the explanation, but carefully explored the
+movements of the planets and satellites of the solar system to see if
+the facts accorded with the hypothesis. Even the perfect
+correspondence which he found did not entirely content inquirers, and
+in this century very important experiments have been made which have
+served to show that a ball suspended in front of a precipice will be
+attracted toward the steep, and that even a mass of lead some tons in
+weight will attract toward itself a small body suspended in the manner
+of a pendulum.
+
+It is this incessant revision of the facts, in order to see if they
+accord with the assumed rule or law, which has given modern science
+the sound footing that it lacked in earlier days, and which has
+permitted our learning to go on step by step in a safe way up the
+heights to which it has climbed. All explanations of Nature begin with
+the work of the imagination. In common phrase, they all are guesses
+which have at first but little value, and only attain importance in
+proportion as they are verified by long-continued criticism, which has
+for its object to see whether the facts accord with the theory. It is
+in this effort to secure proof that modern science has gathered the
+enormous store of well-ascertained facts which constitutes its true
+wealth, and which distinguishes it from the earlier imaginative and to
+a great extent unproved views.
+
+In the original state of learning, natural science was confounded with
+political and social tradition, with the precepts of duty which
+constitute the law of the people, as well as with their religion, the
+whole being in the possession of the priests or wise men. So long as
+natural action was supposed to be in the immediate control of numerous
+gods and demigods, so long, in a word, as the explanation of Nature
+was what we term polytheistic, this association of science with other
+forms of learning was not only natural but inevitable. Gradually,
+however, as the conception of natural law replaced the earlier idea as
+to the intervention of a spirit, science departed from other forms of
+lore and came to possess a field to itself. At first it was one body
+of learning. The naturalists of Aristotle's time, and from his day
+down to near our own, generally concerned themselves with the whole
+field of Nature. For a time it was possible for any one able and
+laborious man to know all which had been ascertained concerning
+astronomy, chemistry, geology, as well as the facts relating to living
+beings. The more, however, as observation accumulated, and the store
+of facts increased, it became difficult for any one man to know the
+whole. Hence it has come about that in our own time natural learning
+is divided into many distinct provinces, each of which demands a
+lifetime of labour from those who would know what has already been
+done in the field, and what it is now important to do in the way of
+new inquiries.
+
+The large divisions which naturalists have usually made of their tasks
+rest in the main on the natural partitions which we may readily
+observe in the phenomenal world. First of all comes astronomy,
+including the phenomena exhibited in the heavens, beyond the limits of
+the earth's atmosphere. Second, geology, which takes account of all
+those actions which in process of time have been developed in our own
+sphere. Third, physics, which is concerned with the laws of energy, or
+those conditions which affect the motion of bodies, and the changes
+which are impressed upon them by the different natural forces. Fourth,
+chemistry, which seeks to interpret the principles which determine the
+combination of atoms and the molecules which are built of them under
+the influence of the chemical affinities. Fifth, biology, or the laws
+of life, a study which pertains to the forms and structures of animals
+and plants, and their wonderful successions in the history of the
+world. Sixth, mathematics, or the science of space and number, that
+deals with the principles which underlie the order of Nature as
+expressed at once in the human understanding and in the material
+universe. By its use men were made able to calculate, as in
+arithmetic, the problems which concern their ordinary business, as
+well as to compute the movements of the celestial bodies, and a host
+of actions which take place on the earth that would be inexplicable
+except by the aid of this science. Last of all among the primary
+sciences we may name that of psychology, which takes account of mental
+operations among man and his lower kindred, the animals.
+
+In addition to the seven sciences above mentioned, which rest in a
+great measure on the natural divisions of phenomena, there are many,
+indeed, indefinitely numerous, subdivisions which have been made to
+suit the convenience of students. Thus astronomy is often separated
+into physical and mathematical divisions, which take account either of
+the physical phenomena exhibited by the heavenly bodies or of their
+motions. In geology there are half a dozen divisions relating to
+particular branches of that subject. In the realm of organic life, in
+chemistry, and in physics there are many parts of these sciences which
+have received particular names.
+
+It must not be supposed that these sciences have the independence of
+each other which their separate names would imply. In fact, the
+student of each, however, far he may succeed in separating his field
+from that of the other naturalists, as we may fitly term all students
+of Nature, is compelled from time to time to call in the aid of his
+brethren who cultivate other branches of learning. The modern
+astronomer needs to know much of chemistry, or else he can not
+understand many of his observations on the sun. The geologists have to
+share their work with the student of animal and vegetable life, with
+the physicists; they must, moreover, know something of the celestial
+spheres in order to interpret the history of the earth. In fact, day
+by day, with the advance of learning, we come more clearly to
+perceive that all the processes of Nature are in a way related to each
+other, and that in proportion as we understand any part of the great
+mechanism, we are forced in a manner to comprehend the whole. In other
+words, we are coming to understand that these divisions of the field
+of science depend upon the limitations of our knowledge, and not upon
+the order of Nature itself. For the purposes of education it is
+important that every one should know something of the great truths
+which each science has disclosed. No mortal man can compass the whole
+realm of this knowledge, but every one can gain some idea of the
+larger truths which may help him to understand the beauty and grandeur
+of the sphere in which he dwells, which will enable him the better to
+meet the ordinary duties of life, that in almost all cases are related
+to the facts of the world about us. It has been of late the custom to
+term this body of general knowledge which takes account of the more
+evident facts and important series of terrestrial actions
+physiography, or, as the term implies, a description of Nature, with
+the understanding that the knowledge chosen for the account is that
+which most intimately concerns the student who seeks information that
+is at once general and important. Therefore, in this book the effort
+is made first to give an account as to the ways and means which have
+led to our understanding of scientific problems, the methods by which
+each person may make himself an inquirer, and the outline of the
+knowledge that has been gathered since men first began to observe and
+criticise the revelations the universe may afford them.
+
+
+
+
+                             CHAPTER II.
+
+                  WAYS AND MEANS OF STUDYING NATURE.
+
+
+It is desirable that the student of Nature keep well in mind the means
+whereby he is able to perceive what goes on in the world about him. He
+should understand something as to the nature of his senses, and the
+extent to which these capacities enable him to discern the operations
+of Nature. Man, in common with his lower kindred, is, by the mechanism
+of the body, provided with five somewhat different ways by which he
+may learn something of the things about him. The simplest of these
+capacities is that of touch, a faculty that is common to the general
+surface of the body, and which informs us when the surface is affected
+by contact with some external object. It also enables us to discern
+differences of temperature. Next is the sense of taste, which is
+limited to the mouth and the parts about it. This sense is in a way
+related to that of touch, for the reason that it depends on the
+contact of our body with material things. Third is the sense of smell,
+so closely related to that of taste that it is difficult to draw the
+line between the two. Yet through the apparatus of the nose we can
+perceive the microscopically small parts of matter borne to us through
+the air, which could not be appreciated by the nerves of the mouth.
+Fourth in order of scope comes the hearing, which gives us an account
+of those waves of matter that we understand as sound. This power is
+much more far ranging than those before noted; in some cases, as in
+that of the volcanic explosions from the island of Krakatoa, in the
+eruption of 1883, the convulsions were audible at the distance of
+more than a thousand miles away. The greater cannon of modern days may
+be heard at the distance of more than a hundred miles, so that while
+the sense of touch, taste, and smell demand contact with the bodies
+which we appreciate, hearing gives us information concerning objects
+at a considerable distance. Last and highest of the senses, vastly the
+most important in all that relates to our understanding of Nature, is
+sight, or the capacity which enables us to appreciate the movement of
+those very small waves of ether which constitute light. The eminent
+peculiarity of sight is that it may give us information concerning
+things which are inconceivably far away; it enables us to discern the
+light of suns probably millions of times as remote from us as is the
+centre of our own solar system.
+
+Although much of the pleasure which the world affords us comes through
+the other senses, the basis of almost all our accurate knowledge is
+reported by sight. It is true that what we have observed with our eyes
+may be set forth in words, and thus find its way to the understanding
+through the ears; also that in many instances the sense of touch
+conveys information which extends our perceptions in many important
+ways; but science rests practically on sight, and on the insight that
+comes from the training of the mind which the eyes make possible.
+
+The early inquirers had no resources except those their bodies
+afforded; but man is a tool-making creature, and in very early days he
+began to invent instruments which helped him in inquiry. The earliest
+deliberate study was of the stars. Science began with astronomy, and
+the first instruments which men contrived for the purpose of
+investigation were astronomical. In the beginning of this search the
+stars were studied in order to measure the length of the year, and
+also for the reason that they were supposed in some way to control the
+fate of men. So far as we know, the first pieces of apparatus for this
+purpose were invented in Egypt, perhaps about four thousand years
+before the Christian era. These instruments were of a simple nature,
+for the magnifying glass was not yet contrived, and so the telescope
+was impossible. They consisted of arrangements of straight edges and
+divided circles, so that the observers, by sighting along the
+instruments, could in a rough way determine the changes in distance
+between certain stars, or the height of the sun above the horizon at
+the various seasons of the year. It is likely that each of the great
+pyramids of Egypt was at first used as an observatory, where the
+priests, who had some knowledge of astronomy, found a station for the
+apparatus by which they made the observations that served as a basis
+for casting the horoscope of the king.
+
+In the progress of science and of the mechanical invention attending
+its growth, a great number of inventions have been contrived which
+vastly increase our vision and add inconceivably to the precision it
+may attain. In fact, something like as much skill and labour has been
+given to the development of those inventions which add to our learning
+as to those which serve an immediate economic end. By far the greatest
+of these scientific inventions are those which depend upon the lens.
+By combining shaped bits of glass so as to control the direction in
+which the light waves move through them, naturalists have been able to
+create the telescope, which in effect may bring distant objects some
+thousand times nearer to view than they are to the naked eye; and the
+microscope, which so enlarges minute objects as to make them visible,
+as they were not before. The result has been enormously to increase
+our power of vision when applied to distant or to small objects. In
+fact, for purposes of learning, it is safe to say that those tools
+have altogether changed man's relation to the visible universe. The
+naked eye can see at best in the part of the heavens visible from any
+one point not more than thirty thousand stars. With the telescope
+somewhere near a hundred million are brought within the limits of
+vision. Without the help of the microscope an object a thousandth of
+an inch in diameter appears as a mere point, the existence of which we
+can determine only under favourable circumstances. With that
+instrument the object may reveal an extended and complicated structure
+which it may require a vast labour for the observer fully to explore.
+
+Next in importance to the aid of vision above noted come the
+scientific tools which are used in weighing and measuring. These
+balances and gauges have attained such precision that intervals so
+small as to be quite invisible, and weights as slight as a
+ten-thousandth of a grain, can be accurately measured. From these
+instruments have come all those precise examinations on which the
+accuracy of modern science intimately depends. All these instruments
+of precision are the inventions of modern days. The simplest
+telescopes were made only about two hundred and fifty years ago, and
+the earlier compound microscopes at a yet later date. Accurate
+balances and other forms of gauges of space, as well as good means of
+dividing time, such as our accurate astronomical clocks and
+chronometers, are only about a century old. The instruments have made
+science accurate, and have immensely extended its powers in nearly all
+the fields of inquiry.
+
+Although the most striking modern discoveries are in the field which
+was opened to us by the lens in its manifold applications, it is in
+the chemist's laboratory that we find that branch of science, long
+cultivated, but rapidly advanced only within the last two centuries,
+which has done the most for the needs of man. The ancients guessed
+that the substances which make up the visible world were more
+complicated in their organization than they appear to our vision. They
+even suggested the great truth that matter of all kinds is made up of
+inconceivably small indivisible bits which they and we term atoms. It
+is likely that in the classic days of Greece men began to make simple
+experiments of a chemical nature. A century or two after the time of
+Mohammed, the Arabians of his faith, a people who had acquired Greek
+science from the libraries which their conquests gave them, conducted
+extensive experiments, and named a good many familiar chemical
+products, such as alcohol, which still bears its Arabic name.
+
+These chemical studies were continued in Europe by the alchemists, a
+name also of Arabic origin, a set of inquirers who were to a great
+extent drawn away from scientific studies by vain though unending
+efforts to change the baser metals into gold and silver, as well as to
+find a compound which would make men immortal in the body. By the
+invention of the accurate balance, and by patient weighing of the
+matters which they submitted to experiment, by the invention of
+hypotheses or guesses at truth, which were carefully tested by
+experiment, the majestic science of modern chemistry has come forth
+from the confused and mystical studies of the alchemists. We have
+learned to know that there are seventy or more primitive or apparently
+unchangeable elements which make up the mass of this world, and
+probably constitute all the celestial spheres, and that these elements
+in the form of their separate atoms may group themselves in almost
+inconceivably varied combinations. In the inanimate realm these
+associations, composed of the atoms of the different substances,
+forming what are termed molecules, are generally composed of but few
+units. Thus carbonic-acid gas, as it is commonly called, is made up of
+an aggregation of molecules, each composed of one atom of carbon and
+two of oxygen; water, of two atoms of hydrogen and one of oxygen;
+ordinary iron oxide, of two atoms of iron and three of oxygen. In the
+realm of organic life, however, these combinations become vastly more
+complicated, and with each of them the properties of the substance
+thus produced differ from all others. A distinguished chemist has
+estimated that in one group of chemical compounds, that of carbon, it
+would be possible to make such an array of substances that it would
+require a library of many thousand ordinary volumes to contain their
+names alone.
+
+It is characteristic of chemical science that it takes account of
+actions which are almost entirely invisible. No contrivances have been
+or are likely to be invented which will show the observer what takes
+place when the atoms of any substance depart from their previous
+combination and enter on new arrangements. We only know that under
+certain conditions the old atomic associations break up, and new ones
+are formed. But though the processes are hidden, the results are
+manifest in the changes which are brought about upon the masses of
+material which are subjected to the altering conditions. Gradually the
+chemists of our day are learning to build up in their laboratories
+more and more complicated compounds; already they have succeeded in
+producing many of the materials which of old could only be obtained by
+extracting them from plants. Thus a number of the perfumes of flowers,
+and many of the dye-stuffs which a century ago were extracted from
+vegetables, and were then supposed to be only obtainable in that way,
+are now readily manufactured. In time it seems likely that important
+articles of food, for which we now depend upon the seeds of plants,
+may be directly built up from the mineral kingdom. Thus the result of
+chemical inquiry has been not only to show us much of the vast realm
+of actions which go on in the earth, but to give us control of many of
+these movements so that we may turn them to the needs of man.
+
+Animals and plants were at an early day very naturally the subjects of
+inquiry. The ancients perceived that there were differences of kind
+among these creatures, and even in Aristotle's time the sciences of
+zooelogy and botany had attained the point where there were
+considerable treatises on those subjects. It was not, however, until a
+little more than a century ago that men began accurately to describe
+and classify these species of the organic world. Since the time of
+Linnaeus the growth of our knowledge has gone forward with amazing
+swiftness. Within a century we have come to know perhaps a hundred
+times as much concerning these creatures as was learned in all the
+earlier ages. This knowledge is divisible into two main branches: in
+one the inquirers have taken account of the different species, genera,
+families, orders, and classes of living forms with such effect that
+they have shown the existence at the present time of many hundred
+thousand distinct species, the vast assemblage being arranged in a
+classification which shows something as to the relationship which the
+forms bear to each other, and furthermore that the kinds now living
+have not been long in existence, but that at each stage in the history
+of the earth another assemblage of species peopled the waters and the
+lands.
+
+At first naturalists concerned themselves only with the external forms
+of living creatures; but they soon came to perceive that the way in
+which these organisms worked, their physiology, in a word, afforded
+matters for extended inquiry. These researches have developed the
+science of physiology, or the laws of bodily action, on many accounts
+the most modern and extensive of our new acquisitions of natural
+learning. Through these studies we have come to know something of the
+laws or principles by which life is handed on from generation to
+generation, and by which the gradations of structure have been
+advanced from the simple creatures which appear like bits of animated
+jelly to the body and mind of man.
+
+The greatest contribution which modern naturalists have made to
+knowledge concerns the origin of organic species. The students of a
+century ago believed that all these different kinds had been suddenly
+created either through natural law or by the immediate will of God. We
+now know that from the beginning of organic life in the remote past to
+the present day one kind of animal or plant has been in a natural and
+essentially gradual way converted into the species which was to be its
+successor, so that all the vast and complicated assemblage of kinds
+which now exists has been derived by a process of change from the
+forms which in earlier ages dwelt upon this planet. The exact manner
+in which these alterations were produced is not yet determined, but in
+large part it has evidently been brought about by the method indicated
+by Mr. Darwin, through the survival of the fittest individuals in the
+struggle for existence.
+
+Until men came to have a clear conception as to the spherical form of
+the earth, it was impossible for them to begin any intelligent
+inquiries concerning its structure or history. The Greeks knew the
+earth to be a sphere, but this knowledge was lost among the early
+Christian people, and it was not until about four hundred years ago
+that men again came to see that they dwelt upon a globe. On the basis
+of this understanding the science of geology, which had in a way been
+founded by the Greeks, was revived. As this science depends upon the
+knowledge which we have gained of astronomy, physics, chemistry, and
+biology, all of which branches of learning have to be used in
+explaining the history of the earth, the advance which has been made
+has been relatively slow. Geology as a whole is the least perfectly
+organized of all the divisions of learning. A special difficulty
+peculiar to this science has also served to hinder its development.
+All the other branches of learning deal mainly, if not altogether,
+with the conditions of Nature as they now exist. In this alone is it
+necessary at every step to take account of actions which have been
+performed in the remote past.
+
+It is an easy matter for the students of to-day to imagine that the
+earth has long endured; but to our forefathers, who were educated in
+the view that it had been brought from nothingness into existence
+about seven thousand years ago, it was most difficult and for a time
+impossible to believe in its real antiquity. Endeavouring, as they
+naturally did, to account for all the wonderful revolutions, the
+history of which is written in the pages of the great stone book, the
+early geologists supposed this planet to have been the seat of
+frequent and violent changes, each of which revolutionized its shape
+and destroyed its living tenants. It was only very gradually that
+they became convinced that a hundred million years or more have
+elapsed since the dawn of life on the earth, and that in this vast
+period the march of events has been steadfast, the changes taking
+place at about the same rate in which they are now going on. As yet
+this conception as to the history of our sphere has not become the
+general property of the people, but the fact of it is recognised by
+all those who have attentively studied the matter. It is now as well
+ascertained as any of the other truths which science has disclosed to
+us.
+
+It is instructive to note the historic outlines of scientific
+development. The most conspicuous truth which this history discloses
+is that all science has had its origin and almost all its development
+among the peoples belonging to the Aryan race. This body of folk
+appears to have taken on its race characteristics, acquired its
+original language, its modes of action, and the foundations of its
+religion in that part of northern Europe which is about the Baltic
+Sea. Thence the body of this people appear to have wandered toward
+central Asia, where after ages of pastoral life in the high table
+lands and mountains of their country it sent forth branches to India,
+Asia Minor and Greece, to Persia, and to western Europe. It seems ever
+to have been a characteristic of these Aryan peoples that they had an
+extreme love for Nature; moreover, they clearly perceived the need of
+accounting for the things that happened in the world about them. In
+general they inclined to what is called the pantheistic explanation of
+the universe. They believed a supreme God in many different forms to
+be embodied in all the things they saw. Even their own minds and
+bodies they conceived as manifestations of this supreme power. Among
+the Aryans who came to dwell in Europe and along the eastern
+Mediterranean this method of explaining Nature was in time changed to
+one in which humanlike gods were supposed to control the visible and
+invisible worlds. In that marvellous centre of culture which was
+developed among the Greeks this conception of humanlike deities was in
+time replaced by that of natural law, and in their best days the
+Greeks were men of science essentially like those of to-day, except
+that they had not learned by experience how important it was to
+criticise their theories by patiently comparing them with the facts
+which they sought to explain. The last of the important Greek men of
+science, Strabo, who was alive when Christ was born, has left us
+writings which in quality are essentially like many of the able works
+of to-day. But for the interruption in the development of Greek
+learning, natural science would probably have been fifteen hundred
+years ahead of its present stage. This interruption came in two ways.
+In one, through the conquest of Greece and the destruction of its
+intellectual life by the Romans, a people who were singularly
+incapable of appreciating natural science, and who had no other
+interest in it except now and then a vacant and unprofitable curiosity
+as to the processes of the natural world. A second destructive
+influence came through the fact that Christianity, in its energetic
+protest against the sins of the pagan civilization, absolutely
+neglected and in a way despised all forms of science.
+
+The early indifference of Christians to natural learning is partly to
+be explained by the fact that their religion was developed among the
+Hebrews, a people remarkable for their lack of interest in the
+scientific aspects of Nature. To them it was a sufficient explanation
+that one omnipotent God ruled all things at his will, the heavens and
+the earth alike being held in the hollow of his hand.
+
+Finding the centre of its development among the Romans, Christianity
+came mainly into the control of a people who, as we have before
+remarked, had no scientific interest in the natural world. This
+condition prolonged the separation of our faith from science for
+fifteen hundred years after its beginning. In this time the records of
+Greek scientific learning mostly disappeared. The writings of
+Aristotle were preserved in part for the reason that the Church
+adopted many of his views concerning questions in moral philosophy and
+in politics. The rest of Greek learning was, so far as Europe was
+concerned, quite neglected.
+
+A large part of Greek science which has come down to us owes its
+preservation to a very singular incident in the history of learning.
+In the ninth century, after the Arabs had been converted to
+Mohammedanism, and on the basis of that faith had swiftly organized a
+great and cultivated empire, the scholars of that folk became deeply
+interested in the remnants of Greek learning which had survived in the
+monastic and other libraries about the eastern Mediterranean. So
+greatly did they prize these records, which were contemned by the
+Christians, that it was their frequent custom to weigh the old
+manuscripts in payment against the coin of their realm. In astronomy,
+mathematics, chemistry, and geology the Arabian students, building on
+the ancient foundations, made notable and for a time most important
+advances. In the tenth century of our era they seemed fairly in the
+way to do for science what western Europe began five centuries later
+to accomplish. In the fourteenth century the centre of Mohammedan
+strength was transferred from the Arabians to the Turks, from a people
+naturally given to learning to a folk of another race, who despised
+all such culture. Thenceforth in place of the men who had treasured
+and deciphered with infinite pains all the records of earlier
+learning, the followers of Mohammed zealously destroyed all the
+records of the olden days. Some of these records, however, survived
+among the Arabs of Spain, and others were preserved by the Christian
+scholars who dwelt in Byzantium, or Constantinople, and were brought
+into western Europe when that city was captured by the Turks in the
+fifteenth century.
+
+Already the advance of the fine arts in Italy and the general tendency
+toward the study of Nature, such as painting and sculpture indicate,
+had made a beginning, or rather a proper field for a beginning, of
+scientific inquiry. The result was a new interest in Greek learning in
+all its branches, and a very rapid awakening of the scientific spirit.
+At first the Roman Church made no opposition to this new interest
+which developed among its followers, but in the course of a few years,
+animated with the fear that science would lead men to doubt many of
+the dogmas of the Church, it undertook sternly to repress the work of
+all inquirers.
+
+The conflict between those of the Roman faith and the men of science
+continued for above two hundred years. In general, the part which the
+Church took was one of remonstrance, but in a few cases the spirit of
+fanaticism led to the persecution of the men who did not obey its
+mandates and disavow all belief in the new opinions which were deemed
+contrary to the teachings of Scripture. The last instance of such
+oppression occurred in France in the year 1756, when the great Buffon
+was required to recant certain opinions concerning the antiquity of
+the earth which he had published in his work on Natural History. This
+he promptly did, and in almost servile language withdrew all the
+opinions to which the fathers had objected. A like conflict between
+the followers of science and the clerical authorities occurred in
+Protestant countries. Although in no case were the men of science
+physically tortured or executed for their opinions, they were
+nevertheless subjected to great religious and social pressure: they
+were almost as effectively disciplined as were those who fell under
+the ban of the Roman Church.
+
+Some historians have criticised the action of the clerical authorities
+toward science as if the evil which was done had been performed in our
+own day. It should be remembered, however, that in the earlier
+centuries the churches regarded themselves as bound to protect all men
+from the dangers of heresy. For centuries in the early history of
+Christianity the defenders of the faith had been engaged in a
+life-and-death struggle with paganism, the followers of which held all
+that was known of Nature. Quite naturally the priestly class feared
+that the revival of scientific inquiry would bring with it the evils
+from which the world had suffered in pagan times. There is no doubt
+that these persecutions of science were done under what seemed the
+obligations of duty. They may properly be explained particularly by
+men of science as one of the symptoms of development in the day in
+which they were done. It is well for those who harshly criticise the
+relations of the Church to science to remember that in our own
+country, about two centuries ago, among the most enlightened and
+religious people of the time, Quakers were grievously persecuted, and
+witches hanged, all in the most dutiful and God-fearing way. In
+considering these relations of science to our faith, the matter should
+be dealt with in a philosophical way, and with a sense of the
+differences between our own and earlier ages.
+
+To the student of the relations between Christianity and science it
+must appear doubtful whether the criticism or the other consequences
+which the men of science had to meet from the Church was harmful to
+their work. The early naturalists, like the Greeks whom they followed,
+were greatly given to speculations concerning the processes of Nature,
+which, though interesting, were unprofitable. They also showed a
+curious tendency to mingle their scientific speculations with ancient
+and base superstitions. They were often given to the absurdity
+commonly known as the "black art," or witchcraft, and held to the
+preposterous notions of the astrologists. Even the immortal astronomer
+Kepler, who lived in the sixteenth century, was a professional
+astrologer, and still held to the notion that the stars determined the
+destiny of men. Many other of the famous inquirers in those years
+which ushered in modern science believed in witchcraft. Thus for a
+time natural learning was in a way associated with ancient and
+pernicious beliefs which the Church was seeking to overthrow. One
+result of the clerical opposition to the advancement of science was
+that its votaries were driven to prove every step which led to their
+conclusions. They were forced to abandon the loose speculation of
+their intellectual guides, the Greeks, and to betake themselves to
+observation. Thus a part of the laborious fact-gathering habit on
+which the modern advance of science has absolutely depended was due to
+the care which men had to exercise in face of the religious
+authorities.
+
+In our own time, in the latter part of the nineteenth century, the
+conflict between the religious authority and the men of science has
+practically ceased. Even the Roman Church permits almost everywhere an
+untrammelled teaching of the established learning to which it was at
+one time opposed. Men have come to see that all truth is accordant,
+and that religion has nothing to fear from the faithful and devoted
+study of Nature.
+
+The advance of science in general in modern times has been greatly due
+to the development of mechanical inventions. Among the ancients, the
+tools which served in the arts were few in number, and these of
+exceeding simplicity. So far as we can ascertain, in the five hundred
+years during which the Greeks were in their intellectual vigour, not
+more than half a dozen new machines were invented, and these were
+exceedingly simple. The fact seems to be that a talent for mechanical
+invention is mainly limited to the peoples of France, Germany, and of
+the English-speaking folk. The first advances in these contrivances
+were made in those countries, and all our considerable gains have come
+from their people. Thus, while the spirit of science in general is
+clearly limited to the Aryan folk, that particular part of the motive
+which leads to the invention of tools is restricted to western and
+northern Europe, to the people to whom we give the name of Teutonic.
+
+Mechanical inventions have aided the development of our sciences in
+several ways. They have furnished inquirers with instruments of
+precision; they have helped to develop accuracy of observation; best
+of all, they have served ever to bring before the attention of men a
+spectacle of the conditions in Nature which we term cause and effect.
+The influence of these inventions on the development of learning has
+been particularly great where the machines, such as our wind and water
+mills, and our steam engine, make use of the forces of Nature,
+subjugating them to the needs of man. Such instruments give an
+unending illustration as to the presence in Nature of energy. They
+have helped men to understand that the machinery of the universe is
+propelled by the unending application of power. It was, in fact,
+through such machines that men of science first came to understand
+that energy, manifested in the natural forces, is something that
+eternally endures; that we may change its form in our arts as its form
+is changed in the operations of Nature, but the power endures forever.
+
+It is interesting to note that the first observation which led to this
+most important scientific conclusion that energy is indestructible
+however much it may change its form, was made by an American, Benjamin
+Thompson, who left this country at the time of the Revolution, and
+after a curious life became the executive officer, and in effect king,
+of Bavaria. While engaged in superintending the manufacture of cannon,
+he observed that in boring out the barrel of the gun an amount of heat
+was produced which evaporated a certain amount of water. He therefore
+concluded that the energy required to do the boring of the metal
+passed into the state of heat, and thus only changed its state, in no
+wise disappearing from the earth. Other students pursuing the same
+line of inquiry have clearly demonstrated what is called the law of
+the conservation of energy, which more than anything has helped us to
+understand the large operations of Nature. Through these studies we
+have come to see that, while the universe is a place of ceaseless
+change, the quantities of energy and of matter remain unaltered.
+
+The foregoing brief sketch, which sets forth some of the important
+conditions which have affected the development of science, may in a
+way serve to show the student how he can himself become an interpreter
+of Nature. The evidence indicates that the people of our race have
+been in a way chosen among all the varieties of mankind to lead in
+this great task of comprehending the visible universe. The facts,
+moreover, show that discovery usually begins with the interest which
+men feel in the world immediately about them, or which is presented to
+their senses in a daily spectacle. Thus Benjamin Franklin, in the
+midst of a busy life, became deeply interested in the phenomena of
+lightning, and by a very simple experiment proved that this wonder of
+the air was due to electrical action such as we may arouse by rubbing
+a stick of sealing-wax or a piece of amber with a cloth. All
+discoveries, in a word, have had their necessary beginnings in an
+interest in the facts which daily experience discloses. This desire to
+know something more than the first sight exhibits concerning the
+actions in the world about us is native in every human soul--at least,
+in all those who are born with the heritage of our race. It is
+commonly strong in childhood; if cultivated by use, it will grow
+throughout a lifetime, and, like other faculties, becomes the stronger
+and more effective by the exertions which it inspires. It is therefore
+most important that every one should obey this instinctive command to
+inquiry, and organize his life and work so that he may not lose but
+gain more and more as time goes on of this noble capacity to
+interrogate and understand the world about him.
+
+It is best that all study of Nature should begin not in laboratories,
+nor with the things which are remote from us, but in the field of
+Nature which is immediately about us. The student, even if he dwell in
+the unfavourable conditions of a great city, is surrounded by the
+world which has yielded immeasurable riches in the way of learning,
+which he can appropriate by a little study. He can readily come to
+know something of the movements of the air; the buildings will give
+him access to a great many different kinds of stone; the smallest
+park, a little garden, or even a few potted plants and captive
+animals, may tell him much concerning the forms and actions of living
+beings. By studying in this way he can come to know something of the
+differences between things and their relations to each other. He will
+thus have a standard by which he can measure and make familiar the
+body of learning concerning Nature which he may find in books. From
+printed pages alone, however well they be written, he can never hope
+to catch the spirit that animates the real inquirer, the true lover of
+Nature.
+
+On many accounts the most attractive way of beginning to form the
+habit of the naturalist is by the study of living animals and plants.
+To all of us life adds interest, and growth has a charm. Therefore it
+is well for the student to start on the way of inquiry by watching the
+actions of birds and insects or by rearing plants. It is fortunate if
+he can do both these agreeable things. When the habit of taking an
+account of that most important part of the world which is immediately
+about him has been developed in the student, he may profitably proceed
+to acquire the knowledge of the invisible universe which has been
+gathered by the host of inquirers of his race. However far he
+journeys, he should return to the home world that lies immediately and
+familiarly about him, for there alone can he acquire and preserve that
+personal acquaintance with things which is at once the inspiration and
+the test of all knowledge.
+
+Along with this study of the familiar objects about us the student may
+well combine some reading which may serve to show him how others have
+been successful in thus dealing with Nature at first hand. For this
+purpose there are, unfortunately, but few works which are well
+calculated to serve the needs of the beginner. Perhaps the best
+naturalist book, though its form is somewhat ancient, is White's
+Natural History of Selborne. Hugh Miller's works, particularly his Old
+Red Sandstone and My Schools and Schoolmasters, show well how a man
+may become a naturalist under difficulties. Sir John Lubbock's studies
+on Wasps, and Darwin's work on Animals and Plants under Domestication
+are also admirable to show how observation should be made. Dr. Asa
+Gray's little treatise on How Plants Grow will also be useful to the
+beginner who wishes to approach botany from its most attractive
+side--that of the development of the creature from the seed to seed.
+
+There is another kind of training which every beginner in the art of
+observing Nature should obtain, and which many naturalists of repute
+would do well to give themselves--namely, an education in what we may
+call the art of distance and geographical forms. With the primitive
+savage the capacity to remember and to picture to the eye the shape of
+a country which he knows is native and instinctive. Accustomed to
+range the woods, and to trust to his recollection to guide him through
+the wilderness to his home, the primitive man develops an important
+art which among civilized people is generally dormant. In fact, in our
+well-trodden ways people may go for many generations without ever
+being called upon to use this natural sense of geography. The easiest
+way to cultivate the geographic sense is by practising the art of
+making sketch maps. This the student, however untrained, can readily
+do by taking first his own dwelling house, on which he should practise
+until he can readily from memory make a tolerably correct and
+proportional plan of all its rooms. Then on a smaller scale he should
+begin to make also from recollection a map showing the distribution of
+the roads, streams, and hills with which his daily life makes him
+familiar. From time to time this work from memory should be compared
+with the facts. At first the record will be found to be very poor, but
+with a few months of occasional endeavour the observer will find that
+his mind takes account of geographic features in a way it did not
+before, and, moreover, that his mind becomes enriched with
+impressions of the country which are clear and distinct, in place of
+the shadowy recollections which he at first possessed.
+
+When the student has attained the point where, after walking or riding
+over a country, he can readily recall its physical features of the
+simpler sort, he will find it profitable to undertake the method of
+mapping with contour lines--that is, by pencilling in indications to
+show the exact shape of the elevations and depressions. The principle
+of contour lines is that each of them represents where water would
+come against the slope if the area were sunk step by step below the
+sea level--in other words, each contour line marks the intersection of
+a horizontal plane with the elevation of the country. Practice on this
+somewhat difficult task will soon give the student some idea as to the
+complication of the surface of a region, and afford him the basis for
+a better understanding of what geography means than all the reading he
+can do will effect. It is most desirable that training such as has
+been described should be a part of our ordinary school education.
+
+Very few people have clear ideas of distances. Even the men whose
+trade requires some such knowledge are often without that which a
+little training could give them. Without some capacity in this
+direction, the student is always at a disadvantage in his contact with
+Nature. He can not make a record of what he sees as long as the
+element of horizontal and vertical distance is not clearly in mind. To
+attain this end the student should begin by pacing some length of road
+where the distances are well known. In this way he will learn the
+length of his step, which with a grown man generally ranges between
+two and a half and three feet. Learning the average length of his
+stride by frequent counting, it is easy to repeat the trial until one
+can almost unconsciously keep the count as he walks. Properly to
+secure the training of this sort the observer should first attentively
+look across the distance which is to be determined. He should notice
+how houses, fences, people, and trees appear at that distance. He will
+quickly perceive that each hundred feet of additional interval
+somewhat changes their aspect. In training soldiers to measure with
+the eye the distances which they have to know in order effectively to
+use the modern weapons of war, a common device is to take a squad of
+men, or sometimes a company, under the command of an officer, who
+halts one man at each hundred yards until the detachment is strung out
+with that interval as far as the eye can see them. The men then walk
+to and fro so that the troops who are watching them may note the
+effects of increased distance on their appearance, whether standing or
+in motion. At three thousand yards a man appears as a mere dot, which
+is not readily distinguishable. Schoolboys may find this experiment
+amusing and instructive.
+
+After the student has gained, as he readily may, some sense of the
+divisions of distance within the range of ordinary vision, he should
+try to form some notion of greater intervals, as of ten, a hundred,
+and perhaps a thousand miles. The task becomes more difficult as the
+length of the line increases, but most persons can with a little
+address manage to bring before their eyes a tolerably clear image of a
+hundred miles of distance by looking from some elevation which
+commands a great landscape. It is doubtful, however, whether the
+best-trained man can get any clear notion of a thousand miles--that
+is, can present it to himself in imagination as he may readily do with
+shorter intervals.
+
+The most difficult part of the general education which the student has
+to give himself is begun when he undertakes to picture long intervals
+of time. Space we have opportunities to measure, and we come in a way
+to appreciate it, but the longest lived of men experiences at most a
+century of life, and this is too small a measure to give any notion as
+to the duration of such great events as are involved in the history of
+the earth, where the periods are to be reckoned by the millions of
+years. The only way in which we can get any aid in picturing to
+ourselves great lapses of time is by expressing them in units of
+distance. Let a student walk away on a straight road for the distance
+of a mile; let him call each step a year; when he has won the first
+milestone, he may consider that he has gone backward in time to the
+period of Christ's birth. Two miles more will take him to the station
+which will represent the age when the oldest pyramids were built. He
+is still, however, in the later days of man's history on this planet.
+To attain on the scale the time when man began, he might well have to
+walk fifty miles away, while a journey which would thus by successive
+steps describe the years of the earth's history since life appeared
+upon its surface would probably require him to circle the earth at
+least four times. We may accept it as impossible for any one to deal
+with such vast durations save with figures which are never really
+comprehended. It is well, however, to enlarge our view as to the age
+of the earth by such efforts as have just been indicated.
+
+When we go beyond the earth into the realm of the stars all efforts
+toward understanding the ranges of space or the durations of time are
+quite beyond the efforts of man. Even the distance of about two
+hundred and forty thousand miles which separates us from the moon can
+not be grasped by even the greater minds. No human intelligence,
+however cultivated, can conceive the distance of about ninety-five
+million miles which separates us from the sun. In the celestial realm
+we can only deal with relations of space and time in a general and
+comparative way. We can state the distances if we please in millions
+of miles, or we can reckon the ampler spaces by using the interval
+which separates the earth from the sun as we do a foot rule in our
+ordinary work, but the depths of the starry spaces can only be sounded
+by the winged imagination.
+
+Although the student has been advised to begin his studies of Nature
+on the field whereon he dwells, making that study the basis of his
+most valuable communications with Nature, it is desirable that he
+should at the same time gain some idea as to the range and scope of
+our knowledge concerning the visible universe. As an aid toward this
+end the following chapters of this book will give a very brief survey
+of some of the most important truths concerning the heavens and the
+earth which have rewarded the studies of scientific men. Of remoter
+things, such as the bodies in the stellar spaces, the account will be
+brief, for that which is known and important to the general student
+can be briefly told. So, too, of the earlier ages of the earth's
+history, although a vast deal is known, the greater part of the
+knowledge is of interest and value mainly to geologists who cultivate
+that field. That which is most striking and most important to the mass
+of mankind is to be found in the existing state of our earth, the
+conditions which make it a fit abode for our kind, and replete with
+lessons which he may study with his own eyes without having to travel
+the difficult paths of the higher sciences.
+
+Although physiography necessarily takes some account of the things
+which have been, even in the remote past, and this for the reason that
+everything in this day of the world depends on the events of earlier
+days, the accent of its teaching is on the immediate, visible, as we
+may say, living world, which is a part of the life of all its
+inhabitants.
+
+
+
+
+                            CHAPTER III.
+
+                         THE STELLAR REALM.
+
+
+Even before men came to take any careful account of the Nature
+immediately about them they began to conjecture and in a way to
+inquire concerning the stars and the other heavenly bodies. It is
+difficult for us to imagine how hard it was for students to gain any
+adequate idea of what those lights in the sky really are. At first men
+imagined the celestial bodies to be, as they seemed, small objects not
+very far away. Among the Greeks the view grew up that the heavens were
+formed of crystal spheres in which the lights were placed, much as
+lanterns may be hung upon a ceiling. These spheres were conceived to
+be one above the other; the planets were on the lower of them, and the
+fixed stars on the higher, the several crystal roofs revolving about
+the earth. So long as the earth was supposed to be a flat and
+limitless expanse, forming the centre of the universe, it was
+impossible for the students of the heavens to attain any more rational
+view as to their plan.
+
+The fact that the earth was globular in form was understood by the
+Greek men of science. They may, indeed, have derived the opinion from
+the Egyptian philosophers. The discovery rested upon the readily
+observed fact that on a given day the shadow of objects of a certain
+height was longer in high latitude than in low. Within the tropics,
+when the sun was vertical, there would be no shadow, while as far
+north as Athens it would be of considerable length. The conclusion
+that the earth was a sphere appears to have been the first large
+discovery made by our race. It was, indeed, one of the most important
+intellectual acquisitions of man.
+
+Understanding the globular form of the earth, the next and most
+natural step was to learn that the earth was not the centre of the
+planetary system, much less of the universe, but that that centre was
+the sun, around which the earth and the other planets revolved. The
+Greeks appear to have had some idea that this was the case, and their
+spirit of inquiry would probably have led them to the whole truth but
+for the overthrow of their thought by the Roman conquest and the
+spread of Christianity. It was therefore not until after the revival
+of learning that astronomers won their way to our modern understanding
+concerning the relation of the planets to the sun. With Galileo this
+opinion was affirmed. Although for a time the Church, resting its
+opposition on the interpretation of certain passages of Scripture,
+resisted this view, and even punished the men who held it, it
+steadfastly made its way, and for more than two centuries has been the
+foundation of all the great discoveries in the stellar realm. Yet long
+after the fact that the sun was the centre of the solar system was
+well established no one understood why the planets should move in
+their ceaseless, orderly procession around the central mass. To Newton
+we owe the studies on the law of gravitation which brought us to our
+present large conception as to the origin of this order. Starting with
+the view that bodies attracted each other in proportion to their
+weight, and in diminishing proportion as they are removed from each
+other, Newton proceeded by most laborious studies to criticise this
+view, and in the end definitely proved it by finding that the motions
+of the moon about the earth, as well as the paths of the planets,
+exactly agreed with the supposition.
+
+The last great path-breaking discovery which has helped us in our
+understanding of the stars was made by Fraunhofer and other
+physicists, who showed us that substances when in a heated, gaseous,
+or vaporous state produced, in a way which it is not easy to explain
+in a work such as this, certain dark lines in the spectrum, or streak
+of divided light which we may make by means of a glass prism, or, as
+in the rainbow, by drops of water. Carefully studying these very
+numerous lines, those naturalists found that they could with singular
+accuracy determine what substances there were in the flame which gave
+the light. So accurate is this determination that it has been made to
+serve in certain arts where there is no better means of ascertaining
+the conditions of a flaming substance except by the lines which its
+light exhibits under this kind of analysis. Thus, in the manufacture
+of iron by what is called the Bessemer process, it has been found very
+convenient to judge as to the state of the molten metal by such an
+analysis of the flame which comes forth from it.
+
+[Illustration: _Seal Rocks near San Francisco, California, showing
+slight effect of waves where there is no beach._]
+
+No sooner was the spectroscope invented than astronomers hastened by
+its aid to explore the chemical constitution of the sun. These studies
+have made it plain that the light of our solar centre comes forth from
+an atmosphere composed of highly heated substances, all of which are
+known among the materials forming the earth. Although for various
+reasons we have not been able to recognise in the sun all the elements
+which are found in our sphere, it is certain that in general the two
+bodies are alike in composition. An extension of the same method of
+inquiry to the fixed stars was gradually though with difficulty
+attained, and we now know that many of the elements common to the sun
+and earth exist in those distant spheres. Still further, this method
+of inquiry has shown us, in a way which it is not worth while here to
+describe, that among these remoter suns there are many aggregations of
+matter which are not consolidated as are the spheres of our own solar
+system, but remain in the gaseous state, receiving the name of nebulae.
+
+Along with the growth of observational astronomy which has taken place
+since the discoveries of Galileo, there has been developed a view
+concerning the physical history of the stellar world, known as the
+nebular hypothesis, which, though not yet fully proved, is believed by
+most astronomers and physicists to give us a tolerably correct notion
+as to the way in which the heavenly spheres were formed from an
+earlier condition of matter. This majestic conception was first
+advanced, in modern times at least, by the German philosopher Immanuel
+Kant. It was developed by the French astronomer Laplace, and is often
+known by his name. The essence of this view rests upon the fact
+previously noted that in the realm of the fixed stars there are many
+faintly shining aggregations of matter which are evidently not solid
+after the manner of the bodies in our solar system, but are in the
+state where their substances are in the condition of dustlike
+particles, as are the bits of carbon in flame or the elements which
+compose the atmosphere. The view held by Laplace was to the effect
+that not only our own solar system, but the centres of all the other
+similar systems, the fixed stars, were originally in this gaseous
+state, the material being disseminated throughout all parts of the
+heavenly realm, or at least in that portion of the universe of which
+we are permitted to know something. In this ancient state of matter we
+have to suppose that the particles of it were more separated from each
+other than are the atoms of the atmospheric gases in the most perfect
+vacuum which we can produce with the air-pump. Still we have to
+suppose that each of these particles attract the other in the
+gravitative way, as in the present state of the universe they
+inevitably do.
+
+Under the influence of the gravitative attraction the materials of
+this realm of vapour inevitably tended to fall in toward the centre.
+If the process had been perfectly simple, the result would have been
+the formation of one vast mass, including all the matter which was in
+the original body. In some way, no one has yet been able to make a
+reasonable suggestion of just how, there were developed in the
+process of concentration a great many separate centres of aggregation,
+each of which became the beginning of a solar system. The student may
+form some idea of how readily local centres may be produced in
+materials disseminated in the vaporous state by watching how fog or
+the thin, even misty clouds of the sunrise often gather into the
+separate shapes which make what we term a "mackerel" sky. It is
+difficult to imagine what makes centres of attraction, but we readily
+perceive by this instance how they might have occurred.
+
+When the materials of each solar system were thus set apart from the
+original mass of star dust or vapour, they began an independent
+development which led step by step, in the case of our own solar
+system at least, and presumably also in the case of the other suns,
+the fixed stars, to the formation of planets and their moons or
+satellites, all moving around the central sun. At this stage of the
+explanation the nebular hypothesis is more difficult to conceive than
+in the parts of it which have already been described, for we have now
+to understand how the planets and satellites had their matter
+separated from each other and from the solar centre, and why they came
+to revolve around that central body. These problems are best
+understood by noting some familiar instances connected with the
+movement of fluids and gases toward a centre. First let us take the
+case of a basin in which the water is allowed to flow out through a
+hole in its centre. When we lift the stopper the fluid for a moment
+falls straight down through the opening. Very quickly, however, all
+the particles of the water start to move toward the centre, and almost
+at once the mass begins to whirl round with such speed that, although
+it is working toward the middle, it is by its movement pushed away
+from the centre and forms a conical depression. As often as we try the
+experiment, the effect is always the same. We thus see that there is
+some principle which makes particles of fluid that tend toward a
+centre fail directly to attain it, but win their way thereto in a
+devious, spinning movement.
+
+Although the fact is not so readily made visible to the eye, the same
+principle is illustrated in whirling storms, in which, as we shall
+hereafter note with more detail, the air next the surface of the earth
+is moving in toward a kind of chimney by which it escapes to the upper
+regions of the atmosphere. A study of cyclones and tornadoes, or even
+of the little air-whirls which in hot weather lift the dust of our
+streets, shows that the particles of the atmosphere in rushing in
+toward the centre of upward movement take on the same whirling motion
+as do the molecules of water in the basin--in fact, the two actions
+are perfectly comparable in all essential regards, except that the
+fluid is moving downward, while the air flows upward. Briefly stated,
+the reason for the movement of fluid and gas in the whirling way is as
+follows: If every particle on its way to the centre moved on a
+perfectly straight line toward the point of escape, the flow would be
+directly converging, and the paths followed would resemble the spokes
+of a wheel. But when by chance one of the particles sways ever so
+little to one side of the direct way, a slight lateral motion would
+necessarily be established. This movement would be due to the fact
+that the particle which pursued the curved line would press against
+the particles on the out-curved side of its path--or, in other words,
+shove them a little in that direction--to the extent that they
+departed from the direct line they would in turn communicate the
+shoving to the next beyond. When two particles are thus shoving on one
+side of their paths, the action which makes for revolution is doubled,
+and, as we readily see, the whole mass may in this way become quickly
+affected, the particles driven out of their path, moving in a curve
+toward the centre. We also see that the action is accumulative: the
+more curved the path of each particle, the more effectively it shoves;
+and so, in the case of the basin, we see the whirling rapidly
+developed before our eyes.
+
+In falling in toward the centre the particles of star dust or vapour
+would no more have been able one and all to pursue a perfectly
+straight line than the particles of water in the basin. If a man
+should spend his lifetime in filling and emptying such a vessel, it is
+safe to say that he would never fail to observe the whirling movement.
+As the particles of matter in the nebular mass which was to become a
+solar system are inconceivably greater than those of water in the
+basin, or those of air in the atmospheric whirl, the chance of the
+whirling taking place in the heavenly bodies is so great that we may
+assume that it would inevitably occur.
+
+As the vapours in the olden day tended in toward the centre of our
+solar system, and the mass revolved, there is reason to believe that
+ringlike separations took place in it. Whirling in the manner
+indicated, the mass of vapour or dust would flatten into a disk or a
+body of circular shape, with much the greater diameter in the plane of
+its whirling. As the process of concentration went on, this disk is
+supposed to have divided into ringlike masses, some approach to which
+we can discern in the existing nebulae, which here and there among the
+farther fixed stars appear to be undergoing such stages of development
+toward solar systems. It is reasonably supposed that after these rings
+had been developed they would break to pieces, the matter in them
+gathering into a sphere, which in time was to become a planet. The
+outermost of these rings led to the formation of the planet farthest
+from the sun, and was probably the first to separate from the parent
+mass. Then in succession rings were formed inwardly, each leading in
+turn to the creation of another planet, the sun itself being the
+remnant, by far the greater part of the whole mass of matter, which
+did not separate in the manner described, but concentrated on its
+centre. Each of these planetary aggregations of vapour tended to
+develop, as it whirled upon its centre, rings of its own, which in
+turn formed, by breaking and concentrating, the satellites or moons
+which attend the earth, as they do all the planets which lie farther
+away from the sun than our sphere.
+
+[Illustration: Fig. 1.--Saturn, Jan. 26, 1889 (Antoniadi).]
+
+As if to prove that the planets and moons of the solar system were
+formed somewhat in the manner in which we have described it, one of
+these spheres, Saturn, retains a ring, or rather a band which appears
+to be divided obscurely into several rings which lie between its group
+of satellites and the main sphere. How this ring has been preserved
+when all the others have disappeared, and what is the exact
+constitution of the mass, is not yet well ascertained. It seems clear,
+however, that it can not be composed of solid matter. It is either in
+the form of dust or of small spheres, which are free to move on each
+other; otherwise, as computation shows, the strains due to the
+attraction which Saturn itself and its moons exercise upon it would
+serve to break it in pieces. Although this ring theory of the
+formation of the planets and satellites is not completely proved, the
+occurrence of such a structure as that which girdles Saturn affords
+presumptive evidence that it is true. Taken in connection with what we
+know of the nebulae, the proof of Laplace's nebular hypothesis may
+fairly be regarded as complete.
+
+It should be said that some of the fixed stars are not isolated suns
+like our own, but are composed of two great spheres revolving about
+one another; hence they are termed double stars. The motions of these
+bodies are very peculiar, and their conditions show us that it is not
+well to suppose that the solar system in which we dwell is the only
+type of order which prevails in the celestial families; there may,
+indeed, be other variations as yet undetected. Still, these
+differences throw no doubt on the essential truth of the theory as to
+the process of development of the celestial systems. Though there is
+much room for debate as to the details of the work there, the general
+truth of the theory is accepted by nearly all the students of the
+problem.
+
+A peculiar advantage of the nebular hypothesis is that it serves to
+account for the energy which appears as light and heat in the sun and
+the fixed stars, as well as that which still abides in the mass of our
+earth, and doubtless also in the other large planets. When the matter
+of which these spheres were composed was disseminated through the
+realms of space, it is supposed to have had no positive temperature,
+and to have been dark, realizing the conception which appears in the
+first chapter of Genesis, "without form, and void." With each stage of
+the falling in toward the solar centres what is called the "energy of
+position" of this original matter became converted into light and
+heat. To understand how this took place, the reader should consider
+certain simple yet noble generalizations of physics. We readily
+recognise the fact that when a hammer falls often on an anvil it heats
+itself and the metal on which it strikes. Those who have been able to
+observe the descent of meteoric stones from the heavens have remarked
+that when they came to the earth they were, on their surfaces at
+least, exceedingly hot. Any one may observe shining meteors now and
+then flashing in the sky. These are known commonly to be very small
+bits of matter, probably not larger than grains of sand, which,
+rushing into our atmosphere, are so heated by the friction which they
+encounter that they burn to a gas or vapour before they attain the
+earth. As we know that these particles come from the starry spaces,
+where the temperature is somewhere near 500 deg. below 0 deg. Fahr., it is
+evident that the light and heat are not brought with them into the
+atmosphere; it can only be explained by the fact that when they enter
+the air they are moving at an average speed of about twenty miles a
+second, and that the energy which this motion represents is by the
+resistance which the body encounters converted into heat. This fact
+will help us to understand how, as the original star dust fell in
+toward the centre of attraction, it was able to convert what we have
+termed the energy of position into temperature. We see clearly that
+every such particle of dust or larger bit of matter which falls upon
+the earth brings about the development of heat, even though it does
+not actually strike upon the solid mass of our sphere. The conception
+of what took place in the consolidation of the originally disseminated
+materials of the sun and planets can be somewhat helped by a simple
+experiment. If we fit a piston closely into a cylinder, and then
+suddenly drive it down with a heavy blow, the compressed air is so
+heated that it may be made to communicate fire. If the piston should
+be slowly moved, the same amount of heat would be generated, or, as we
+may better say, liberated by the compression, though the effect would
+not be so striking. A host of experiments show that when a given mass
+of matter is brought to occupy a less space the effect is in
+practically all cases to increase the temperature. The energy which
+kept the particles apart is, when they are driven together, converted
+into heat. These two classes of actions are somewhat different in
+their nature; in the case of the meteors, or the equivalent star dust,
+the coming together of the particles is due to gravitation. In the
+experiment with the cylinder above described, the compression is due
+to mechanical energy, a force of another nature.
+
+There is reason for believing that all our planets, as well as the sun
+itself, and also the myriad other orbs of space, have all passed
+through the stages of a transition in which a continually
+concentrating vapour, drawn together by gravitation, became
+progressively hotter and more dense until it assumed the condition of
+a fluid. This fluid gradually parted with its heat to the cold spaces
+of the heavens, and became more and more concentrated and of a lower
+temperature until in the end, as in the case of our earth and of other
+planets, it ceased to glow on the outside, though it remained
+intensely heated in the inner parts. It is easy to see that the rate
+of this cooling would be in some proportion to the size of the sphere.
+Thus the earth, which is relatively small, has become relatively cold,
+while the sun itself, because of its vastly greater mass, still
+retains an exceedingly high temperature. The reason for this can
+readily be conceived by making a comparison of the rate of cooling
+which occurs in many of our ordinary experiences. Thus a vial of hot
+water will quickly come down to the temperature of the air, while a
+large jug filled with the fluid at the same temperature will retain
+its heat many times as long. The reason for this rests upon the simple
+principle that the contents of a sphere increase with its enlargement
+more rapidly than the surface through which the cooling takes place.
+
+The modern studies on the physical history of the sun and other
+celestial bodies show that their original store of heat is constantly
+flowing away into the empty realms of space. The rate at which this
+form of energy goes away from the sun is vast beyond the powers of the
+imagination to conceive; thus, in the case of our earth, which viewed
+from the sun would appear no more than a small star, the amount of
+heat which falls upon it from the great centre is enough each day to
+melt, if it all could be put to such work, about eight thousand cubic
+miles of ice. Yet the earth receives only 1/2,170,000,000 part of the
+solar radiation. The greater part of this solar heat--in fact, we may
+say nearly all of it--slips by the few and relatively small planets
+and disappears in the great void.
+
+The destiny of all the celestial spheres seems in time to be that
+they shall become cooled down to a temperature far below anything
+which is now experienced on this earth. Even the sun, though its heat
+will doubtless endure for millions of years to come, must in time, so
+far as we can see, become dark and cold. So far as we know, we can
+perceive no certain method by which the life of the slowly decaying
+suns can be restored. It has, however, been suggested that in many
+cases a planetary system which has attained the lifeless and lightless
+stage may by collision with some other association of spheres be by
+the blow restored to its previous state of vapour, the joint mass of
+the colliding systems once again to resume the process of
+concentration through which it had gone before. Now and then stars
+have been seen to flash suddenly into great brilliancy in a way which
+suggests that possibly their heat had been refreshed by a collision
+with some great mass which had fallen into them from the celestial
+spaces. There is room for much speculation in this field, but no
+certainty appears to be attainable.
+
+The ancients believed that light and heat were emanations which were
+given off from the bodies that yielded them substantially as odours
+are given forth by many substances. Since the days of Newton inquiry
+has forced us to the conviction that these effects of temperature are
+produced by vibrations having the general character of waves, which
+are sent through the spaces with great celerity. When a ray of light
+departs from the sun or other luminous body, it does not convey any
+part of the mass; it transmits only motion. A conception of the action
+can perhaps best be formed by suspending a number of balls of ivory,
+stone, or other hard substance each by a cord, the series so arranged
+that they touch each other. Then striking a blow against one end of
+the line, we observe that the ball at the farther end of the line is
+set in motion, swinging a little away from the place it occupied
+before. The movement of the intermediate balls may be so slight as to
+escape attention. We thus perceive that energy can be transmitted
+from one to another of these little spheres. Close observation shows
+us that under the impulse which the blow gives each separate body is
+made to sway within itself much in the manner of a bell when it is
+rung, and that the movement is transmitted to the object with which it
+is in contact. In passing from the sun to the earth, the light and
+heat traverse a space which we know to be substantially destitute of
+any such materials as make up the mass of the earth or the sun. Judged
+by the standards which we can apply, this space must be essentially
+empty. Yet because motions go through it, we have to believe that it
+is occupied by something which has certain of the properties of
+matter. It has, indeed, one of the most important properties of all
+substances, in that it can vibrate. This practically unknown thing is
+called ether.
+
+The first important observational work done by the ancients led them
+to perceive that there was a very characteristic difference between
+the planets and the fixed stars. They noted the fact that the planets
+wandered in a ceaseless way across the heavens, while the fixed stars
+showed little trace of changing position in relation to one another.
+For a long time it was believed that these, as well as the remoter
+fixed stars, revolved about the earth. This error, though great, is
+perfectly comprehensible, for the evident appearance of the movement
+is substantially what would be brought about if they really coursed
+around our sphere. It was only when the true nature of the earth and
+its relations to the sun were understood that men could correct this
+first view. It was not, indeed, until relatively modern times that the
+solar system came to be perceived as something independent and widely
+detached from the fixed stars system; that the spaces which separate
+the members of our own solar family, inconceivably great as they are,
+are but trifling as compared with the intervals which part us from the
+nearer fixed stars. At this stage of our knowledge men came to the
+noble suggestion that each of the fixed stars was itself a sun, each
+of the myriad probably attended by planetary bodies such as exist
+about our own luminary.
+
+It will be well for the student to take an imaginary journey from the
+sun forth into space, along the plane in which extends that vast
+aggregation of stars which we term the Milky Way. Let him suppose that
+his journey could be made with something like the speed of light, or,
+say, at the rate of about two hundred thousand miles a second. It is
+fit that the imagination, which is free to go through all things,
+should essay such excursions. On the fancied outgoing, the observer
+would pass the interval between the sun and the earth in about eight
+minutes. It would require some hours before he attained to the outer
+limit of the solar system. On his direct way he would pass the orbits
+of the several planets. Some would have their courses on one side or
+the other of his path; we should say above or below, but for the fact
+that we leave these terms behind in the celestial realm. On the margin
+of the solar system the sun would appear shrunken to the state where
+it was hardly greater than the more brilliant of the other fixed
+stars. The onward path would then lead through a void which it would
+require years to traverse. Gradually the sun which happened to lie
+most directly in his path would grow larger; with nearer approach, it
+would disclose its planets. Supposing that the way led through this
+solar system, there would doubtless be revealed planets and satellites
+in their order somewhat resembling those of our own solar family, yet
+there would doubtless be many surprises in the view. Arriving near the
+first sun to be visited, though the heavens would have changed their
+shape, all the existing constellations having altered with the change
+in the point of view, there would still be one familiar element in
+that the new-found planets would be near by, and the nearest fixed
+stars far away in the firmament.
+
+With the speed of light a stellar voyage could be taken along the path
+of the Milky Way, which would endure for thousands of years. Through
+all the course the journeyer would perceive the same vast girdle of
+stars, faint because they were far away, which gives the dim light of
+our galaxy. At no point is it probable that he would find the separate
+suns much more aggregated or greatly farther apart than they are in
+that part of the Milky Way which our sun now occupies. Looking forth
+on either side of the "galactic plane," there would be the same
+scattering of stars which we now behold when we gaze at right angles
+to the way we are supposing the spirit to traverse.
+
+As the form of the Milky Way is irregular, the mass, indeed, having
+certain curious divisions and branches, it well might be that the
+supposed path would occasionally pass on one or the other side of the
+vast star layer. In such positions the eye would look forth into an
+empty firmament, except that there might be in the far away, tens of
+thousands of years perhaps at the rate that light travels away from
+the observer, other galaxies or Milky Ways essentially like that which
+he was traversing. At some point the journeyer would attain the margin
+of our star stratum, whence again he would look forth into the
+unpeopled heavens, though even there he might discern other remote
+star groups separated from his own by great void intervals.
+
+                  *       *       *       *       *
+
+The revelations of the telescope show us certain features in the
+constitution and movements of the fixed stars which now demand our
+attention. In the first place, it is plain that not all of these
+bodies are in the same physical condition. Though the greater part of
+these distant luminous masses are evidently in the state of
+aggregation displayed by our own sun, many of them retain more or less
+of that vaporous, it may be dustlike, character which we suppose to
+have been the ancient state of all the matter in the universe. Some of
+these masses appear as faint, almost indistinguishable clouds, which
+even to the greatest telescope and the best-trained vision show no
+distinct features of structure. In other cases the nebulous
+appearance is hardly more than a mist about a tolerably distinct
+central star. Yet again, and most beautifully in the great nebula of
+the constellation of Orion, the cloudy mass, though hardly visible to
+the naked eye, shows a division into many separate parts, the whole
+appearing as if in process of concentration about many distinct
+centres.
+
+The nebulas are reasonably believed by many astronomers to be examples
+of the ancient condition of the physical universe, masses of matter
+which for some reason as yet unknown have not progressed in their
+consolidation to the point where they have taken on the
+characteristics of suns and their attendant planets.
+
+Many of the fixed stars, the incomplete list of which now amounts to
+several hundred, are curiously variable in the amount of light which
+they send out to the earth. Sometimes these variations are apparently
+irregular, but in the greater number of cases they have fixed periods,
+the star waxing and waning at intervals varying from a few months to a
+few years. Although some of the sudden flashings forth of stars from
+apparent small size to near the greatest brilliancy may be due to
+catastrophes such as might be brought about by the sudden falling in
+of masses of matter upon the luminous spheres, it is more likely that
+the changes which we observe are due to the fact that two suns
+revolving around a common centre are in different stages of
+extinction. It may well be that one of these orbs, presumably the
+smaller, has so far lost temperature that it has ceased to glow. If in
+its revolution it regularly comes between the earth and its luminous
+companion, the effect would be to give about such a change in the
+amount of light as we observe.
+
+The supposition that a bright sun and a relatively dark sun might
+revolve around a common centre of gravity may at first sight seem
+improbable. The fact is, however, that imperfect as our observations
+on the stars really are, we know many instances in which this kind of
+revolution of one star about another takes place. In some cases these
+stars are of the same brilliancy, but in others one of the lights is
+much brighter than the other. From this condition to the state where
+one of the stars is so nearly dark as to be invisible, the transition
+is but slight. In a word, the evidence goes to show that while we see
+only the luminous orbs of space, the dark bodies which people the
+heavens are perhaps as numerous as those which send us light, and
+therefore appear as stars.
+
+Besides the greater spheres of space, there is a vast host of lesser
+bodies, the meteorites and comets, which appear to be in part members
+of our solar system, and perhaps of other similar systems, and in part
+wanderers in the vast realm which intervenes between the solar
+systems. Of these we will first consider the meteors, of which we know
+by far the most; though even of them, as we shall see, our knowledge
+is limited.
+
+From time to time on any starry night, and particularly in certain
+periods of the year, we may behold, at the distance of fifty or more
+miles above the surface of the earth, what are commonly called
+"shooting stars." The most of these flashing meteors are evidently
+very small, probably not larger than tiny sand grains, possibly no
+greater than the fragments which would be termed dust. They enter the
+air at a speed of about thirty miles a second. They are so small that
+they burn to vapour in the very great heat arising from their friction
+on the air, and do not attain the surface of the earth. These are so
+numerous that, on the average, some hundreds of thousands probably
+strike the earth's atmosphere each day. From time to time larger
+bodies fall--bodies which are of sufficient bulk not to be burned up
+in the air, but which descend to the ground. These may be from the
+smallest size which may be observed to masses of many hundred pounds
+in weight. These are far less numerous than the dust meteorites; it is
+probable, however, that several hundred fragments each year attain the
+earth's surface. They come from various directions of space, and
+there is as yet no means of determining whether they were formed in
+some manner within our planetary system or whether they wander to us
+from remoter realms. We know that they are in part composed of
+metallic iron commingled with nickel and carbon (sometimes as very
+small diamonds) in a way rarely if ever found on the surface of our
+sphere, and having a structure substantially unknown in its deposits.
+In part they are composed of materials which somewhat resemble certain
+lavas. It is possible that these fragments of iron and stone which
+constitute the meteorites have been thrown into the planetary spaces
+by the volcanic eruption of our own and other planets. If hurled forth
+with a sufficient energy, the fragments would escape from the control
+of the attraction of the sphere whence they came, and would become
+independent wanderers in space, moving around the sun in varied orbits
+until they were again drawn in by some of the greater planets.
+
+As they come to us these meteorites often break up in the atmosphere,
+the bits being scattered sometimes over a wide area of country. Thus,
+in the case of the Cocke County meteorite of Tennessee, one of the
+iron species, the fragments, perhaps thousands in number, which came
+from the explosion of the body were scattered over an area of some
+thousand square miles. When they reach the surface in their natural
+form, these meteors always have a curious wasted and indented
+appearance, which makes it seem likely that they have been subject to
+frequent collisions in their journeys after they were formed by some
+violent rending action.
+
+In some apparent kinship with the meteorites may be classed the
+comets. The peculiarity of these bodies is that they appear in most
+cases to be more or less completely vaporous. Rushing down from the
+depths of the heavens, these bodies commonly appear as faintly
+shining, cloudlike masses. As they move in toward the sun long trails
+of vapour stream back from the somewhat consolidated head. Swinging
+around that centre, they journey again into the outer realm. As they
+retreat, their tail-like streamers appear to gather again upon their
+centres, and when they fade from view they are again consolidated. In
+some cases it has been suspected that a part at least of the cometary
+mass was solid. The evidence goes to show, however, that the matter is
+in a dustlike or vaporous condition, and that the weight of these
+bodies is relatively very small.
+
+[Illustration: Fig. 2.--The Great Comet of 1811, one of the many
+varied forms of these bodies.]
+
+Owing to their strange appearance, comets were to the ancients omens
+of calamity. Sometimes they were conceived as flaming swords; their
+forms, indeed, lend themselves to this imagining. They were thought to
+presage war, famine, and the death of kings. Again, in more modern
+times, when they were not regarded as portents of calamity, it was
+feared that these wanderers moving vagariously through our solar
+system might by chance come in contact with the earth with disastrous
+results. Such collisions are not impossible, for the reason that the
+planets would tend to draw these errant bodies toward them if they
+came near their spheres; yet the chance of such collisions happening
+to the earth is so small that they may be disregarded.
+
+
+                      MOTIONS OF THE SPHERES.
+
+Although little is known of the motions which occur among the
+celestial bodies beyond the sphere of our solar family, that which has
+been ascertained is of great importance, and serves to make it likely
+that all the suns in space are upon swift journeys which in their
+speed equal, if they do not exceed, the rate of motion among the
+planetary spheres, which may, in general, be reckoned at about twenty
+miles a second. Our whole solar system is journeying away from certain
+stars, and in the direction of others which are situated in the
+opposite part of the heavens. The proof of this fact is found in the
+observations which show that on one side of us the stars are
+apparently coming closer together, while on the other side they are
+going farther apart. The phenomenon, in a word, is one of perspective,
+and may be made real to the understanding by noting what takes place
+when we travel down a street along which there are lights. We readily
+note that these lights appear to close in behind us, and widen their
+intervals in the direction in which we journey. By such evidence
+astronomers have become convinced that our sphere, along with the sun
+which controls it, is each second a score of miles away from the point
+where it was before.
+
+There is yet other and most curious evidence which serves to show that
+certain of the stars are journeying toward our part of the heavens at
+great speed, while others are moving away from us by their own proper
+motion. These indications are derived from the study of the lines in
+the light which the spectrum reveals to us when critically examined.
+The position of these cross lines is, as we know, affected by the
+motion of the body whence the light comes, and by close analysis of
+the facts it has been pretty well determined that the distortion in
+their positions is due to very swift motions of the several stars. It
+is not yet certain whether these movements of our sun and of other
+solar bodies are in straight lines or in great circles.
+
+It should be noted that, although the evidence from the spectroscope
+serves to show that the matter in the stars is akin to that of our own
+earth, there is reason to believe that those great spheres differ much
+from each other in magnitude.
+
+We have now set forth some of the important facts exhibited by the
+stellar universe. The body of details concerning that realm is vast,
+and the conclusions drawn from it important; only a part, however, of
+the matter with which it deals is of a nature to be apprehended by the
+student who does not approach it in a somewhat professional way. We
+shall therefore now turn to a description of the portion of the starry
+world which is found in the limits of our solar system. There the
+influences of the several spheres upon our planet are matters of vital
+importance; they in a way affect, if they do not control, all the
+operations which go on upon the surface of the earth.
+
+
+                          THE SOLAR SYSTEM.
+
+We have seen that the matter in the visible universe everywhere tends
+to gather into vast associations which appear to us as stars, and that
+these orbs are engaged in ceaseless motion in journeys through space.
+In only one of these aggregations--that which makes our own solar
+system--are the bodies sufficiently near to our eyes for us, even with
+the resources of our telescopes and other instruments, to divine
+something of the details which they exhibit. In studying what we may
+concerning the family of the sun, the planets, and their satellites,
+we may reasonably be assured that we are tracing a history which with
+many differences is in general repeated in the development of each
+star in the firmament. Therefore the inquiry is one of vast range and
+import.
+
+Following, as we may reasonably do, the nebular hypothesis--a view
+which, though not wholly proved, is eminently probable--we may regard
+our solar system as having begun when the matter of which it is
+composed, then in a finely divided, cloudy state, was separated from
+the similar material which went to make the neighbouring fixed stars.
+The period when our solar system began its individual life was remote
+beyond the possibility of conception. Naturalists are pretty well
+agreed that living beings began to exist upon the earth at least a
+hundred million years ago; but the beginnings of our solar system must
+be placed at a date very many times as remote from the present day.[1]
+
+[Footnote 1: Some astronomers, particularly the distinguished Professor
+Newcomb, hold that the sun can not have been supplying heat as at
+present for more than about ten million years, and that all geological
+time must be thus limited. The geologist believes that this reckoning is
+far too short.]
+
+According to the nebular theory, the original vapour of the solar
+system began to fall in toward its centre and to whirl about that
+point at a time long before the mass had shrunk to the present limits
+of the solar system as defined by the path of the outermost planets.
+At successive stages of the concentration, rings after the manner of
+those of Saturn separated from the disklike mass, each breaking up and
+consolidating into a body of nebulous matter which followed in the
+same path, generally forming rings which became by the same process
+the moons or satellites of the sphere. In this way the sun produced
+eight planets which are known, and possibly others of small size on
+the outer verge of the system which have eluded discovery. According
+to this view, the planetary masses were born in succession, the
+farthest away being the oldest. It is, however, held by an able
+authority that the mass of the solar system would first form a rather
+flat disk, the several rings forming and breaking into planets at
+about the same time. The conditions in Saturn, where the inner ring
+remains parted, favours the view just stated.
+
+Before making a brief statement of the several planets, the asteroids,
+and the satellites, it will be well to consider in a general way the
+motions of these bodies about their centres and about the sun. The
+most characteristic and invariable of these movements is that by which
+each of the planetary spheres, as well as the satellites, describes an
+orbit around the gravitative centre which has the most influence upon
+it--the sun. To conceive the nature of this movement, it will be well
+to imagine a single planet revolving around the sun, each of these
+bodies being perfect spheres, and the two the only members of the
+solar system. In this condition the attraction of the two bodies would
+cause them to circle around a common centre of gravity, which, if the
+planet were not larger or the sun smaller than is the case in our
+solar system, would lie within the mass of the sun. In proportion as
+the two bodies might approach each other in size, the centre of
+gravity would come the nearer to the middle point in a line connecting
+the two spheres. In this condition of a sun with a single planet,
+whatever were the relative size of sun and planet, the orbits which
+they traverse would be circular. In this state of affairs it should be
+noted that each of the two bodies would have its plane of rotation
+permanently in the same position. Even if the spheres were more or
+less flattened about the poles of their axes, as is the case with all
+the planets which we have been able carefully to measure, as well as
+with the sun, provided the axes of rotation were precisely parallel to
+each other, the mutual attraction of the masses would cause no
+disturbance of the spheres. The same would be the case if the polar
+axis of one sphere stood precisely at right angles to that of the
+other. If, however, the spheres were somewhat flattened at the poles,
+and the axes inclined to each other, then the pull of one mass on the
+other would cause the polar axes to keep up a constant movement which
+is called nutation, or nodding.
+
+The reason why this nodding movement of the polar axes would occur
+when these lines were inclined to each other is not difficult to see
+if we remember that the attraction of masses upon each other is
+inversely as the square of the distance; each sphere, pulling on the
+equatorial bulging of the other, pulls most effectively on the part of
+it which is nearest, and tends to draw it down toward its centre. The
+result is that the axes of the attracted spheres are given a wobbling
+movement, such as we may note in the spinning top, though in the toy
+the cause of the motion is not that which we are considering.
+
+If, now, in that excellent field for the experiment we are essaying,
+the mind's eye, we add a second planet outside of the single sphere
+which we have so far supposed to journey about the sun, or rather
+about the common centre of gravity, we perceive at once that we have
+introduced an element which leads to a complication of much
+importance. The new sphere would, of course, pull upon the others in
+the measure of its gravitative value--i.e., its weight. The centre of
+gravity of the system would now be determined not by two distinct
+bodies, but by three. If we conceive the second planet to journey
+around the sun at such a rate that a straight line always connected
+the centres of the three orbs, then the only effect on their
+gravitative centre would be to draw the first-mentioned planet a
+little farther away from the centre of the sun; but in our own solar
+system, and probably in all others, this supposition is inadmissible,
+because the planets have longer journeys to go and also move slower,
+the farther they are from the sun. Thus Mercury completes the circle
+of its year in eighty-eight of our days, while the outermost planet
+requires sixty thousand days (more than one hundred and sixty-four
+years) for the same task. The result is not only that the centre of
+gravity of the system is somewhat displaced--itself a matter of no
+great account--but also that the orbit of the original planet ceases
+to be circled and becomes elliptical, and this for the evident reason
+that the sphere will be drawn somewhat away from the sun when the
+second planet happens to lie in the part of its orbit immediately
+outside of its position, in which case the pull is away from the solar
+centre; while, on the other hand, when the new planet was on the other
+side of the sun, its pull would serve to intensify the attraction
+which drew the first sphere toward the centre of gravity. As the
+pulling action of the three bodies upon each other, as well as upon
+their equatorial protuberances, would vary with every change in their
+relative position, however slight, the variations in the form of their
+orbits, even if the spheres were but three in number, would be very
+important. The consequences of these perturbations will appear in the
+sequel.
+
+In our solar system, though there are but eight great planets, the
+group of asteroids, and perhaps a score of satellites, the variety of
+orbital and axial movement which is developed taxes the computing
+genius of the ablest astronomer. The path which our earth follows
+around the sun, though it may in general and for convenience be
+described as a variable ellipse, is, in fact, a line of such
+complication that if we should essay a diagram of it on the scale of
+this page it would not be possible to represent any considerable part
+of its deviations. These, in fact, would elude depiction, even if the
+draughtsman had a sheet for his drawing as large as the orbit itself,
+for every particle of matter in space, even if it be lodged beyond the
+limits of the farthest stars revealed to us by the telescope,
+exercises a certain attraction, which, however small, is effective on
+the mass of the earth. Science has to render its conclusions in
+general terms, and we can safely take them as such; but in this, as in
+other instances, it is well to qualify our acceptance of the
+statements by the memory that all things are infinitely more
+complicated than we can possibly conceive or represent them to be.
+
+We have next to consider the rotations of the planetary spheres upon
+their axes, together with the similar movement, or lack of it, in the
+case of their satellites. This rotation, according to the nebular
+hypothesis, may be explained by the movements which would set up in
+the share of matter which was at first a ring of the solar nebula, and
+which afterward gathered into the planetary aggregation. The way of it
+may be briefly set forth as follows: Such a ring doubtless had a
+diameter of some million miles; we readily perceive that the particles
+of matter in the outer part of the belt would have a swifter movement
+around the sun than those on the inside. When by some disturbance, as
+possibly by the passage of a great meteoric body of a considerable
+gravitative power, this ring was broken in two, the particles
+composing it on either side would, because of their mutual attraction,
+tend to draw away from the breach, widening that gap until the matter
+of the broken ring was aggregated into a sphere of the star dust or
+vapour. When the nebulous matter originally in the ring became
+aggregated into a spherical form, it would, on account of the
+different rates at which the particles were moving when they came
+together, be the surer to fall in toward the centre, not in straight
+lines, but in curves--in other words, the mass would necessarily take
+on a movement of rotation essentially like that which we have
+described in setting forth the nebular hypothesis.
+
+In the stages of concentration the planetary nebulae might well repeat
+those through which the greater solar mass proceeded. If the volume of
+the material were great, subordinate rings would be formed, which when
+they broke and concentrated would constitute secondary planets or
+satellites, such as our moon. For some reason as yet unknown the outer
+planets--in fact, all those in the solar system except the two inner,
+Venus and Mercury and the asteroids--formed such attendants. All these
+satellite-forming rings have broken and concentrated except the inner
+of Saturn, which remains as an intellectual treasure of the solar
+system to show the history of its development.
+
+To the student who is not seeking the fulness of knowledge which
+astronomy has to offer, but desires only to acquaint himself with the
+more critical and important of the heavenly phenomena which help to
+explain the earth, these features of planetary movement should prove
+especially interesting for the reason that they shape the history of
+the spheres. As we shall hereafter see, the machinery of the earth's
+surface, all the life which it bears, its winds and rains--everything,
+indeed, save the actions which go on in the depths of the sphere--is
+determined by the heat and light which come from the sun. The
+conditions under which this vivifying tide is received have their
+origin in the planetary motion. If our earth's path around the centre
+of the system was a perfect circle, and if its polar axis lay at right
+angles to the plane of its journey, the share of light and heat which
+would fall upon any one point on the sphere would be perfectly
+uniform. There would be no variations in the length of day or night;
+no changes in the seasons; the winds everywhere would blow with
+exceeding steadiness--in fact, the present atmospheric confusion would
+be reduced to something like order. From age to age, except so far as
+the sun itself might vary in the amount of energy which it radiated,
+or lands rose up into the air or sunk down toward the sea level, the
+climate of each region would be perfectly stable. In the existing
+conditions the influences bring about unending variety. First of all,
+the inclined position of the polar axis causes the sun apparently to
+move across the heavens, so that it comes in an overhead position once
+or twice in the year in quite half the area of the lands and seas.
+This apparent swaying to and fro of the sun, due to the inclination of
+the axis of rotation, also affects the width of the climatal belts on
+either side of the equator, so that all parts of the earth receive a
+considerable share of the sun's influence. If the axis of the earth's
+rotation were at right angles to the plane of its orbit, there would
+be a narrow belt of high temperature about the equator, north and
+south of which the heat would grade off until at about the parallels
+of fifty degrees we should find a cold so considerable and uniform
+that life would probably fade away; and from those parallels to the
+poles the conditions would be those of permanent frost, and of days
+which would darken into the enduring night or twilight in the realm
+of the far north and south. Thus the wide habitability of the earth is
+an effect arising from the inclination of its polar axis.
+
+[Illustration: Fig. 3.--Inclination of Planetary Orbits (from
+Chambers).]
+
+As the most valuable impression which the student can receive from his
+study of Nature is that sense of the order which has made possible all
+life, including his own, it will be well for him to imagine, as he may
+readily do, what would be the effect arising from changes in relations
+of earth and sun. Bringing the earth's axis in imagination into a
+position at right angles to the plane of the orbit, he will see that
+the effect would be to intensify the equatorial heat, and to rob the
+high latitudes of the share which they now have. On moving the axis
+gradually to positions where it approaches the plane of the orbit, he
+will note that each stage of the change widens the tropic belt.
+Bringing the polar axis down to the plane of the orbit, one hemisphere
+would receive unbroken sunshine, the other remaining in perpetual
+darkness and cold. In this condition, in place of an equatorial line
+we should have an equatorial point at the pole nearest the sun; thence
+the temperatures would grade away to the present equator, beyond which
+half the earth would be in more refrigerating condition than are the
+poles at the present day. In considering the movements of our planet,
+we shall see that no great changes in the position of the polar axis
+can have taken place. On this account the suggested alterations of the
+axis should not be taken as other than imaginary changes.
+
+It is easy to see that with a circular orbit and with an inclined axis
+winter and summer would normally come always at the same point in the
+orbit, and that these seasons would be of perfectly even length. But,
+as we have before noted, the earth's path around the sun is in its
+form greatly affected by the attractions which are exercised by the
+neighbouring planets, principally by those great spheres which lie in
+the realm without its orbit, Jupiter and Saturn. When these attracting
+bodies, as is the case from time to time, though at long intervals,
+are brought together somewhere near to that part of the solar system
+in which the earth is moving around the sun, they draw our planet
+toward them, and so make its path very elliptical. When, however, they
+are so distributed that their pulling actions neutralize each other,
+the orbit returns more nearly to a circular form. The range in its
+eccentricity which can be brought about by these alterations is very
+great. When the path is most nearly circular, the difference in the
+major and minor axis may amount to as little as about five hundred
+thousand miles, or about one one hundred and eighty-sixth of its
+average diameter. When the variation is greatest the difference in
+these measurements may be as much as near thirteen million miles, or
+about one seventh of the mean width of the orbit.
+
+The first and most evident effect arising from these changes of the
+orbit comes from the difference in the amount of heat which the earth
+may receive according as it is nearer or farther from the sun. As in
+the case of other fires, the nearer a body is to it the larger the
+share of light and heat which it will receive. In an orbit made
+elliptical by the planetary attraction the sun necessarily occupies
+one of the foci of the ellipse. The result is, of course, that the
+side of the earth which is toward the sun, while it is thus brought
+the nearer to the luminary, receives more energy in the form of light
+and heat than come to any part which is exposed when the spheres are
+farther away from each other in the other part of the orbit.
+Computations clearly show that the total amount of heat and the
+attendant light which the earth receives in a year is not affected by
+these changes in the form of its path. While it is true that it
+receives heat more rapidly in the half of the ellipse which is nearest
+the source of the inundation, it obtains less while it is farther
+away, and these two variations just balance each other.
+
+Although the alterations in the eccentricity of its orbit do not vary
+the annual supply of heat which the earth receives, they are capable
+of changing the character of the seasons, and this in the way which we
+will now endeavour to set forth, though we must do it at the cost of
+considerable attention on the part of the reader, for the facts are
+somewhat complicated. In the first place, we must note that the
+ellipticity of the earth's orbit is not developed on fixed lines, but
+is endlessly varied, as we can readily imagine it would be for the
+reason that its form depends upon the wandering of the outer planetary
+spheres which pull the earth about. The longer axis of the ellipse is
+itself in constant motion in the direction in which the earth travels.
+This movement is slow, and at an irregular rate. It is easy to see
+that the effect of this action, which is called the revolution of the
+apsides, or, as the word means, the movement of the poles of the
+ellipse, is to bring the earth, when a given hemisphere is turned
+toward the sun, sometimes in the part of the orbit which is nearest
+the source of light and heat, and sometimes farther away. It may thus
+well come about that at one time the summer season of a hemisphere
+arrives when it is nearest the sun, so that the season, though hot,
+will be very short, while at another time the same season will arrive
+when the earth is farthest from the sun, and receives much less heat,
+which would tend to make a long and relatively cool summer. The reason
+for the difference in length of the seasons is to be found in the
+relative swiftness of the earth's revolution when it is nearest the
+sun, and the slowness when it is farther away.
+
+There is a further complication arising from that curious phenomenon
+called the precession of the equinoxes, which has to be taken into
+account before we can sufficiently comprehend the effect of the
+varying eccentricity of the orbit on the earth's seasons. To
+understand this feature of precession we should first note that it
+means that each year the change from the winter to the summer--or, as
+we phrase it, the passage of the equinoctial line--occurs a little
+sooner than the year before. The cause of this is to be found in the
+attraction which the heavenly bodies, practically altogether the moon,
+exercises on the equatorial protuberance of the earth. We know that
+the diameter of our sphere at the equator is, on the average,
+something more than twenty-six miles greater than it is through the
+poles. We know, furthermore, that the position of the moon in relation
+to the earth is such that it causes the attraction on one half of this
+protuberance to be greater than it is upon the other. We readily
+perceive that this action will cause the polar axis to make a certain
+revolution, or, what comes to the same thing, that the plane of the
+equator will constantly be altering its position. Now, as the
+equinoctial points in the orbit depend for their position upon the
+attitude of the equatorial plane, we can conceive that the effect is a
+change in position of the place in that orbit where summer and winter
+begin. The actual result is to bring the seasonal points backward,
+step by step, through the orbit in a regular measure until in
+twenty-two thousand five hundred years they return to the place where
+they were before. This cycle of change was of old called the Annus
+Magnus, or great year.
+
+If the earth's orbit were an ellipse, the major axis of which remained
+in the same position, we could readily reckon all the effects which
+arise from the variations of the great year. But this ellipse is ever
+changing in form, and in the measure of its departure from a circle
+the effects on the seasons distributed over a great period of time are
+exceedingly irregular. Now and then, at intervals of hundreds of
+thousands or millions of years, the orbit becomes very elliptical;
+then again for long periods it may in form approach a circle. When in
+the state of extreme ellipticity, the precession of the equinoxes will
+cause the hemispheres in turn each to have their winter and summer
+alternately near and far from the sun. It is easily seen that when the
+summer season comes to a hemisphere in the part of the orbit which is
+then nearest the sun the period will be very hot. When the summer
+came farthest from the sun that part of the year would have the
+temperature mitigated by its removal to a greater distance from the
+source of heat. A corresponding effect would be produced in the winter
+season. As long as the orbit remained eccentric the tendency would be
+to give alternately intense seasons to each hemisphere through periods
+of about twelve thousand years, the other hemisphere having at the
+same time a relatively slight variation in the summer and winter.
+
+At first sight it may seem to the reader that these studies we have
+just been making in matters concerning the shape of the orbit and the
+attendant circumstances which regulate the seasons were of no very
+great consequence; but, in the opinion of some students of climate, we
+are to look to these processes for an explanation of certain climatal
+changes on the earth, including the Glacial periods, accidents which
+have had the utmost importance in the history of man, as well as of
+all the other life of the planet.
+
+It is now time to give some account as to what is known concerning the
+general conditions of the solar bodies--the planets and satellites of
+our own celestial group. For our purpose we need attend only to the
+general physical state of these orbs so far as it is known to us by
+the studies of astronomers. The nearest planet to the sun is Mercury.
+This little sphere, less than half the diameter of our earth, is so
+close to the sun that even when most favourably placed for observation
+it is visible for but a few minutes before sunrise and after sunset.
+Although it may without much difficulty be found by the ordinary eye,
+very few people have ever seen it. To the telescope when it is in the
+_full moon_ state it appears as a brilliant disk; it is held by most
+astronomers that the surface which we see is made up altogether of
+clouds, but this, as most else that has been stated concerning this
+planet, is doubtful. The sphere is so near to the sun that if it were
+possessed of water it would inevitably bear an atmosphere full of
+vapour. Under any conceivable conditions of a planet placed as
+Mercury is, provided it had an atmosphere to retain the heat, its
+temperature would necessarily be very high. Life as we know it could
+not well exist upon such a sphere.
+
+Next beyond Mercury is Venus, a sphere only a little less in diameter
+than the earth. Of this sphere we know more than we do of Mercury, for
+the reason that it is farther from the sun and so appears in the
+darkened sky. Most astronomers hold that the surface of this planet
+apparently is almost completely and continually hidden from us by what
+appears to be a dense cloud envelope, through which from time to time
+certain spots appear of a dark colour. These, it is claimed, retain
+their place in a permanent way; it is, indeed, by observing them that
+the rotation period of the planet has, according to some observers,
+been determined. It therefore seems likely that these spots are the
+summits of mountains, which, like many of our own earth, rise above
+the cloud level.
+
+Recent observations on Venus made by Mr. Percival Lowell appear to
+show that the previous determinations of the rotation of that planet,
+as well as regards its cloud wrap, are in error. According to these
+observations, the sphere moves about the sun, always keeping the same
+side turned toward the solar centre, just as the moon does in its
+motion around the earth. Moreover, Mr. Lowell has failed to discover
+any traces of clouds upon the surface of the planet. As yet these
+results have not been verified by the work of other astronomers;
+resting, however, as they do on studies made with an excellent
+telescope and in the very translucent and steady air of the Flagstaff
+Station, they are more likely to be correct than those obtained by
+other students. If it be true that Venus does not turn upon its axis,
+such is likely to be the case also with the planet Mercury.
+
+Next in the series of the planets is our own earth. As the details of
+this planet are to occupy us during nearly all the remainder of this
+work, we shall for the present pass it by.
+
+Beyond the earth we pass first to the planet Mars, a sphere which has
+already revealed to us much concerning its peculiarities of form and
+physical state, and which is likely in the future to give more
+information than we shall obtain from any other of our companions in
+space, except perhaps the moon. Mars is not only nearer to us than any
+other planet, but it is so placed that it receives the light of the
+sun under favourable conditions for our vision. Moreover, its sky
+appears to be generally almost cloudless, so that when in its orbital
+course the sphere is nearest our earth it is under favourable
+conditions for telescopic observation. At such times there is revealed
+to the astronomer a surface which is covered with an amazing number of
+shadings and markings which as yet have been incompletely interpreted.
+The faint nature of these indications has led to very contradictory
+statements as to their form; no two maps which have been drawn agree
+except in their generalities. There is reason to believe that Mars has
+an atmosphere; this is shown by the fact that in the appropriate
+season the region about either pole is covered by a white coating,
+presumably snow. This covering extends rather less far toward the
+planet's equator than does the snow sheet on our continents. Taking
+into account the colour of the coating, and the fact that it
+disappears when the summer season comes to the hemisphere in which it
+was formed, we are, in fact, forced to believe that the deposit is
+frozen water, though it has been suggested that it may be frozen
+carbonic acid. Taken in connection with what we have shortly to note
+concerning the apparent seas of this sphere, the presumption is
+overwhelmingly to the effect that Mars has seasons not unlike our own.
+
+The existence of snow on any sphere may safely be taken as evidence
+that there is an atmosphere. In the case of Mars, this supposition is
+borne out by the appearance of its surface. The ruddy light which it
+sends back to us, and the appearance on the margin of the sphere,
+which is somewhat dim, appears to indicate that its atmosphere is
+dense. In fact, the existence of an atmosphere much denser than that
+of our own earth appears to be demanded by the fact that the
+temperatures are such as to permit the coming and going of snow. It is
+well known that the temperature of any point on the earth, other
+things being equal, is proportionate to the depth of atmosphere above
+its surface. If Mars had no more air over its surface than has an
+equal area of the earth, it would remain at a temperature so low that
+such seasonal changes as we have observed could not take place. The
+planet receives one third less heat than an equal area of the earth,
+and its likeness to our own temperature, if such exists, is doubtless
+brought about by the greater density of its atmosphere, that serves to
+retain the heat which comes upon its surface. The manner in which this
+is effected will be set forth in the study of the earth's atmosphere.
+
+[Illustration: Fig. 4.--Mars, August 27, 1892 (Guiot), the white patch
+is the supposed Polar Snow Cap.]
+
+As is shown by the maps of Mars, the surface is occupied by shadings
+which seem to indicate the existence of water and lands. Those
+portions of the area which are taken to be land are very much divided
+by what appear to be narrow seas. The general geographic conditions
+differ much from those of our own sphere in that the parts of the
+planet about the water level are not grouped in great continents, and
+there are no large oceans. The only likeness to the conditions of our
+earth which we can perceive is in a general pointing of the somewhat
+triangular masses of what appears to be land toward one pole. As a
+whole, the conditions of the Martial lands and seas as regards their
+form, at least, is more like that of Europe than that of any other
+part of the earth's surface. Europe in the early Tertiary times had a
+configuration even more like that of Mars than it exhibits at present,
+for in that period the land was very much more divided than it now is.
+
+If the lands of Mars are framed as are those of our own earth, there
+should be ridges of mountains constituting what we may term the
+backbones of the continent. As yet such have not been discerned, which
+may be due to the fact that they have not been carefully looked for.
+The only peculiar physical features which have as yet been discerned
+on the lands of Mars are certain long, straight, rather narrow
+crevicelike openings, which have received the name of "canals." These
+features are very indistinct, and are just on the limit of visibility.
+As yet they have been carefully observed by but few students, so that
+their features are not yet well recorded; as far as we know them,
+these fissures have no likeness in the existing conditions of our
+earth. It is difficult to understand how they are formed or preserved
+on a surface which is evidently subjected to rainfalls.
+
+It will require much more efficient telescopes than we now have before
+it will be possible to begin any satisfactory study on the geography
+of this marvellous planet. We can not hope as yet to obtain any
+indications as to the details of its structure; we can not see closely
+enough to determine whether rivers exist, or whether there is a
+coating which we may interpret as vegetation, changing its hues in the
+different seasons of the year. An advance in our instruments of
+research during the coming century, if made with the same speed as
+during the last, will perhaps enable us to interpret the nature of
+this neighbour, and thereby to extend the conception of planetary
+histories which we derive from our own earth.
+
+[Illustration: Fig. 5.--Comparative Sizes of the Planets (Chambers).]
+
+Beyond Mars we find one of the most singular features of our solar
+system in a group of small planetary bodies, the number of which now
+known amounts to some two hundred, and the total may be far greater.
+These bodies are evidently all small; it is doubtful if the largest is
+three hundred and the smaller more than twenty miles in diameter. So
+far as it has been determined by the effect of their aggregate mass in
+attracting the other spheres, they would, if put together, make a
+sphere far less in diameter than our earth, perhaps not more than five
+hundred miles through. The forms of these asteroids is as yet unknown;
+we therefore can not determine whether their shapes are spheroidal, as
+are those of the other planets, or whether they are angular bits like
+the meteorites. We are thus not in a position to conjecture whether
+their independence began when the nebulous matter of the ring to which
+they belonged was in process of consolidation, or whether, after the
+aggregation of the sphere was accomplished, and the matter solidified,
+the mass was broken into bits in some way which we can not yet
+conceive. It has been conjectured that such a solid sphere might have
+been driven asunder by a collision with some wandering celestial body;
+but all we can conceive of such actions leads us to suppose that a
+blow of this nature would tend to melt or convert materials subjected
+to it into the state of vapour, rather than to drive them asunder in
+the manner of an explosion.
+
+The four planets which lie beyond the asteroids give us relatively
+little information concerning their physical condition, though they
+afford a wide field for the philosophic imagination. From this point
+of view the reader is advised to consult the writings of the late R.A.
+Proctor, who has brought to the task of interpreting the planetary
+conditions the skill of a well-trained astronomer and a remarkable
+constructive imagination.
+
+The planet Jupiter, by far the largest of the children of the sun,
+appears to be still in a state where its internal heat has not so far
+escaped that the surface has cooled down in the manner of our earth.
+What appear to be good observations show that the equatorial part of
+its area, at least, still glows from its own heat. The sphere is
+cloud-wrapped, but it is doubtful whether the envelope be of watery
+vapour; it is, indeed, quite possible that besides such vapour it may
+contain some part of the many substances which occupy the atmosphere
+of the sun. If the Jovian sphere were no larger than the earth, it
+would, on account of its greater age, long ago have parted with its
+heat; but on account of its great size it has been able,
+notwithstanding its antiquity, to retain a measure of temperature
+which has long since passed away from our earth.
+
+In the case of Saturn, the cloud bands are somewhat less visible than
+on Jupiter, but there is reason to suppose in this, as in the
+last-named planet, that we do not behold the more solid surface of the
+sphere, but see only a cloud wrap, which is probably due rather to the
+heat of the sphere itself than to that which comes to it from the sun.
+At the distance of Saturn from the centre of the solar system a given
+area of surface receives less than one ninetieth of the sun's heat as
+compared with the earth; therefore we can not conceive that any
+density of the atmosphere whatever would suffice to hold in enough
+temperature to produce ordinary clouds. Moreover, from time to time
+bright spots appear on the surface of the planet, which must be due to
+some form of eruptions from its interior.
+
+Beyond Saturn the two planets Uranus and Neptune, which occupy the
+outer part of the solar system, are so remote that even our best
+telescopes discern little more than their presence, and the fact that
+they have attendant moons.
+
+From the point of view of astronomical science, the outermost planet
+Neptune, of peculiar interest for the reason that it was, as we may
+say, discovered by computation. Astronomers had for many years
+remarked the fact that the next inner planetary sphere exhibited
+peculiarities in its orbit which could only be accounted for on the
+supposition that it was subjected to the attraction of another
+wandering body which had escaped observation. By skilful computation
+the place in the heavens in which this disturbing element lay was so
+accurately determined that when the telescope was turned to the given
+field a brief study revealed the planet. Nothing else in the history
+of the science of astronomy, unless it be the computation of eclipses,
+so clearly and popularly shows the accuracy of the methods by which
+the work of that science may be done.
+
+As we shall see hereafter, in the chapters which are devoted to
+terrestrial phenomena, the physical condition of the sun determines
+the course of all the more important events which take place on the
+surface of the earth. It is therefore fit that in this preliminary
+study of the celestial bodies, which is especially designed to make
+the earth more interpretable to us, we should give a somewhat special
+attention to what is known under the title of "Solar Physics."
+
+The reader has already been told that the sun is one of many million
+similar bodies which exist in space, and, furthermore, that these
+aggregations of matter have been developed from an original nebulous
+condition. The facts indicate that the natural history of the sun, as
+well as that of its attendant spheres, exhibits three momentous
+stages: First, that of vapour; second, that of igneous fluidity;
+third, that in which the sphere is so far congealed that it becomes
+dark. Neither of these states is sharply separated from the other; a
+mass may be partly nebulous and partly fluid; even when it has been
+converted into fluid, or possibly into the solid state, it may still
+retain on the exterior some share of its original vaporous condition.
+In our sun the concentration has long since passed beyond the limits
+of the nebulous state; the last of the successively developed rings
+has broken, and has formed itself into the smallest of the planets,
+which by its distance from the sun seems to indicate that the process
+of division by rings long ago attained in our solar system its end,
+the remainder of its nebulous material concentrating on its centre
+without sign of any remaining tendency to produce these planet-making
+circles.
+
+
+                   THE CONSTITUTION OF THE SUN.
+
+Before the use of the telescope in astronomical work, which was begun
+by the illustrious Galileo in 1608, astronomers were unable to
+approach the problem of the structure of the sun. They could discern
+no more than can be seen by any one who looks at the great sphere
+through a bit of smoked glass, as we know this reveals a disklike body
+of very uniform appearance. The only variation in this simple aspect
+occurs at the time of a total eclipse, when for a minute or two the
+moon hides the whole body of the sun. On such occasions even the
+unaided eye can see that there is about the sphere a broad, rather
+bright field, of an aspect like a very thin cloud or fog, which rises
+in streamer like projections at points to a quarter of a million miles
+or more above the surface of the sphere. The appearance of this
+shining field, which is called the corona, reminds one of the aurora
+which glows in the region about either pole of the earth.
+
+One of the first results of the invention of the telescope was the
+revelation of the curious dark objects on the sun's disk, known by the
+name of spots from the time of their discovery, or, at least, from the
+time when it was clearly perceived that they were not planets, but
+really on the solar body. The interest in the constitution of the
+sphere has increased during the last fifty years. This interest has
+rapidly grown until at the present time a vast body of learning has
+been gathered for the solution of the many problems concerning the
+centre of our system. As yet there is great divergence in the views of
+astronomers as to the interpretation of their observations, but
+certain points of great general interest have been tolerably well
+determined. These may be briefly set forth by an account of what would
+meet the eye if an observer were able to pass from the surface of the
+earth to the central part of the sun.
+
+[Illustration: _Lava stream, in Hawaiian Islands, flowing into the
+sea. Note the "ropy" character of the half-frozen rock on the sides of
+the nearest rivulet of the lava._]
+
+In passing from the earth to a point about a quarter of a million
+miles from the sun's surface--a distance about that of the moon from
+our sphere--the observer would traverse the uniformly empty spaces of
+the heavens, where, but for the rare chance of a passing meteorite or
+comet, there would be nothing that we term matter. Arriving at a point
+some two or three hundred thousand miles from the body of the sun, he
+would enter the realm of the corona; here he would find scattered
+particles of matter, the bits so far apart that there would perhaps be
+not more than one or two in the cubic mile; yet, as they would glow
+intensely in the central light, they would be sufficient to give the
+illumination which is visible in an eclipse. These particles are most
+likely driven up from the sun by some electrical action, and are
+constantly in motion, much as are the streamers of the aurora.
+
+Below the corona and sharply separated from it the observer finds
+another body of very dense vapour, which is termed the chromosphere,
+and which has been regarded as the atmosphere of the sun. This layer
+is probably several thousand miles thick. From the manner in which it
+moves, in the way the air of our own planet does in great storms, it
+is not easy to believe that it is a fluid, yet its sharply defined
+upper surface leads us to suppose that it can not well be a mere mass
+of vapour. The spectroscope shows us that this chromosphere contains
+in the state of vapour a number of metallic substances, such as iron
+and magnesium. To an observer who could behold this envelope of the
+sun from the distance at which we see the moon, the spectacle would be
+more magnificent than the imagination, guided by the sight of all the
+relatively trifling fractures of our earth, can possibly conceive.
+From the surface of the fiery sea vast uprushes of heated matter rise
+to the height of two or three hundred thousand miles, and then fall
+back upon its surface. These jets of heated matter have the aspect of
+flames, but they would not be such in fact, for the materials are not
+burning, but merely kept at a high temperature by the heat of the
+great sphere beneath. They spring up with such energy that they at
+times move with a speed of one hundred and fifty miles a second, or at
+a rate which is attained by no other matter in the visible universe,
+except that strange, wandering star known to astronomers as
+"Grombridge, 1830," which is traversing the firmament with a speed of
+not less than two hundred miles a second.
+
+Below the chromosphere is the photosphere, the lower envelope of the
+sun, if it be not indeed the body of the sphere itself; from this
+comes the light and heat of the mass. This, too, can not well be a
+firm-set mass, for the reason that the spots appear to form in and
+move over it. It may be regarded as an extremely dense mass of gas, so
+weighed down by the vast attraction of the great sphere below it that
+it is in effect a fluid. The near-at-hand observer would doubtless
+find this photosphere, as it appears in the telescope, to be sharply
+separated from the thinner and more vaporous envelopes--the
+chromosphere and the corona--which are, indeed, so thin that they are
+invisible even with the telescope, except when the full blaze of the
+sun is cut off in a total eclipse. The fact that the photosphere,
+except when broken by the so-called spots, lies like a great smooth
+sea, with no parts which lie above the general line, shows that it has
+a very different structure from the envelope which lies upon it. If
+they were both vaporous, there would be a gradation between them.
+
+On the surface of the photosphere, almost altogether within thirty
+degrees of the equator of the sun, a field corresponding approximately
+to the tropical belt of the earth, there appear from time to time the
+curious disturbances which are termed spots. These appear to be
+uprushes of matter in the gaseous state, the upward movement being
+upon the margins of the field and a downward motion taking place in
+the middle of the irregular opening, which is darkened in its central
+part, thus giving it, when seen by an ordinary telescope, the aspect
+of a black patch on the glowing surface. These spots, which are from
+some hundred to some thousand miles in diameter, may endure for
+months before they fade away. It is clear that they are most abundant
+at intervals of about eleven years, the last period of abundance being
+in 1893. The next to come may thus be expected in 1904. In the times
+of least spotting more than half the days of a year may pass without
+the surface of the photosphere being broken, while in periods of
+plenty no day in the year is likely to fail to show them.
+
+[Illustration: Fig. 6.--Ordinary Sun-spot, June 22, 1885.]
+
+It is doubtful if the closest seeing would reveal the cause of the
+solar spots. The studies of the physicists who have devoted the most
+skill to the matter show little more than that they are tumults in the
+photosphere, attended by an uprush of vapours, in which iron and other
+metals exist; but whether these movements are due to outbreaks from
+the deeper parts of the sun or to some action like the whirling storms
+of the earth's atmosphere is uncertain. It is also uncertain what
+effect these convulsions of the sun have on the amount of the heat and
+light which is poured forth from the orb. The common opinion that the
+sun-spot years are the hottest is not yet fully verified.
+
+Below the photosphere lies the vast unknown mass of the unseen solar
+realm. It was at one time supposed that the dark colour of the spots
+was due to the fact that the photosphere was broken through in those
+spaces, and that we looked down through them upon the surface of the
+slightly illuminated central part of the sphere. This view is
+untenable, and in its place we have to assume that for the eight
+hundred and sixty thousand miles of its diameter the sun is composed
+of matter such as is found in our earth, but throughout in a state of
+heat which vastly exceeds that known on or in our planet. Owing to its
+heat, this matter is possibly not in either the solid or the fluid
+state, but in that of very compressed gases, which are kept from
+becoming solid or even fluid by the very high temperature which exists
+in them. This view is apparently supported by the fact that, while the
+pressure upon its matter is twenty-seven times greater in the sun than
+it is in the earth, the weight of the whole mass is less than we
+should expect under these conditions.
+
+As for the temperature of the sun, we only know that it is hot enough
+to turn the metals into gases in the manner in which this is done in a
+strong electric arc, but no satisfactory method of reckoning the scale
+of this heat has been devised. The probabilities are to the effect
+that the heat is to be counted by the tens of thousands of degrees
+Fahrenheit, and it may amount to hundreds of thousands; it has,
+indeed, been reckoned as high as a million degrees. This vast
+discharge is not due to any kind of burning action--i.e., to the
+combustion of substances, as in a fire. It must be produced by the
+gradual falling in of the materials, due to the gravitation of the
+mass toward its centre, each particle converting its energy of
+position into heat, as does the meteorite when it comes into the air.
+
+It is well to close this very imperfect account of the learning which
+relates to the sun with a brief tabular statement showing the relative
+masses of the several bodies of the solar system. It should be
+understood that by mass is meant not the bulk of the object, but the
+actual amount of matter in it as determined by the gravitative
+attraction which it exercises on other celestial bodies. In this test
+the sun is taken as the measure, and its mass is for convenience
+reckoned at 1,000,000,000.
+
+
+             TABLE OF RELATIVE MASSES OF SUN AND PLANETS.[2]
+    +------------------------------------------------------------+
+    |  The sun                                    1,000,000,000  |
+    |  Mercury                                              200  |
+    |  Venus                                              2,353  |
+    |  Earth                                              3,060  |
+    |  Mars                                                 339  |
+    |  Asteroids                                              ?  |
+    |  Saturn                                           285,580  |
+    |  Jupiter                                          954,305  |
+    |  Uranus                                            44,250  |
+    |  Neptune                                           51,600  |
+    |    Combined mass of the four inner planets          5,952  |
+    |    Combined mass of all the planets             1,341,687  |
+    +------------------------------------------------------------+
+
+[Footnote 2: See Newcomb's Popular Astronomy, p. 234. Harper Brothers,
+New York.]
+
+
+It thus appears that the mass of all the planets is about one seven
+hundredth that of the sun.
+
+Those who wish to make a close study of celestial geography will do
+well to procure the interesting set of diagrams prepared by the late
+James Freeman Clarke, in which transparencies placed in a convenient
+lantern show the grouping of the important stars in each
+constellation. The advantage of this arrangement is that the little
+maps can be consulted at night and in the open air in a very
+convenient manner. After the student has learned the position of a
+dozen of the constellations visible in the northern hemisphere, he can
+rapidly advance his knowledge in the admirable method invented by Dr.
+Clarke.
+
+Having learned the constellations, the student may well proceed to
+find the several planets, and to trace them in their apparent path
+across the fixed stars. It will be well for him here to gain if he can
+the conception that their apparent movement is compounded of their
+motion around the sun and that of our own sphere; that it would be
+very different if our earth stood still in the heavens. At this stage
+he may well begin to take in mind the evidence which the planetary
+motion supplies that the earth really moves round the sun, and not
+the sun and planets round the earth. This discovery was one of the
+great feats of the human mind; it baffled the wits of the best men for
+thousands of years. Therefore the inquirer who works over the evidence
+is treading one of the famous paths by which his race climbed the
+steeps of science.
+
+The student must not expect to find the evidence that the sun is the
+centre of the solar system very easy to interpret; and yet any youth
+of moderate curiosity, and that interest in the world about him which
+is the foundation of scientific insight, can see through the matter.
+He will best begin his inquiries by getting a clear notion of the fact
+that the moon goes round the earth. This is the simplest case of
+movements of this nature which he can see in the solar system. Noting
+that the moon occupies a different place at a given hour in the
+twenty-four, but is evidently at all times at about the same distance
+from the earth, he readily perceives that it circles about our sphere.
+This the people knew of old, but they made of it an evidence that the
+sun also went around our sphere. Here, then, is the critical point.
+Why does the sun not behave in the same manner as the moon? At this
+stage of his inquiry the student best notes what takes place in the
+motions of the planets between the earth and the sun. He observes that
+those so-called inferior planets Mercury and Venus are never very far
+away from the central body; that they appear to rise up from it, and
+then to go back to it, and that they have phases like the moon. Now
+and then Venus may be observed as a black spot crossing the disk of
+the sun. A little consideration will show that on the theory that
+bodies revolve round each other in the solar system these movements of
+the inner planets can only be explained on the supposition that they
+at least travel around the great central fire. Now, taking up the
+outer planets, we observe that they occasionally appear very bright,
+and that they are then at a place in the heavens where we see that
+they are far from the solar centre. Gradually they move down toward
+the sunset and disappear from view. Here, too, the movement, though
+less clearly so, is best reconcilable with the idea that these bodies
+travel in orbits, such as those which are traversed by the inner
+planets. The wonder is that with these simple facts before them, and
+with ample time to think the matter over, the early astronomers did
+not learn the great truth about the solar system--namely, that the sun
+is the centre about which the planets circled. Their difficulty lay
+mainly in the fact that they did not conceive the earth as a sphere,
+and even after they attained that conception they believed that our
+globe was vastly larger than the planets, or even than the sun. This
+misconception kept even the thoughtful Greeks, who knew that the earth
+was spherical in form, from a clear notion as to the structure of our
+system. It was not, indeed, until mathematical astronomy attained a
+considerable advance, and men began to measure the distances in the
+solar system, and until the Newtonian theory of gravitation was
+developed, that the planetary orbits and the relation of the various
+bodies in the solar system to each other could be perfectly discerned.
+
+Care has been taken in the above statements to give the student
+indices which may assist him in working out for himself the evidence
+which may properly lead a person, even without mathematical
+considerations of a formal kind, to construct a theory as to the
+relation of the planets to the sun. It is not likely that he can go
+through all the steps of this argument at once, but it will be most
+useful to him to ponder upon the problem, and gradually win his way to
+a full understanding of it. With that purpose in mind, he should avoid
+reading what astronomers have to say on the matter until he is
+satisfied that he has done as much as he can with the matter on his
+own account. He should, however, state his observations, and as far as
+possible draw the results in his note-book in a diagrammatic form. He
+should endeavour to see if the facts are reconcilable with any other
+supposition than that the earth and the other planets move around the
+sun. When he has done his task, he will have passed over one of the
+most difficult roads which his predecessors had to traverse on their
+way to an understanding of the heavens. Even if he fail he will have
+helped himself to some large understandings.
+
+The student will find it useful to make a map of the heavens, or
+rather make several representing their condition at different times in
+the year. On this plot he should put down only the stars whose places
+and names he has learned, but he should plot the position of the
+planets at different times. In this way, though at first his efforts
+will be very awkward, he will soon come to know the general geography
+of the heavens.
+
+Although the possession or at least the use of a small astronomical
+telescope is a great advantage to a student after he has made a
+certain advance in his work, such an instrument is not at all
+necessary, or, indeed, desirable at the outset of his studies. An
+ordinary opera-glass, however, will help him in picking out the stars
+in the constellations, in identifying the planets, and in getting a
+better idea as to the form of the moon's surface--a matter which will
+be treated in this work in connection with the structure of the earth.
+
+
+
+
+                            CHAPTER IV.
+
+                             THE EARTH.
+
+
+In beginning the study of the earth it is important that the student
+should at once form the habit of keeping in mind the spherical form of
+the planet. Many persons, while they may blindly accept the fact that
+the earth is a sphere, do not think of it as having that form. Perhaps
+the simplest way of securing the correct image of the shape is to
+imagine how the earth would appear as seen from the moon. In its full
+condition the moon is apt to appear as a disk. When it is new, and
+also when in its waning stages it is visible in the daytime, the
+spherical form is very apparent. Imagining himself on the surface of
+the moon, the student can well perceive how the earth would appear as
+a vast body in the heavens; its eight thousand miles of diameter,
+about four times that of the satellite, would give an area sixteen
+times the size which the moon presents to us. On this scale the
+continents and oceans would appear very much more plain than do the
+relatively slight irregularities on the lunar surface.
+
+With the terrestrial globe in hand, the student can readily construct
+an image which will represent, at least in outline, the appearance
+which the sphere he inhabits would present when seen from a distance
+of about a quarter of a million miles away. The continent of
+Europe-Asia would of itself appear larger than all the lunar surface
+which is visible to us. Every continent and all the greater islands
+would be clearly indicated. The snow covering which in the winter of
+the northern hemisphere wraps so much of the land would be seen to
+come and go in the changes of the seasons; even the permanent ice
+about either pole, and the greater regions of glaciers, such as those
+of the Alps and the Himalayas, would appear as brilliant patches of
+white amid fields of darker hue. Even the changes in the aspect of the
+vegetation which at one season clothes the wide land with a green
+mantle, and at another assumes the dun hue of winter, would be, to the
+unaided eye, very distinct. It is probable that all the greater rivers
+would be traceable as lines of light across the relatively dark
+surface of the continents. By such exercises of the constructive
+imagination--indeed, in no other way--the student can acquire the
+habit of considering the earth as a vast whole. From time to time as
+he studies the earth from near by he should endeavour to assemble the
+phenomena in the general way which we have indicated.
+
+The reader has doubtless already learned that the earth is a slightly
+flattened sphere, having an average diameter of about eight thousand
+miles, the average section at the equator being about twenty-six miles
+greater than that from pole to pole. In a body of such large
+proportions this difference in measurement appears not important; it
+is, however, most significant, for it throws light upon the history of
+the earth's mass. Computation shows that the measure of flattening at
+the poles is just what would occur if the earth were or had been at
+the time when it assumed its present form in a fluid condition. We
+readily conceive that a soft body revolving in space, while all its
+particles by gravitation tended to the centre, would in turning
+around, as our earth does upon its axis, tend to bulge out in those
+parts which were remote from the line upon which the turning took
+place. Thus the flattening of our sphere at the poles corroborates the
+opinion that its mass was once molten--in a word, that its ancient
+history was such as the nebular theory suggests.
+
+Although we have for convenience termed the earth a flattened
+spheroid, it is only such in a very general sense. It has an infinite
+number of minor irregularities which it is the province of the
+geographer to trace and that of the geologist to account for. In the
+first place, its surface is occupied by a great array of ridges and
+hollows. The larger of these, the oceans and continents, first deserve
+our attention. The difference in altitude of the earth's surface from
+the height of the continents to the deepest part of the sea is
+probably between ten and eleven miles, thus amounting to about two
+fifths of the polar flattening before noted. The average difference
+between the ocean floor and the summits of the neighbouring continents
+is probably rather less than four miles. It happens, most fortunately
+for the history of the earth, that the water upon its surface fills
+its great concavities on the average to about four fifths of their
+total depth, leaving only about one fifth of the relief projecting
+above the ocean level. We have termed this arrangement fortunate, for
+it insures that rainfall visits almost all the land areas, and thereby
+makes those realms fit for the uses of life. If the ocean had only
+half its existing area, the lands would be so wide that only their
+fringes would be fertile. If it were one fifth greater than it is, the
+dry areas would be reduced to a few scattered islands.
+
+From all points of view the most important feature of the earth's
+surface arises from its division into land and water areas, and this
+for the reason that the physical and vital work of our sphere is
+inevitably determined by this distribution. The shape of the seas and
+lands is fixed by the positions at which the upper level of the great
+water comes against the ridges which fret the earth's surface. These
+elevations are so disposed that about two thirds of the hard mass is
+at the present time covered with water, and only one third exposed to
+the atmosphere. This proportion is inconstant. Owing to the endless
+up-and-down goings of the earth's surface, the place of the shore
+lines varies from year to year, and in the geological ages great
+revolutions in the forms and relative area of water and land are
+brought about.
+
+Noting the greater divisions of land and water as they are shown on a
+globe, we readily perceive that those parts of the continental ridges
+which rise above the sea level are mainly accumulated in the northern
+hemisphere--in fact, far more than half the dry realm is in that part
+of the world. We furthermore perceive that all the continents more or
+less distinctly point to the southward; they are, in a word,
+triangles, with their bases to the northward, and their apices,
+usually rather acute, directed to the southward. This form is very
+well indicated in three of the great lands, North and South America
+and Africa; it is more indistinctly shown in Asia and in Australia. As
+yet we do not clearly understand the reason why the continents are
+triangular, why they point toward the south pole, or why they are
+mainly accumulated in the northern hemisphere. As stated in the
+chapter on astronomy, some trace of the triangular form appears in the
+land masses of the planet Mars. There, too, these triangles appear to
+point toward one pole.
+
+Besides the greater lands, the seas are fretted by a host of smaller
+dry areas, termed islands. These, as inquiry has shown, are of two
+very diverse natures. Near the continents, practically never more than
+a thousand miles from their shores, we find isles, often of great
+size, such as Madagascar, which in their structure are essentially
+like the continents--that is, they are built in part or in whole of
+non-volcanic rocks, sandstones, limestones, etc. In most cases these
+islands, to which we may apply the term continental, have at some time
+been connected with the neighbouring mainland, and afterward separated
+from it by a depression of the surface which permitted the sea to flow
+over the lowlands. Geologists have traced many cases where in the past
+elevations which are now parts of a continent were once islands next
+its shore. In the deeper seas far removed from the margins of the
+continents the islands are made up of volcanic ejections of lava,
+pumice, and dust, which has been thrown up from craters and fallen
+around their margin or are formed of coral and other organic remains.
+
+Next after this general statement as to the division of sea and land
+we should note the peculiarities which the earth's surface exhibits
+where it is bathed by the air, and where it is covered by the water.
+Beginning with the best-known region, that of the dry land, we observe
+that the surface is normally made up of continuous slopes of varying
+declivity, which lead down from the high points to the sea. Here and
+there, though rarely, these slopes centre in a basin which is occupied
+by a lake or a dead sea. On the deeper ocean floors, so far as we may
+judge with the defective information which the plumb line gives us,
+there is no such continuity in the downward sloping of the surface,
+the area being cast into numerous basins, each of great extent.
+
+When we examine in some detail the shape of the land surface, we
+readily perceive that the continuous down slopes are due to the
+cutting action of rivers. In the basin of a stream the waters act to
+wear away the original heights, filling them into the hollows, until
+the whole area has a continuous down grade to the point where the
+waters discharge into the ocean or perhaps into a lake. On the bottom
+of the sea, except near the margin of the continent, where the floor
+may in recent geological times have been elevated into the air, and
+thus exposed to river action, there is no such agent working to
+produce continuous down grades.
+
+Looking upon a map of a continent which shows the differences in
+altitude of the land, we readily perceive that the area is rather
+clearly divided into two kinds of surface, mountains and plains, each
+kind being sharply distinguished from the other by many important
+peculiarities. Mountains are characteristically made up of distinct,
+more or less parallel ridges and valleys, which are grouped in very
+elongated belts, which, in the case of the American Cordilleras,
+extend from the Arctic to the Antarctic Circle. Only in rare instances
+do we find mountains occupying an area which is not very distinctly
+elongated, and in such cases the elevations are usually of no great
+height. Plains, on the other hand, commonly occupy the larger part of
+the continent, and are distributed around the flanks of the mountain
+systems. There is no rule as to their shape; they normally grade away
+from the bases of the mountains toward the sea, and are often
+prolonged below the level of the water for a considerable distance
+beyond the shore, forming what is commonly known as the continental
+shelf or belt of shallows along the coast line. We will now consider
+some details concerning the form and structure of mountains.
+
+In almost any mountain region a glance over the surface of the country
+will give the reader a clew to the principal factor which has
+determined the existence of these elevations. Wherever the bed rocks
+are revealed he will recognise the fact that they have been much
+disturbed. Almost everywhere the strata are turned at high angles;
+often their slopes are steeper than those of house roofs, and not
+infrequently they stand in attitudes where they appear vertical. Under
+the surface of plains bedded rocks generally retain the nearly
+horizontal position in which all such deposits are most likely to be
+found. If the observer will attentively study the details of position
+of these tilted rocks of mountainous districts, he will in most cases
+be able to perceive that the beds have been flexed or folded in the
+manner indicated by the diagram. Sometimes, though rarely, the tops of
+these foldings or arches have been preserved, so that the nature of
+the movement can be clearly discerned. More commonly the upper parts
+of the upward-arching strata have been cut off by the action of the
+decay-bringing forces--frost, flowing water, or creeping ice in
+glaciers--so that only the downward pointing folds which were formed
+in the mountain-making are well preserved, and these are almost
+invariably hidden within the earth.
+
+[Illustration: Fig. 7.--Section of mountains. Rockbridge and Bath
+counties, Va. (from Dana). The numbers indicate the several
+formations.]
+
+By walking across any considerable mountain chain, as, for instance,
+that of the Alleghanies, it is generally possible to trace a number of
+these parallel up-and-down folds of the strata, so that we readily
+perceive that the original beds had been packed together into a much
+less space than they at first occupied. In some cases we could prove
+that the shortening of the line has amounted to a hundred miles or
+more--in other words, points on the plain lands on either side of the
+mountain range which now exists may have been brought a hundred miles
+or so nearer together than they were before the elevations were
+produced. The reader can make for himself a convenient diagram showing
+what occurred by pressing a number of leaves of this book so that the
+sheets of paper are thrown into ridges and furrows. By this experiment
+he also will see that the easiest way to account for such foldings as
+we observe in mountains is by the supposition that some force residing
+in the earth tends to shove the beds into a smaller space than they
+originally occupied. Not only are the rocks composing the mountains
+much folded, but they are often broken through after the manner of
+masonry which has been subjected to earthquake shocks, or of ice which
+has been strained by the expansion that affects it as it becomes
+warmed before it is melted. In fact, many of our small lakes in New
+England and in other countries of a long winter show in a miniature
+way during times of thawing ice folds which much resemble mountain
+arches.
+
+At first geologists were disposed to attribute all the phenomena of
+mountain-folding to the progressive cooling of the earth. Although
+this sphere has already lost a large part of the heat with which it
+was in the beginning endowed, it is still very hot in its deeper
+parts, as is shown by the phenomena of volcanoes. This internal heat,
+which to the present day at the depth of a hundred miles below the
+surface is probably greater than that of molten iron, is constantly
+flowing away into space; probably enough of it goes away on the
+average each day to melt a hundred cubic miles or more of ice, or, in
+more scientific phrase, the amount of heat rendered latent by melting
+that volume of frozen water. J.R. Meyer, an eminent physicist,
+estimated the quantity of heat so escaping each day of the year to be
+sufficient to melt two hundred and forty cubic miles of ice. The
+effect of this loss of heat is constantly to shrink the volume of the
+earth; it has, indeed, been estimated that the sphere on this account
+contracts on the average to the amount of some inches each thousand
+years. For the reason that almost all this heat goes from the depths
+of the earth, the cool outer portion losing no considerable part of
+it, the contraction that is brought about affects the interior
+portions of the sphere alone. The inner mass constantly shrinking as
+it loses heat, the outer, cold part is by its weight forced to settle
+down, and can only accomplish this result by wrinkling. An analogous
+action may be seen where an apple or a potato becomes dried; in this
+case the hard outer rind is forced to wrinkle, because, losing no
+water, it does not diminish in its extent, and can only accommodate
+itself to the interior by a wrinkling process. In one case it is water
+which escapes, in the other heat; but in both contraction of the part
+which suffers the loss leads to the folding of the outside of the
+spheroid.
+
+Although this loss of heat on the part of the earth accounts in some
+measure for the development of mountains, it is not of itself
+sufficient to explain the phenomena, and this for the reason that
+mountains appear in no case to develop on the floors of the wide sea.
+The average depth of the ocean is only fifteen thousand feet, while
+there are hundreds, if not thousands, of mountain crests which exceed
+that height above the sea. Therefore if mountains grew on the sea
+floor as they do upon the land, there should be thousands of peaks
+rising above the plain of the waters, while, in fact, all of the
+islands except those near the shores of continents are of volcanic
+origin--that is, are lands of totally different nature.
+
+Whenever a considerable mountain chain is formed, although the actual
+folding of the beds is limited to the usually narrow field occupied by
+these disturbances, the elevation takes place over a wide belt of
+country on one or both sides of the range. Thus if we approach the
+Rocky Mountains from the Mississippi Valley, we begin to mount up an
+inclined plane from the time we pass westward from the Mississippi
+River. The beds of rock as well as the surface rises gradually until
+at the foot of the mountain; though the rocks are still without
+foldings, they are at a height of four or five thousand feet above the
+sea. It seems probable--indeed, we may say almost certain--that when
+the crust is broken, as it is in mountain-building, by extensive folds
+and faults, the matter which lies a few score miles below the crust
+creeps in toward those fractures, and so lifts up the country on which
+they lie. When we examine the forms of any of our continents, we find
+that these elevated portions of the earth's crust appear to be made up
+of mountains and the table-lands which fringe those elevations. There
+is not, as some of our writers suppose, two different kinds of
+elevation in our great lands--the continents and the mountains which
+they bear--but one process of elevation by which the foldings and the
+massive uplifts which constitute the table-lands are simultaneously
+and by one process formed.
+
+Looking upon continents as the result of mountain growth, we may say
+that here and there on the earth's crust these dislocations have
+occurred in such association and of such magnitude that great areas
+have been uplifted above the plain of the sea. In general, we find
+these groups of elevations so arranged that they produce the
+triangular form which is characteristic of the great lands. It will be
+observed, for instance, that the form of North America is in general
+determined by the position of the Appalachian and Cordilleran systems
+on its eastern and western margins, though there are a number of
+smaller chains, such as the Laurentians in Canada and the ice-covered
+mountains of Greenland, which have a measure of influence in fixing
+its shore lines.
+
+[Illustration: _Waterfall near Gadsden, Alabama. The upper shelf of
+rock is a hard sandstone, the lower beds are soft shale. The
+conditions are those of most waterfalls, such as Niagara._]
+
+The history of plains, as well as that of mountains, will have further
+light thrown upon it when in the next chapter we come to consider the
+effect of rain water on the land. We may here note the fact that the
+level surfaces which are above the seashores are divisible into two
+main groups--those which have been recently lifted above the sea
+level, composed of materials laid down in the shallows next the shore,
+and which have not yet shared in mountain-building disturbances, and
+those which have been slightly tilted in the manner before indicated
+in the case of the plains which border the Rocky Mountains on the
+east. The great southern plain of eastern and southern United States,
+extending from near New York to Mexico, is a good specimen of the
+level lands common on all the continents which have recently emerged
+from the sea. The table-lands on either side of the Mississippi
+Valley, sloping from the Alleghanies and the Cordilleras, represent
+the more ancient type of plain which has already shared in the
+elevation which mountain-building brings about. In rarer cases plains
+of small area are formed where mountains formerly existed by the
+complete moving down of the original ridges.
+
+There is a common opinion that the continents are liable in the course
+of the geologic ages to very great changes of position; that what is
+now sea may give place to new great lands, and that those already
+existing may utterly disappear. This opinion was indeed generally held
+by geologists not more than thirty years ago. Further study of the
+problem has shown us that while parts of each continent may at any
+time be depressed beneath the sea, the whole of its surface rarely if
+ever goes below the water level. Thus, in the case of North America,
+we can readily note very great changes in its form since the land
+began to rise above the water. But always, from that ancient day to
+our own, some portion of the area has been above the level of the sea,
+thus providing an ark of refuge for the land life when it was
+disturbed by inundations. The strongest evidence in favour of the
+opinion that the existing continents have endured for many million
+years is found in the fact that each of the great lands preserves many
+distinct groups of animals and plants which have descended from
+ancient forms dwelling upon the same territory. If at any time the
+relatively small continent of Australia had gone beneath the sea, all
+of the curious pouched animals akin to the opossum and kangaroo which
+abound in that country--creatures belonging in the ancient life of the
+world--would have been overwhelmed.
+
+We have already noted the fact that the uplifting of mountains and of
+the table-lands about them, which appears to have been the basis of
+continental growth, has been due to strains in the rocks sufficiently
+strong to disturb the beds. At each stage of the mountain-building
+movement these compressive strains have had to contend with the very
+great weight of the rocks which they had to move. These lands are not
+to be regarded as firm set or rigid arches, but as highly elastic
+structures, the shapes of which may be determined by any actions which
+put on or take off burden. We see a proof of this fact from numerous
+observations which geologists are now engaged in making. Thus during
+the last ice epoch, when almost all the northern part of this
+continent, as well as the northern part of Europe, was covered by an
+ice sheet several thousand feet thick, the lands sank down under their
+load, and to an extent roughly proportional to the depth of the icy
+covering. While the northern regions were thus tilted down by the
+weight which was upon them, the southern section of this land, the
+region about the Gulf of Mexico, was elevated much above its present
+level; it seems likely, indeed, that the peninsula of Florida rose to
+the height of several hundred feet above its present shore line. After
+the ice passed away the movements were reversed, the northern region
+rising and the southern sinking down. These movements are attested by
+the position of the old shore lines formed during the later stages of
+the Glacial epoch. Thus around Lake Ontario, as well as the other
+Great Lakes, the beaches which mark the higher positions of those
+inland seas during the closing stages of the ice time, and which, of
+course, were when formed horizontal, now rise to the northward at the
+rate of from two to five feet for each mile of distance. Recent
+studies by Mr. G.K. Gilbert show that this movement is still in
+progress.
+
+Other evidence going to show the extent to which the movements of the
+earth's crust are affected by the weight of materials are found in the
+fact that wherever along the shores thick deposits of sediments are
+accumulated the tendency of the region where they lie is gradually to
+sink downward, so that strata having an aggregate thickness of ten
+thousand feet or more may be accumulated in a sea which was always
+shallow. The ocean floor, in general, is the part of the earth's
+surface where strata are constantly being laid down. In the great
+reservoir of the waters the _debris_ washed from the land, the dust
+from volcanoes, and that from the stellar spaces, along with the vast
+accumulation of organic remains, almost everywhere lead to the
+steadfast accumulation of sedimentary deposits. On the other hand, the
+realms of the surface above the ocean level are constantly being worn
+away by the action of the rivers and glaciers, of the waves which beat
+against the shores, and of the winds which blow over desert regions.
+The result is that the lands are wearing down at the geologically
+rapid average rate of somewhere about one foot in five thousand years.
+All this heavy matter goes to the sea bottoms. Probably to this cause
+we owe in part the fact that in the wrinklings of the crust due to the
+contraction of the interior the lands exhibit a prevailing tendency to
+uprise, while the ocean floors sink down. In this way the continents
+are maintained above the level of the sea despite the powerful forces
+which are constantly wearing their substance away, while the seas
+remain deep, although they are continually being burdened with
+imported materials.
+
+[Illustration: Fig. 8.--Diagram showing the effect of the position of
+the fulcrum point in the movement of the land masses. In diagrams I
+and II, the lines _a b_ represent the land before the movement, and
+_a' b'_ its position after the movement; _s_, _s_, the position of the
+shore line; _p_, _p_, the pivotal points; _l_, _s_, the sea line. In
+diagram III, the curved line designates a shore; the line _a b_,
+connecting the pivotal points _p_, _p_, is partly under the land and
+partly under the sea.]
+
+It is easy to see that if the sea floors tend to sink downward, while
+the continental lands uprise, the movements which take place may be
+compared with those which occur in a lever about a fulcrum point. In
+this case the sea end of the bar is descending and the land end
+ascending. Now, it is evident that the fulcrum point may fall to the
+seaward or to the landward of the shore; only by chance and here and
+there would it lie exactly at the coast line. By reference to the
+diagram (Fig. 8), it will be seen that, while the point of rotation is
+just at the shore, a considerable movement may take place without
+altering the position of the coast line. Where the point of no
+movement is inland of the coast, the sea will gain on the continent;
+where, however, the point is to seaward, beneath the water, the land
+will gain on the ocean. In this way we can, in part at least, account
+for the endless changes in the attitude of the land along the coastal
+belt without having to suppose that the continents cease to rise or
+the sea floors to sink downward. It is evident that the bar or section
+of the rocks from the interior of the land to the bottoms of the seas
+is not rigid; it is also probable that the matter in the depths of the
+earth, which moves with the motions of this bar, would change the
+position of the fulcrum point from time to time. Thus it may well come
+about that our coast lines are swaying up and down in ceaseless
+variation.
+
+In very recent geological times, probably since the beginning of the
+last Glacial period, the region about the Dismal Swamp in Virginia has
+swayed up and down through four alternating movements to the extent of
+from fifty to one hundred feet. The coast of New Jersey is now sinking
+at the rate of about two feet in a hundred years. The coast of New
+England, though recently elevated to the extent of a hundred feet or
+more, at a yet later time sank down, so that at some score of points
+between New York and Eastport, Me., we find the remains of forests
+with the roots of their trees still standing below high-tide mark in
+positions where the trees could not have grown. Along all the marine
+coasts of the world which have been carefully studied from this point
+of view there are similar evidences of slight or great modern changes
+in the level of the lands. At some points, particularly on the coast
+of Alaska and along the coast of Peru, these uplifts of the land have
+amounted to a thousand feet or more. In the peninsular district of
+Scandinavia the swayings, sometimes up and sometimes down, which are
+now going on have considerably changed the position of the shore lines
+since the beginning of the historical period.
+
+There are other causes which serve to modify the shapes and sizes of
+the continents which may best be considered in the sequel; for the
+present we may pass from this subject with the statement that our
+great lands are relatively permanent features; their forms change from
+age to age, but they have remained for millions of years habitable to
+the hosts of animals and plants which have adapted their life to the
+conditions which these fields afford them.
+
+
+
+
+                              CHAPTER V.
+
+                            THE ATMOSPHERE.
+
+
+The firm-set portion of the earth, composed of materials which became
+solid when the heat so far disappeared from the sphere that rocky
+matter could pass from its previous fluid condition to the solid or
+frozen state, is wrapped about by two great envelopes, the atmosphere
+and the waters. Of these we shall first consider the lighter and more
+universal air; in taking account of its peculiarities we shall have to
+make some mention of the water with which it is greatly involved;
+afterward we shall consider the structure and functions of that fluid.
+
+Atmospheric envelopes appear to be common features about the celestial
+spheres. In the sun there is, as we have noted, a very deep envelope
+of this sort which is in part composed of the elements which form our
+own air; but, owing to the high temperature of the sphere, these are
+commingled with many substances which in our earth--at least in its
+outer parts--have entered in the solid state. Some of the planets, so
+far as we can discern their conditions, seem also to have gaseous
+wraps; this is certainly the case with the planet Mars, and even the
+little we know of the other like spheres justifies the supposition
+that Jupiter and Saturn, at least, have a like constitution. We may
+regard an atmosphere, in a word, as representing a normal and
+long-continued state in the development of the heavenly orbs. In only
+one of these considerable bodies of the solar system, the moon, do we
+find tolerably clear evidence that there is no atmosphere.
+
+The atmosphere of the earth is composed mainly of very volatile
+elements, known as nitrogen and argon. This is commingled with oxygen,
+also a volatile element. Into this mass a number of other substances
+enter in varying but always relatively very small proportions. Of
+these the most considerable are watery vapour and carbon dioxide; the
+former of these rarely amounts to one per cent of the weight of the
+air, considering the atmosphere as a whole, and the latter is never
+more than a small fraction of one per cent in amount. As a whole, the
+air envelope of the earth should be regarded as a mass of nitrogen and
+argon, which only rarely, under the influence of conditions which
+exist in the soil, enters into combinations with other elements by
+which it assumes a solid form. The oxygen, though a permanent element
+in the atmosphere, tends constantly to enter into combinations which
+fix it temporarily or permanently in the earth, in which it forms,
+indeed, in its combined state about one half the weight of all the
+mineral substances we know. The carbon dioxide, or carbonic-acid gas,
+as it is commonly termed, is a most important substance, as it affords
+plants all that part of their bodies which disappear on burning. It is
+constantly returned to the atmosphere by the decay of organic matter,
+as well as by volcanic action.
+
+In addition to the above-noted materials composing the air, all of
+which are imperatively necessary to the wonderful work accomplished by
+that envelope, we find a host of other substances which are
+accidentally, variably, and always in small quantities contained in
+this realm. Thus near the seashores, and indeed for a considerable
+distance into the continent, we find the air contains a certain amount
+of salt so finely divided that it floats in the atmosphere. So, too,
+we find the air, even on the mountain tops amid eternal snows, charged
+with small particles of dust, which, though not evident to the
+unassisted eye, become at once visible when we permit a slender ray of
+light to enter a dark chamber.
+
+It is commonly asserted that the atmosphere does not effectively
+extend above the height of forty-five miles; we know that it is
+densest on the surface of the earth, the most so in those depressions
+which lie below the level of the sea. This is proved to us by the
+weight which the air imposes upon the mercury at the open end of a
+barometric tube. If we could deepen these cavities to the extent of a
+thousand miles, the pressure would become so great that if the pit
+were kept free from the heat of the earth the gaseous materials would
+become liquefied. Upward from the earth's surface at the sea level the
+atoms and molecules of the air become farther apart until, at the
+height of somewhere between forty and fifty miles, the quantity of
+them contained in the ether is so small that we can trace little
+effect from them on the rays of light which at lower levels are
+somewhat bent by their action. At yet higher levels, however, meteors
+appear to inflame by friction against the particles of air, and even
+at the height of eighty miles very faint clouds have at times been
+discerned, which are possibly composed of volcanic dust floating in
+the very rarefied medium, such as must exist at this great elevation.
+
+The air not only exists in the region where we distinctly recognise
+it; it also occupies the waters and the under earth. In the waters it
+occurs as a mechanical mixture which is brought about as the rain
+forms and falls in the air, as the streams flow to the sea, and as the
+waves roll over the deep and beat against the shores. In the realm of
+the waters, as well as on the land, the air is necessary for the
+maintenance of all animal forms; but for its presence such life would
+vanish from the earth.
+
+Owing to certain peculiarities in its constitution, the atmosphere of
+our earth, and that doubtless of myriad other spheres, serves as a
+medium of communication between different regions. It is, as we know,
+in ceaseless motion at rates which may vary from the speed in the
+greatest tempests, which may move at the rate of somewhere a hundred
+and fifty miles an hour, to the very slow movements which occur in
+caverns, where the transfer is sometimes effected at an almost
+microscopic rate in the space of a day. The motion of the atmosphere
+is brought about by the action of heat here and there, and in a
+trifling way, by the heat from the interior of the earth escaping
+through hot springs or volcanoes, but almost altogether by the heat of
+the sun. If we can imagine the earth cut off from the solar radiation,
+the air would cease to move. We often note how the variable winds fall
+away in the nighttime. Those who in seeking for the North Pole have
+spent winters in the long-continued dark of that region have noted
+that the winds almost cease to blow, the air being disturbed only when
+a storm originated in the sunlit realm forced its way into the
+circumpolar darkness.
+
+The sun's heat does not directly disturb the atmosphere; if we could
+take the solid sphere of the world away, leaving the air, the rays
+would go straight through, and there would be no winds produced. This
+is due to the fact that the air permits the direct rays of heat, such
+as come from the sun, to pass through it with very slight resistance.
+In an aerial globe such as we have imagined, the rays impinging upon
+its surface would be slightly thrown out of their path as they are in
+passing through a lens, but they would journey on in space without in
+any considerable measure warming the mass. Coming, however, upon the
+solid earth, the heat rays warm the materials on which they are
+arrested, bringing them to a higher temperature than the air. Then
+these heated materials radiate the energy into the air; it happens,
+however, that this radiant heat can not journey back into space as
+easily as it came in; therefore the particles of air next the surface
+acquire a relatively high temperature. Thus a thermometer next the
+ground may rise to over a hundred degrees Fahrenheit, while at the
+same time the fleecy clouds which we may observe floating at the
+height of five or six miles above the surface are composed of frozen
+water.
+
+The effect of the heated air which acquires its temperature by
+radiation from the earth's surface is to produce the winds. This it
+brings about in a very simple manner, though the details of the
+process have a certain complication. The best illustration of the mode
+in which the winds are produced is obtained by watching what takes
+place about an ordinary fire at the bottom of a chimney. As soon as
+the fire is lit, we observe that the air about it, so far as it is
+heated, tends upward, drawing the smoke with it. If the air in the
+chimney be cold, it may not draw well at first; but in a few minutes
+the draught is established, or, in other words, the heated lower air
+breaks its way up the shaft, gradually pushing the cooler matter out
+at the top. In still air we may observe the column from the flue
+extending about the chimney-top, sometimes to the height of a hundred
+feet or more before it is broken to pieces. It is well here to note
+the fact that the energy of the draught in a chimney is, with a given
+heat of fire and amount of air which is permitted to enter the shaft,
+directly proportionate to the height; thus in very tall flues, between
+two and three hundred feet high, which are sometimes constructed, the
+uprush is at the speed of a gale.
+
+Whenever the air next the surface is so far heated that it may
+overcome the inertia of the cooler air above, it forces its way up
+through it in the general manner indicated in the chimney flue. When
+such a place of uprush is established, the hot air next the surface
+flows in all directions toward the shaft, joining the expedition to
+the heights of the atmosphere. Owing to the conditions of the earth's
+surface, which we shall now proceed to trace, these ascents of heated
+air belong in two distinct classes--those which move upward through
+more or less cylindrical chimneys in the atmosphere, shafts which are
+impermanent, which vary in diameter from a few feet to fifty or
+perhaps a hundred miles, and which move over the surface of the earth;
+and another which consists of a broad, beltlike shaft in the
+equatorial regions, which in a way girdles the earth, remains in
+about the same place, continually endures, and has a width of hundreds
+of miles. Of these two classes of uprushes we shall first consider the
+greatest, which occurs in the central portions of the tropical realm.
+
+Under the equator, owing to the fact that the sun for a considerable
+belt of land and sea maintains the earth at a high temperature, there
+is a general updraught which began many million years ago, probably
+before the origin of life, in the age when our atmosphere assumed its
+present conditions. Into this region the cooler air from the north and
+south necessarily flows, in part pressed in by the weight of the cold
+air which overlies it, but aided in its motion by the fact that the
+particles which ascend leave place for others to occupy. Over the
+surfaces of the land within the tropical region this draught toward
+what we may term the equatorial chimney is perturbed by the
+irregularities of the surface and many local accidents. But on the
+sea, where the conditions are uniform, the air moving toward the point
+of ascent is marked in the trade winds, which blow with a steadfast
+sweep down toward the equator. Many slight actions, such as the
+movement of the hot and cold currents of the sea, the local air
+movements from the lands or from detached islands, somewhat perturb
+the trade winds, but they remain among the most permanent features in
+this changeable world. It is doubtful if anything on this sphere
+except the atoms and molecules of matter have varied as little as the
+trade winds in the centre of the wide ocean. So steadfast and uniform
+are they that it is said that the helm and sails of a ship may be set
+near the west coast of South America and be left unchanged for a
+voyage which will carry the navigator in their belt across the width
+of the Pacific.
+
+Rising up from the earth in the tropical belt, the air attains the
+height of several thousand feet; it then begins to curve off toward
+the north and south, and at the height of somewhere about three to
+five miles above the surface is again moving horizontally toward
+either pole; attaining a distance on that journey, it gradually
+settles down to the surface of the earth, and ceases to move toward
+higher latitudes. If the earth did not revolve upon its axis the
+course of these winds along the surface toward the equator, and in the
+upper air back toward the poles, would be made in what we may call a
+square manner--that is, the particles of air would move toward the
+point where they begin to rise upward in due north and south lines,
+according as they came from the southern or northern hemisphere, and
+the upper currents or counter trades would retrace their paths also
+parallel with the meridians or longitude lines. But because the earth
+revolves from west to east, the course of the trade winds is oblique
+to the equator, those in the northern hemisphere blowing from
+northeast to southwest, those in the southern from southeast to
+northwest. The way in which the motion of the earth affects the
+direction of these currents is not difficult to understand. It is as
+follows:
+
+Let us conceive a particle of air situated immediately over the
+earth's polar axis. Such an atom would by the rotation of the sphere
+accomplish no motion except, indeed, that it might turn round on its
+own centre. It would acquire no velocity whatever by virtue of the
+earth's movement. Then let us imagine the particle moving toward the
+equator with the speed of an ordinary wind. At every step of its
+journey toward lower latitudes it would come into regions having a
+greater movement than those which it had just left. Owing to its
+inertia, it would thus tend continually to lag behind the particles of
+matter about it. It would thus fall off to the westward, and, in place
+of moving due south, would in the northern hemisphere drift to the
+southwest, and in the southern hemisphere toward the northwest. A good
+illustration of this action may be obtained from an ordinary
+turn-table such as is used about railway stations to reverse the
+position of a locomotive. If the observer will stand in the centre of
+such a table while it is being turned round he will perceive that his
+body is not swayed to the right or left. If he will then try to walk
+toward the periphery of the rotating disk, he will readily note that
+it is very difficult, if not impossible, to walk along the radius of
+the circle; he naturally falls behind in the movement, so that his
+path is a curved line exactly such as is followed by the winds which
+move toward the equator in the trades. If now he rests a moment on the
+periphery of the table, so that his body acquires the velocity of the
+disk at that point, and then endeavours to walk toward the centre, he
+will find that again he can not go directly; his path deviates in the
+opposite direction--in other words, the body continually going to a
+place having a less rate of movement by virtue of the rotation of the
+earth, on account of its momentum is ever moving faster than the
+surface over which it passes. This experiment can readily be tried on
+any small rotating disk, such as a potter's wheel, or by rolling a
+marble or a shot from the centre to the circumference and from the
+circumference to the centre. A little reflection will show the
+inquirer how these illustrations clearly account for the oblique
+though opposite sets of the trade winds in the upper and lower parts
+of the air.
+
+The dominating effect of the tropical heat in controlling the
+movements of the air currents extends, on the ocean surface, in
+general about as far north and south as the parallels of forty
+degrees, considerably exceeding the limits of the tropics, those lines
+where the sun, because of the inclination of the earth's axis, at some
+time of the year comes just overhead. Between these belts of trade
+winds there is a strip or belt under the region where the atmosphere
+is rising from the earth, in which the winds are irregular and have
+little energy. This region of the "doldrums" or frequent calms is one
+of much trouble to sailing ships on their voyages from one hemisphere
+to another. In passing through it their sails are filled only by the
+airs of local storms, or winds which make their way into that part of
+the sea from the neighbouring continents. Beyond the trade-wind belt,
+toward the poles, the movements of the atmosphere are dependent in
+part on the counter trades which descend to the surface of the earth
+in latitudes higher than that in which the surface or trade winds
+flow. Thus along our Atlantic coast, and even in the body of the
+continent, at times when the air is not controlled by some local
+storm, the counter trade blows with considerable regularity.
+
+The effect of the trade and counter-trade movements of the air on the
+distribution of temperature over the earth's surface is momentous. In
+part their influence is due to the direct heat-carrying power of the
+atmosphere; in larger measure it is brought about by the movement of
+the ocean waters which they induce. Atmospheric air, when deprived of
+the water which it ordinarily contains, has very little
+heat-containing capacity. Practically nearly all the power of
+conveying heat which it possesses is due to the vapour of water which
+it contains. By virtue of this moisture the winds do a good deal to
+transfer heat from the tropical or superheated portion of the earth's
+surface to the circumpolar or underheated realms. At first, the
+relatively cool air which journeys toward the equator along the
+surface of the sea constantly gains in heat, and in that process takes
+up more and more water, for precisely the same reason that causes
+anything to dry more rapidly in air which has been warmed next a fire.
+The result is that before it begins to ascend in the tropical
+updraught, being much moisture-laden, the atmosphere stores a good
+deal of heat. As it rises, rarefies, and cools, the moisture descends
+in the torrential rains which ordinarily fall when the sun is nearly
+vertical in the tropical belt.
+
+Here comes in a very interesting principle which is of importance in
+understanding the nature of great storms, either the continuous storm
+of the tropics or the local and irregular whirlings which occur in
+various parts of the earth. When the moisture-laden air starts on its
+upward journey from the earth it has, by virtue of the watery vapour
+which it contains, a store of energy which becomes applied to
+promoting the updraught. As it rises, the moisture in the air gathers
+together or condenses, and in so doing parts with the heat which
+caused it to evaporate from the ocean surface. For a given weight of
+water, the amount of heat required to effect the evaporation is very
+great; this we may roughly judge by observing what a continuous fire
+is required to send a pint of water into the state of steam. This
+energy, when it is released by the condensation of water into rain or
+snow, becomes again heat, and tends somewhat, as does the fire in the
+chimney, to accelerate the upward passage of the air. The result is
+that the water which ascends in the equatorial updraught becomes what
+we may term fuel to promote this important element in the earth's
+aerial circulation. Trades and counter trades would doubtless exist
+but for the efficiency of this updraught, which is caused by the
+condensation of watery vapour, but the movement would be much less
+than it is.
+
+
+                        WHIRLING STORMS.
+
+In the region near the equator, or near the line of highest
+temperature, which for various reasons does not exactly follow the
+equator, there is, as we have noticed, a somewhat continuous uprushing
+current where the air passes upward through an ascending chimney,
+which in a way girdles the sea-covered part of the earth. In this
+region the movements of the air are to a great extent under the
+control of the great continuous updraught. As we go to the north and
+south we enter realms where the air at the surface of the earth is, by
+the heat which it acquires from contact with that surface, more or
+less impelled upward; but there being no permanent updraught for its
+escape, it from time to time breaks through the roof of cold air which
+overlies it and makes a temporary channel of passage. Going polarward
+from the equator, we first encounter these local and temporary
+upcastings of the air near the margin of the tropical belt. In these
+districts, at least over the warmer seas, during the time of the year
+when it is midsummer, and in the regions where the trade winds are not
+strong enough to sweep the warm and moisture-laden air down to the
+equatorial belt, the upward tending strain of the atmosphere next the
+earth often becomes so strong that the overlying air is displaced,
+forming a channel through which the air swiftly passes. As the
+moisture condenses in the way before noted, the energy set free serves
+to accelerate the updraught, and a hurricane is begun. At first the
+movement is small and of no great speed, but as the amount of air
+tending upward is likely to be great, as is also the amount of
+moisture which it contains, the aerial chimney is rapidly enlarged,
+and the speed of the rising air increased. The atmosphere next the
+surface of the sea flows in toward the channel of escape; its passage
+is marked by winds which are blowing toward the centre. On the
+periphery of the movement the particles move slowly, but as they win
+their way toward the centre they travel with accelerating velocity. On
+the principle which determines the whirling movement of the water
+escaping through a hole in the bottom of a basin, the particles of the
+air do not move on straight lines toward the centre, but journey in
+spiral paths, at first along the surface, and then ascending.
+
+We have noted the fact that in a basin of water the direction of the
+whirling is what we may term accidental--that is, dependent on
+conditions so slight that they elude our observation--but in
+hurricanes a certain fact determines in an arbitrary way the direction
+in which the spin shall take place. As soon as such a movement of the
+air attains any considerable diameter, although in its beginning it
+may have spun in a direction brought about by local accidents, it will
+be affected by the diverse rates of travel, by virtue of the earth's
+rotation, of the air on its equatorial and polar sides. On the
+equatorial side this air is moving more rapidly than it is on the
+polar side. By observing the water passing from a basin this
+principle, with a few experiments, can be made plain. The result is to
+cause these great whirlwinds of the hurricanes of higher latitudes to
+whirl round from right to left in the northern hemisphere and in the
+reverse way in the southern. The general system of the air currents
+still further affects these, as other whirling storms, by driving
+their centres or chimneys over the surface of the earth. The principle
+on which this is done may be readily understood by observing how the
+air shaft above a chimney, through which we may observe the smoke to
+rise during a time of calm, is drawn off to one side by the slight
+current which exists even when we feel no wind; it may also be
+discerned in the little dust whirls which form in the streets on a
+summer day when the air is not much disturbed. While they spin they
+move on in the direction of the air drift. In this way a hurricane
+originating in the Gulf of Mexico may gradually journey under the
+influence of the counter trades across the Antilles, or over southern
+Florida, and thence pursue a devious northerly course, generally near
+the Atlantic coast and in the path of the Gulf Stream, until it has
+travelled a thousand miles or more toward the North Atlantic. The
+farther it goes northward the less effectively it is fed with warm and
+moisture-laden air, the feebler its movement becomes, until at length
+it is broken up by the variable winds which it encounters.
+
+A very interesting and, from the point of view of the navigator,
+important peculiarity of these whirls is that at their centre there is
+a calm, similar in origin and nature to the calm under the equator
+between the trade-wind belts. Both these areas are in the field where
+the air is ascending, and therefore at the surface of the earth does
+not affect the sails of ships, though if men ever come to use flying
+machines and sail through the tropics at a good height above the sea
+it will be sensible enough. The difference between the doldrum of the
+equator and that of the hurricane, besides their relative areas, is
+that one is a belt and the other a disk. If the seafarer happens to
+sail on a path which leads him through the hurricane centre, he will
+first discern, as from the untroubled air and sea he approaches the
+periphery of the storm, the horizon toward the disturbance beset by
+troubled clouds, all moving in one direction. Entering beneath this
+pall, he finds a steadily increasing wind, which in twenty miles of
+sailing may, and in a hundred miles surely will, compel him to take in
+all but his storm sails, and is likely to bring his ship into grave
+peril. The most furious winds the mariner knows are those which he
+encounters as he approaches the still centre. These trials are made
+the more appalling by the fact that in the furious part of the whirl
+the rain, condensing from the ascending air, falls in torrents, and
+the electricity generated in the condensation gives rise to vivid
+lightning. If the storm-beset ship can maintain her way, in a score or
+two of miles of journey toward the centre, generally very quickly, it
+passes into the calm disk, where the winds, blowing upward, cease to
+be felt. In this area the ship is not out of danger, for the waves,
+rolling in from the disturbed areas on either side, make a torment of
+cross seas, where it is hard to control the movements of a sailing
+vessel because the impulse of the winds is lost. Passing through this
+disk of calm, the ship re-encounters in reverse order the furious
+portion of the whirl, afterward the lessening winds, until it escapes
+again into the airs which are not involved in the great torment.
+
+In the old days, before Dove's studies of storms had shown the laws of
+hurricane movement, unhappy shipmasters were likely to be caught and
+retained in hurricanes, and to battle with them for weeks until their
+vessels were beaten to pieces. Now the "Sailing Directions," which are
+the mariner's guide, enable him, from the direction of the winds and
+the known laws of motion of the storm centre, to sail out of the
+danger, so that in most cases he may escape calamity. It is otherwise
+with the people who dwell upon the land over which these atmospheric
+convulsions sweep. Fortunately, where these great whirlwinds trespass
+on the continent, they quickly die out, because of the relative lack
+of moisture which serves to stimulate the uprush which creates them.
+Thus in their more violent forms hurricanes are only felt near the
+sea, and generally on islands and peninsulas. There the hurricane
+winds, by the swiftness of their movement, which often attains a speed
+of a hundred miles or more, apply a great deal of energy to all
+obstacles in their path. The pressure thus produced is only less
+destructive than that which is brought about by the tornadoes, which
+are next to be described.
+
+There is another effect from hurricanes which is even more destructive
+to life than that caused by the direct action of the wind. In these
+whirlings great differences in atmospheric pressure are brought about
+in contiguous areas of sea. The result is a sudden elevation in the
+level of one part of the water. These disturbances, where the shore
+lands are low and thickly peopled, as is the case along the western
+coast of the Bay of Bengal, may produce inundations which are terribly
+destructive to life and property. They are known also in southern
+Florida and along the islands of the Caribbean, but in that region are
+not so often damaging to mankind.
+
+Fortunately, hurricanes are limited to a very small part of the
+tropical district. They occur only in those regions, on the eastern
+faces of tropical lands, where the general westerly set of the winds
+favours the accumulation of great bodies of very warm, moist air next
+the surface of the sea. The western portion of the Gulf of Mexico and
+the Caribbean, the Bay of Bengal, and the southeastern portion of Asia
+are especially liable to their visitations. They sometimes develop,
+though with less fury, in other parts of the tropics. On the western
+coast of South America and Africa, where the oceans are visited by the
+dry land winds, and where the waters are cooled by currents setting
+in from high latitudes, they are unknown.
+
+Only less in order of magnitude than the hurricanes are the circular
+storms known as cyclones. These occur on the continents, especially
+where they afford broad plains little interrupted by mountain ranges.
+They are particularly well exhibited in that part of North America
+north of Mexico and south of Hudson Bay. Like the hurricanes, they
+appear to be due to the inrush of relatively warm air entering an
+updraught which had been formed in the overlying, cooler portions of
+the atmosphere. They are, however, much less energetic, and often of
+greater size than the hurricane whirl. The lack of energy is probably
+due to the comparative dryness of the air. The greater width of the
+ascending column may perhaps be accounted for by the fact that,
+originating at a considerable height above the sea, they have a less
+thickness of air to break through, and so the upward setting column is
+readily made broad.
+
+The cyclones of North America appear generally to originate in the
+region of the Rocky Mountains, though it is probable that in some
+instances, perhaps in many, the upward set of the air which begins the
+storm originates in the ocean along the Pacific coast. They gather
+energy as they descend the great sloping plain leading eastward from
+the Rocky Mountains to the central portion of the great continental
+valley. Thence they move on across the country to the Atlantic coast.
+Not infrequently they continue on over the ocean to the European
+continent. The eastward passage of the storm centre is due to the
+prevailing eastward movement of the air in its upper part throughout
+that portion of the northern hemisphere. Commonly they incline
+somewhat to the northward of east in their journey. In all cases the
+winds appear to blow spirally into the common storm centre. There is
+the same doldrum area or calm field in the centre of the storm that we
+note between the trade winds and in the middle of a hurricane disk,
+though this area is less defined than in the other instances, and the
+forward motion of the storm at a considerable speed is in most cases
+characteristic of the disturbance. On the front of one of these storms
+in North America the winds commonly begin in the northeast, thence
+they veer by the east to the southwest. At this stage in the movement
+the storm centre has passed by, the rainfall commonly ceases, and
+cold, dry winds setting to the northwestward set in. This is caused by
+the fact that the ascending air, having attained a height above the
+earth, settles down behind the storm, forming an anticyclone or mass
+of dry air, which presses against the retreating side of the great
+whirlwind.
+
+In front of the storm the warm and generally moist relatively warm
+air, pressing in toward the point of uprise and overlaid by the upper
+cold air, is brought into a condition where it tends to form small
+subordinate shafts up through which it whirls on the same principle,
+but with far greater intensity than the main ascending column. The
+reason for the violence of this movement is that the difference in
+temperature of the air next the surface and that at the height of a
+few thousand feet is great. As might be expected, these local
+spinnings are most apt to occur in the season when the air next the
+earth is relatively warm, and they are aptest to take place in the
+half of the advancing front lying between the east and south, for the
+reason that there the highest temperatures and the greatest humidity
+are likely to coexist. In that part of the field, during the time when
+the storm is advancing from the Rocky Mountains to the Atlantic, a
+dozen or more of these spinning uprushes may be produced, though few
+of them are likely to be of large size or of great intensity.
+
+The secondary storms of cyclones, such as are above noted, receive the
+name of tornadoes. They are frequent and terrible visitations of the
+country from northern Texas, Florida, and Alabama to about the line of
+the Great Lakes; they are rarely developed in the region west of
+central Kansas, and only occasionally do they exhibit much energy in
+the region east of the plain-lands of the Ohio Valley. Although known
+in other lands, they nowhere, so far as our observations go, exhibit
+the paroxysmal intensity which they show in the central portion of the
+North American continent. There the air which they affect acquires a
+speed of movement and a fury of action unknown in any other
+atmospheric disturbances, even in those of the hurricanes.
+
+The observer who has a chance to note from an advantageous position
+the development of a tornado observes that in a tolerably still air,
+or at least an air unaffected by violent winds--generally in what is
+termed a "sultry" state of the atmosphere--the storm clouds in the
+distance begin to form a kind of funnel-shaped dependence, which
+gradually extends until it appears to touch the earth. As the clouds
+are low, this downward-growing column probably in no case is observed
+for the height of more than three or four thousand feet. As the funnel
+descends, the clouds above and about it may be seen to take on a
+whirling movement around the centre, and under favourable
+circumstances an uprush of vapours may be noted in the centre of the
+swaying shaft. As the whirl comes nearer, the roar of the disturbance,
+which at a distance is often compared to the sound made by a threshing
+machine or to that of distant musketry, increases in loudness until it
+becomes overwhelming. When a storm such as this strikes a building, it
+is not only likely to be razed by the force of the wind, but it may be
+exploded, as by the action of gunpowder fired within its walls,
+through the sudden expansion of the air which it contains. In the
+centre of the column, although it rarely has a diameter of more than a
+few hundred feet, the uprush is so swift that it makes a partial
+vacuum. The air, striving to get into the space which it is eager to
+occupy, is whirling about at such a rate that the centrifugal motion
+which it thus acquires restrains its entrance. In this way there may
+be, as the column rapidly moves by, a difference of pressure
+amounting probably to what the mercury of a barometer would indicate
+by four or five inches of fall. Unless the structure is small and its
+walls strong, its roof and sides are apt to be blown apart by this
+difference of pressure and the consequent expansion of the contained
+air. In some cases where wooden buildings have withstood this curious
+action the outer clapboards have been blown off by the expansion of
+the small amount of air contained in the interspaces between that
+covering and the lath and plaster within (see Fig. 9).
+
+[Illustration: Fig. 9.--Showing effect of expansion of air contained
+in a hollow wall during the passage of the storm.]
+
+The blow of the air due to its rotative whirling has in several cases
+proved sufficient to throw a heavy locomotive from the track of a
+well-constructed railway. In all cases where it is intense it will
+overturn the strongest trees. The ascending wind in the centre of the
+column may sometimes lift the bodies of men and of animals, as well as
+the branches and trunks of trees and the timber of houses, to the
+height of hundreds of feet above the surface. One of the most striking
+exhibitions of the upsucking action in a tornado is afforded by the
+effect which it produces when it crosses a small sheet of water. In
+certain cases where, in the Northwestern States of this country, the
+path of the storm lay over the pool, the whole of the water from a
+basin acres in extent has been entirely carried away, leaving the
+surface, as described by an observer, apparently dry enough to plough.
+
+Fortunately for the interests of man, as well as those of the lower
+organic life, the paths of these storms, or at least the portion of
+their track where the violence of the air movement makes them very
+destructive, often does not exceed five hundred feet in width, and is
+rarely as great as half a mile in diameter. In most cases the length
+of the journey of an individual tornado does not exceed thirty miles.
+It rarely if ever amounts to twice that distance.
+
+In every regard except their small size and their violence these
+tornadoes closely resemble hurricanes. There is the same broad disk of
+air next the surface spirally revolving toward the ascending centre,
+where its motion is rapidly changed from a horizontal to a vertical
+direction. The energy of the uprush in both cases is increased by the
+energy set free through the condensation of the water, which tends
+further to heat and thus to expand the air. The smaller size of the
+tornado may be accounted for by the fact that we have in their
+originating conditions a relatively thin layer of warm, moist air next
+the earth and a relatively very cold layer immediately overlying it.
+Thus the tension which serves to start the movement is intense, though
+the masses involved are not very great. The short life of a tornado
+may be explained by the fact that, though it apparently tends to grow
+in width and energy, the central spout is small, and is apt to be
+broken by the movements of the atmosphere, which in the front of a
+cyclone are in all cases irregular.
+
+On the warmer seas, but often beyond the limits of the tropics,
+another class of spinning storms, known as waterspouts, may often be
+observed. In general appearance these air whirls resemble tornadoes,
+except that they are in all cases smaller than that group of
+whirlings. As in the tornadoes, the waterspout begins with a funnel,
+which descends from the sky to the surface of the sea. Up the tube
+vapours may be seen ascending at great speed, the whole appearing like
+a gigantic pillar of swiftly revolving smoke. When the whirl reaches
+the water, it is said that the fluid leaps up into the tube in the
+form of dense spray, an assertion which, in view of the fact of the
+action of a tornado on a lake as before described, may well be
+believed. Like the tornadoes and dust whirls, the life of a waterspout
+appears to be brief. They rarely endure for more than a few minutes,
+or journey over the sea for more than two or three miles before the
+column appears to be broken by some swaying of the atmosphere. As
+these peculiar storms are likely to damage ships, the old-fashioned
+sailors were accustomed to fire at them with cannon. It has been
+claimed that a shot would break the tube and end the little
+convulsion. This, in view of the fact that they appear to be easily
+broken up by relatively trifling air currents, may readily be
+believed. The danger which these disturbances bring to ships is
+probably not very serious.
+
+The special atmospheric conditions which bring about the formation of
+waterspouts are not well known; they doubtless include, however, warm,
+moist air next the surface of the sea and cold air above. Just why
+these storms never attain greater size or endurance is not yet known.
+These disturbances have been seen for centuries, but as yet they have
+not been, in the scientific sense, observed. Their picturesqueness
+attracts all beholders; it is interesting to note the fact that
+perhaps the earliest description of their phenomena--one which takes
+account in the scientific spirit of all the features which they
+present--was written by the poet Camoens in the Lusiad, in which he
+strangely mingles fancy and observation in his account of the great
+voyage of Vasco da Gama. The poet even notes that the water which
+falls when the spout is broken is not salt, but fresh--a point which
+clearly proves that not much of the water which the tube contains is
+derived from the sea. It is, in fact, watery vapour drawn from the air
+next the surface of the ocean, and condensed in its ascent through the
+tube. In this and other descriptions of Nature Camoens shows more of
+the scientific spirit than any other poet of his time. He was in this
+regard the first of modern writers to combine a spiritual admiration
+for Nature with some sense of its scientific meaning.
+
+In treating of the atmosphere, meteorologists base their studies
+largely on changes in the weight of that medium, which they determine
+by barometric observations. In fact, the science of the air had its
+beginning in Pascal's admirable observation on the changes in the
+height of a column of mercury contained in a bent tube as he ascended
+the volcanic peak known as Puy de Dome, in central France. As before
+noted, it is to the disturbances in the weight of the air, brought
+about mainly by variations in temperature, that we owe all its
+currents, and it is upon these winds that the features we term climate
+in largest measure depend. Every movement of the winds is not only
+brought about by changes in the relative weight of the air at certain
+points, but the winds themselves, owing to the momentum which the air
+attains by them, serve to bring about alterations in the quantity of
+air over different parts of the earth, which are marked most
+distinctly by barometric variations. These changes are exceedingly
+complicated; a full account of them would demand the space of this
+volume. A few of the facts, however, should be presented here. In the
+first place, we note that each day there is normally a range in the
+pressure which causes the barometer to be at the lowest at about four
+o'clock in the morning and four o'clock in the afternoon, and highest
+at about ten o'clock in those divisions of the day. This change is
+supposed to be due to the fact that the motes of dust in the
+atmosphere in the night, becoming cooled, condense the water vapour
+upon their surfaces, thus diminishing the volume of the air. When the
+sun rises the water evaporated by the heat returns from these little
+storehouses into the body of the atmosphere. Again in the evening the
+condensation sets in; at the same time the air tends to drift in from
+the region to the westward, where the sun is still high, toward the
+field where the barometer has been thus lowered; the current gradually
+attains a certain volume, and so brings about the rise of the
+barometer about ten o'clock at night.
+
+In the winter time, particularly on the well-detached continent of
+North America, we find a prevailing high barometer in the interior of
+the country and a corresponding low state of pressure on the Atlantic
+Ocean. In the summer season these conditions are on the whole
+reversed.
+
+Under the tropics, in the doldrum belt, there is a zone of low
+barometer connected to the ascending currents which take place along
+that line. This is a continuous manifestation of the same action which
+gives a large area of a disklike form in the centre or eye of the
+hurricane and in the middle portion of the tornado's whirl. In
+general, it may be said that the weight of the air is greatest in the
+regions from which it is blowing toward the points of upward escape,
+and least in and about those places where the superincumbent air is
+rising through a temporary or permanent line of escape. In other
+words, ascending air means generally a relatively low barometer, while
+descending air is accompanied by greater pressure in the field upon
+which it falls.
+
+In almost every part of the earth which is affected by a particular
+physiography we find that the movements of the atmosphere next the
+surface are qualified by the condition which it encounters. In fact,
+if a person were possessed of all the knowledge which could be
+obtained concerning winds, he could probably determine as by a map the
+place where he might chance to find himself, provided he could extend
+his observations over a term of years. In other words, the regimen of
+the winds--at least those of a superficial nature--is almost as
+characteristic of the field over which they go as is a map of the
+country. Of these special winds a number of the more important have
+been noted, only a few of which we can advert to. First among these
+may well come the land and sea breezes which are remarked about all
+islands which are not continuously swept by permanent winds. One of
+the most characteristic instances of these alternate winds is perhaps
+that afforded on the island of Jamaica.
+
+The island of Jamaica is so situated within the basin of the Caribbean
+that it does not feel the full influence of the trades. It has a range
+of high mountains through its middle part. In the daytime the surface
+of the land, which has the sun overhead twice each year, and is always
+exposed to nearly vertical radiation, becomes intensely hot, so that
+an upcurrent is formed. The formation of this current is favoured by
+the mountains, which apply a part of the heat at the height of about a
+mile above the surface of the sea. This action is parallel to that we
+notice when, in order to create a draught in the air of a chimney, we
+put a torch some distance up above the fireplace, thus diminishing the
+height of the column of air which has to be set in motion. It is
+further shown by the fact that when miners sought to make an upcurrent
+in a shaft, in order to lead pure air into the workings through other
+openings, they found after much experience that it was better to have
+the fire near the top of the shaft rather than at the bottom.
+
+The ascending current being induced up the mountain sides of Jamaica,
+the air is forced in from the sea to the relatively free space. Before
+noon the current, aided in its speed by a certain amount of the
+condensation of the watery vapour before described, attains the
+proportions of a strong wind. As the sun begins to sink, the earth's
+surface pours forth its heat; the radiation being assisted by the
+extended surfaces of the plants, cooling rapidly takes place.
+Meanwhile the sea, because of the great heat-storing power of water,
+is very little cooled, the ascent of the air ceases, the temporary
+chimney with its updraught is replaced by a downward current, and the
+winds blow from the land until the sun comes again to reverse the
+current. In many cases these movements of the daily winds flowing into
+and from islands induce a certain precipitation of moisture in the
+form of rain. Generally, however, their effect is merely to ameliorate
+the heat by bringing alternately currents from the relatively cool sea
+and from the upper atmosphere to lessen the otherwise excessive
+temperature of the fields which they traverse.
+
+Although characteristic sea and land winds are limited to regions
+where the sun's heat is great, they are traceable even in high
+latitudes during the periods of long-continued calm attended with
+clear skies. Thus on the island of Martha's Vineyard, in
+Massachusetts, the writer has noted, when the atmosphere was in such a
+state, distinct night and day, or sea and land, breezes coming in
+their regular alternation. During the night when these alternate winds
+prevail the central portion of the island, at the distance of three
+miles from the sea, is remarkably cold, the low temperature being due
+to the descending air current. To the same physical cause may be
+attributed the frequent insets of the sea winds toward midday along
+the continental shores of various countries. Thus along the coast of
+New England in the summer season a clear, still, hot day is certain to
+lead to the creation of an ingoing tide of air, which reaches some
+miles into the interior. This stream from the sea enters as a thin
+wedge, it often being possible to note next the shore when the
+movement begins a difference of ten degrees of temperature between the
+surface of the ground to which the point of the wedge has attained,
+and a position twenty feet higher in the air. This is a beautiful
+example to show at once how the relative weight of the atmosphere,
+even when the differences are slight, may bring about motion, and also
+how masses of the atmosphere may move by or through the rest of the
+medium in a way which we do not readily conceive from our observations
+on the transparent mass. Very few people have any idea how general is
+the truth that the air, even in continuous winds, tends to move in
+more or less individualized masses. This, however, is made very
+evident by watching the gusts of a storm or the wandering patches of
+wind which disturb the surface of an otherwise smooth sea.
+
+[Illustration: _South shore, Martha's Vineyard, Massachusetts, showing
+a characteristic sand beach with long slope and low dunes. Note the
+three lines of breakers and the splash flows cutting little bays in
+the sand._]
+
+Among the notable local winds are those which from their likeness to
+the Foehn of the Swiss valleys receive that name. Foehns are produced
+where a body of air blowing against the slope of a continuous mountain
+range is lifted to a considerable height, and, on passing over the
+crest, falls again to a low position. In its ascent the air is cooled,
+rarefied, and to a great extent deprived of its moisture. In
+descending it is recondensed, and by the process by which its atoms
+are brought together its latent heat is made sensible. There being but
+little watery vapour in the mass, this heat is not much called for by
+that heat-storing fluid, and so the air is warmed. So far Foehn winds
+have only been remarked as conspicuous features in Switzerland and on
+the eastern face of the Rocky Mountains. In the region about the head
+waters of the Missouri and to the northward their influence in what
+are called the Chinook winds is distinctly to ameliorate the severe
+winter climate of the country.
+
+In almost all great desert regions, particularly in the typical
+Sahara, we find a variety of storm belonging to the whirlwind group,
+which, owing to the nature of the country, take on special
+characteristics. These desert storms take up from the verdureless
+earth great quantities of sand and other fine _debris_, which often so
+clouds the air as to bring the darkness of night at midday. Their
+whirlings appear in size to be greater than those which produce
+tornadoes or waterspouts, but less than hurricanes or cyclones.
+Little, however, is known about them. They have not been well
+observed by meteorologists. In some ways they are important, for the
+reason that they serve to carry the desert sand into regions
+previously verdure-clad, and thus to extend the bounds of the desolate
+fields in which they originate. Where they blow off to the seaward,
+they convey large quantities of dust into the ocean, and thus serve to
+wear down the surface of the land in regions where there are no rivers
+to effect that action in the normal way.
+
+Notwithstanding its swift motion when impelled by differences in
+weight, the movements of the air have had but little direct and
+immediate influence on the surface of the earth. The greater part of
+the work which it does, as we shall see hereafter, is done through the
+waters which it impels and bears about. Yet where winds blow over
+verdureless surfaces the effect of the sand which they sweep before
+them is often considerable. In regions of arid mountains the winds
+often drive trains of sand through the valleys, where the sharp
+particles cut the rocks almost as effectively as torrents of water
+would, distributing the wearing over the width of the valley. The dust
+thus blown, from a desert region may, when it attains a country
+covered with vegetation, gradually accumulate on its surface, forming
+very thick deposits. Thus in northwestern China there is a wide area
+where dust accumulations blown from the arid districts of central Asia
+have gradually heaped up in the course of ages to the depth of
+thousands of feet, and this although much of the _debris_ is
+continually being borne away by the action of the rain waters as they
+journey toward the sea. Such dust accumulations occur in other parts
+of the world, particularly in the districts about the upper
+Mississippi and in the valleys of the Rocky Mountains, but nowhere are
+they so conspicuous as in the region first mentioned.
+
+Where prevailing winds from the sea, from great lakes, and even from
+considerable rivers, blow against sandy shores or cliffs of the same
+nature, large quantities of sand and dust are often driven inland
+from the coast line. In most cases these wind-borne materials take on
+the form of dunes, or heaps of sand, varying from a few feet to
+several hundred feet in height. It is characteristic of these hills of
+blown sand that they move across the face of the country. Under
+favourable conditions they may journey scores of miles from the shore.
+The marching of a dune is effected through the rolling up of the sand
+on the windward side of the elevation, when it is impelled by the
+current of air to the crest where it falls into the lee or shelter
+which the hill makes to the wind. In this way in the course of a day
+the centre of the dune, if the wind be blowing furiously, may advance
+a measurable distance from the place it occupied before. By fits and
+starts this ongoing may be indefinitely continued. A notable and
+picturesque instance of the march of a great dune may be had from the
+case in which one of them overwhelmed in the last century the village
+of Eccles in southeastern England. The advancing sand gradually crept
+into the hamlet, and in the course of a decade dispossessed the people
+by burying their houses. In time the summit of the church spire
+disappeared from view, and for many years thereafter all trace of the
+hamlet was lost. Of late years, however, the onward march of the sands
+has disclosed the church spire, and in the course of another century
+the place may be revealed on its original site, unchanged except that
+the marching hill will be on its other side.
+
+In the region about the head of the Bay of Biscay the quantity of
+these marching sands is so great that at one time they jeopardized the
+agriculture of a large district. The French Government has now
+succeeded, by carefully planting the surface of the country with
+grasses and other herbs which will grow in such places, in checking
+the movement of the wind-blown materials. By so doing they have merely
+hastened the process by which Nature arrests the march of dunes. As
+these heaps creep away from the sea, they generally come into regions
+where a greater variety of plants flourish; moreover, their sand
+grains become decayed, so that they afford a better soil. Gradually
+the mat of vegetation binds them down, and in time covers them over so
+that only the expert eye can recognise their true nature. Only in
+desert regions can the march of these heaps be maintained for great
+distances.
+
+Characteristic dunes occur from point to point all along the Atlantic
+coast from the State of Maine to the northern coast of Florida. They
+also occur along the coasts of our Great Lakes, being particularly
+well developed at the southern end of Lake Michigan, where they form,
+perhaps, the most notable accumulations within the limits of the
+United States.
+
+When blown sands invade a forest and the deposit is rapidly
+accumulated, the trees are often buried in an undecayed condition. In
+this state, with certain chemical reactions which may take place in
+the mass, the woody matter is apt to become replaced by silex
+dissolved from the sand, which penetrates the tissues of the plants.
+In this way salicified forests are produced, such as are found in the
+region of the Rocky Mountains, where the trunks of the trees, now very
+hard stone, so perfectly preserve their original structure that when
+cut and polished they may be used for decorative purposes. Conspicuous
+as is this work of the dunes, it is in a geological way much less
+important than that accomplished by the finer dust which drifts from
+one region of land to another or into the sea. Because of their
+weight, the sand grains journey over the surface of the earth, except,
+indeed, where they are uplifted by whirl storms. They thus can not
+travel very fast or far. Dust, however, rises into the air, and
+journeys for indefinite distances. We thus see how slight differences
+in the weight of substances may profoundly affect the conditions of
+their deportation.
+
+
+                      THE SYSTEM OF WATERS.
+
+The envelope of air wraps the earth completely about, and, though
+varying in thickness, is everywhere present over its surface. That of
+the waters is much less equally distributed. Because of its weight, it
+is mainly gathered in the depths of the earth, where it lies in the
+interstices of the rocks and in the great realm of the seas. Only a
+very small portion of the fluid is in the atmosphere or on the land.
+Perhaps less than a ten thousandth part of the whole is at any one
+time on this round from the seas through the air to the land and back
+to the great reservoir.
+
+The great water store of the earth is contained in two distinct
+realms--in the oceans, where the fluid is concentrated in a quantity
+which fills something like nine tenths of the hollows formed by the
+corrugations of the earth's surface; and in the rocks, where it is
+stored in a finely divided form, partly between the grains of the
+stony matter and partly in the substance of its crystals, where it
+exists in a combination, the precise nature of which is not well
+known, but is called water of crystallization. On the average, it
+seems likely that the materials of the earth, whether under the sea or
+on the land, have several per cent of their mass of the fluid.
+
+It is not yet known to what depth the water-bearing section of the
+earth extends; but, as we shall see more particularly hereafter when
+we come to consider volcanoes, the lavas which they send up to the
+surface are full of contained water, which passes from them in the
+form of steam. The very high temperature of these volcanic ejections
+makes it necessary for us to suppose that they come from a great
+depth. It is difficult to believe that they originate at less than a
+hundred miles below the earth's surface. If, then, the rocks contain
+an average of even five per cent of water to the depth of one hundred
+miles, the quantity of the fluid stored within the earth is greater
+than that which is contained in the reservoir of the ocean. The
+oceans, on the average, are not more than three miles deep; spread
+evenly over the surface of the whole earth, their depth would be less
+than two miles, while the water in the rocks, if it could be added to
+the seas, would make the total depth seven miles or more. As we shall
+note hereafter, the processes of formation of strata tend to imprison
+water in the beds, which in time is returned to the earth's surface by
+the forces which operate within the crust.
+
+Although the water in the seas is, as we have seen, probably less than
+one half of the store which the earth possesses, the part it plays in
+the economy of the planet is in the highest measure important. The
+underground water operates solely to promote certain changes which
+take place in the mineral realm. Its effect, except in volcanic
+processes, are brought about but slowly, and are limited in their
+action. The movements of this buried water are exceedingly gradual;
+the forces which impel it about and which bring it to do its work
+originate in the earth. In the seas the fluid has an exceeding freedom
+of motion; it can obey the varied impulses which the solar energy
+imposes upon it. The role of these wonderful actions which we are
+about to trace includes almost everything which goes on upon the
+surface of the planet--that which relates to the development of animal
+and vegetable life, as well as to the vast geological changes which
+the earth is undergoing.
+
+If the surface of the earth were uniformly covered with water to the
+depth of ten thousand feet or more, every particle of fluid would, in
+a measure, obey the attraction of the sun, of the moon, and,
+theoretically, also of all the other bodies in space, on the principle
+that every particle of matter in the universe exercises a gravitative
+effect on every other. As it is, owing to the divided condition of the
+water on the earth's surface, only that which is in the ocean and
+larger seas exhibits any measurable influence from these distant
+attractions. In fact, only the tides produced by the moon and sun are
+of determinable magnitude, and of these the lunar is of greater
+importance, the reason being the near position of our satellite to our
+own sphere. The solar tide is four tenths as great as the lunar. The
+water doubtless obeys in a slight way the attraction of the other
+celestial bodies, but the motions thus imparted are too small to be
+discerned; they are lost in the great variety of influences which
+affect all the matter on the earth.
+
+Although the tides are due to the attraction of the solar bodies,
+mainly to that of the moon, the mode in which the result is brought
+about is somewhat complicated. It may briefly and somewhat
+incompletely be stated as follows: Owing to the fact that the
+attracting power of the earth is about eighty times greater than that
+of the moon, the centre of gravity of the two bodies lies within the
+earth. About this centre the spheres revolve, each in a way swinging
+around the other. At this point there is no centrifugal motion arising
+from the revolution of the pair of spheres, but on the side of the
+earth opposite the moon, some six thousand miles away, the centrifugal
+force is considerable, becoming constantly greater as we pass away
+from the turning point. At the same time the attraction of the moon on
+the water becomes less. Thus the tide opposite the satellite is
+formed. On the side toward the moon the same centrifugal action
+operates, though less effectively than in the other case, for the
+reason that the turning point is nearer the surface; but this action
+is re-enforced by the greater attraction of the moon, due to the fact
+that the water is much nearer that body.
+
+In the existing conditions of the earth, what we may call the normal
+run of the tides is greatly interrupted. Only in the southern ocean
+can the waters obey the lunar and solar attraction in anything like a
+normal way. In that part of the earth two sets of tides are
+discernible, the one and greater due to the moon, the other, much
+smaller, to the sun. As these tides travel round at different rates,
+the movements which they produce are sometimes added to each other
+and sometimes subtracted--that is, at times they come together, while
+again the elevation of one falls in the hollow of the other. Once
+again supposing the earth to be all ocean covered, computation shows
+that the tides in such a sea would be very broad waves, having,
+indeed, a diameter of half the earth's circumference. Those produced
+by the moon would have an altitude of about one foot, and those by the
+sun of about three inches. The geological effects of these swayings
+would be very slight; the water would pass over the bottom to and fro
+twice each day, with a maximum journey of a hundred or two feet each
+way from a fixed point. This movement would be so slow that it could
+not stir the fine sediment; its only influence would perhaps be to
+help feed the animals which were fixed upon the bottom by drawing the
+nurture-bringing water by their mouths.
+
+Although the divided condition of the ocean perturbs the action of the
+tides, so that except by chance their waves are rarely with their
+centres where the attracting bodies tend to make them, the influence
+of these divisions is greatly to increase the geological or
+change-bringing influences arising from these movements. When from the
+southern ocean the tides start to the northward up the bays of the
+Atlantic, the Pacific, or the Indian Ocean, they have, as before
+noted, a height of perhaps less than two feet. As they pass up the
+narrowing spaces the waves become compressed--that is, an equal volume
+of moving water has less horizontal room for its passage, and is
+forced to rise higher. We see a tolerably good illustration of the
+same principle when we observe a wind-made wave enter a small recess
+of the shore, the sides of which converge in the direction of the
+motion. With the diminished room, the wave gains in height. It thus
+comes about that the tide throughout the Atlantic basin is much higher
+than in the southern ocean. On the same principle, when the tide rolls
+in against the shores every embayment of a distinct kind, whose sides
+converge toward the head, packs up the tidal wave, often increasing
+its height in a remarkable way. When these bays are wide-mouthed and
+of elongate triangular form, with deep bottoms, the tides which on
+their outer parts have a height of ten or fifteen feet may attain an
+altitude of forty or fifty feet at the apex of the triangle.
+
+We have already noted the fact that the tide, such as runs in the
+southern ocean, exercises little or no influence upon the bottom of
+the sea over which it moves. As the height of the confined waters
+increases, the range of their journey over the bottom as the wave
+comes and goes rapidly increases. When they have an elevation of ten
+feet they can probably stir the finer mud on the ocean floor, and in
+shallow water move yet heavier particles. In the embayments of the
+land, where a great body of water journeys like an alternating river
+into extensive basins, the tidal action becomes intense; the current
+may be able to sweep along large stones quite as effectively as a
+mountain torrent. Thus near Eastport, Me., where the tides have a
+maximum rise and fall of over twenty feet, the waters rush in places
+so swiftly that at certain stages of the movement they are as much
+troubled as those at the rapids of the St. Lawrence. In such portions
+of the shore the tides do important work in carving channels into the
+lands.
+
+Along the shores of the continents about the North Atlantic, where the
+tides act in a vigorous manner, we almost everywhere find an
+underwater shelf extending from the shore with a declivity of only
+five to ten feet to the mile toward the centre of the sea, until the
+depth of about five hundred feet is attained; from this point the
+bottom descends more steeply into the ocean's depth. It is probable
+that the larger part of the material composing these continental
+shelves has been brought to its position by tidal action. Each time
+the tidal wave sweeps in toward the shore it urges the finer particles
+of sediment along with it. When it moves out it drags them on the
+return journey toward the depths of the sea. If this shelf were
+perfectly horizontal, the two journeys of the sand and mud grains
+would be of the same length; but as the movement takes place up and
+down a slope, the bits will travel farther under the impulse which
+leads them downward than under that which impels them up. The result
+will be that the particles will travel a little farther out from the
+shore each time it is swung to and fro in the alternating movement of
+the tide.
+
+The effect of tidal movement in nurturing marine life is very great.
+It aids the animals fixed on the bottoms of the deep seas to obtain
+their provision of food and their share of oxygen by drawing the water
+by their bodies. All regions which are visited by strong tides
+commonly have in the shallows near the shores a thick growth of
+seaweed which furnishes an ample provision of food for the fishes and
+other forms of animal life.
+
+A peculiar effect arising from tidal action is believed by students of
+the phenomena to be found in the slowing of the earth's rotation on
+its axis. The tides rotate around the earth from east to west, or
+rather, we should say, the solid mass of the earth rubs against them
+as it spins from west to east. As they move over the bottom and as
+they strike against the shores this push of the great waves tends in a
+slight measure to use up the original spinning impulse which causes
+the earth's rotation. Computation shows that the amount of this action
+should be great enough gradually to lengthen the day, or the time
+occupied by the earth in making a complete revolution on the polar
+axis. The effect ought to be great enough to be measurable by
+astronomers in the course of a thousand years. On the other hand, the
+records of ancient eclipses appear pretty clearly to show that the
+length of the day has not changed by as much as a second in the course
+of three thousand years. This evidence does not require us to abandon
+the supposition that the tides tend to diminish the earth's rate of
+rotation. It is more likely that the effect of the reduction in the
+earth's diameter due to the loss of heat which is continually going on
+counterbalances the influence of the tidal friction. As the diameter
+of a rotating body diminishes, the tendency is for the mass to spin
+more rapidly; if it expands, to turn more slowly, provided in each
+case the amount of the impulse which leads to the turning remains the
+same. This can be directly observed by whirling a small weight
+attached to a string in such a manner that the cord winds around the
+finger with each revolution; it will be noted that as the line
+shortens the revolution is more quickly accomplished. We can readily
+conceive that the earth is made up of weights essentially like that
+used in the experiment, each being drawn toward the centre by the
+gravitative stress, which is like that applied to the weight by the
+cord.
+
+The fact that the days remain of the same length through vast periods
+of time is probably due to this balance between the effects of tidal
+action and those arising from the loss of heat--in other words, we
+have here one of those delicate arrangements in the way of
+counterpoise which serve to maintain the balanced conditions of the
+earth's surface amid the great conflicts of diverse energies which are
+at work in and upon the sphere.
+
+It should be understood that the effects of the attraction which
+produces tides are much more extensive than they are seen to be in the
+movements of the sea. So long as the solar and planetary spheres
+remain fluid, the whole of their masses partake of the movement. It is
+a consequence of this action, as the computations of Prof. George
+Darwin has shown, that the moon, once nearer the earth than it is at
+present, has by a curious action of the tidal force been pushed away
+from the centre of our sphere, or rather the two bodies have repelled
+each other. An American student of the problem, Mr. T.J.J. See, has
+shown that the same action has served to give to the double stars the
+exceeding eccentricity of their orbits.
+
+Although these recent studies of tidal action in the celestial sphere
+are of the utmost importance to the theory of the universe, for they
+may lead to changes in the nebular hypotheses, they are as yet too
+incomplete and are, moreover, too mathematical to be presented in an
+elementary treatise such as this.
+
+                  *       *       *       *       *
+
+We now turn to another class of waves which are of even more
+importance than those of the tides--to the undulations which are
+produced by the action of the wind on the surface of the water. While
+the tide waves are limited to the open ocean, and to the seas and bays
+which afford them free entrance, wind waves are produced everywhere
+where water is subjected to the friction of air which flows over it.
+While tidal waves come upon the shores but twice each day, the wind
+waves of ordinary size which roll in from the ocean deliver their
+blows at intervals of from three to ten seconds. Although the tidal
+waves sometimes, by a packing-up process, attain the height of fifty
+feet, their average altitude where they come in contact with the shore
+probably does not much exceed four feet; usually they come in gently.
+It is likely that in a general way the ocean surges which beat against
+the coast are of greater altitude.
+
+Wind waves are produced and perform their work in a manner which we
+shall now describe. When the air blows over any resisting surface, it
+tends, in a way which we can hardly afford here to describe, to
+produce motions. If the particle is free to move under the impulse
+which it communicates, it bears it along; if it is linked together in
+the manner of large masses, which the wind can not transport, it tends
+to set it in motion in an alternating way. The sounds of our musical
+instruments which act by wind are due to these alternating vibrations,
+such as all air currents tend to produce. An AEolian harp illustrates
+the action which we are considering. Moving over matter which has the
+qualities that we denote by the term fluid, the swayings which the air
+produces are of a peculiar sort, though they much resemble those of
+the fiddle string. The surface of the liquid rises and falls in what
+we term waves, the size of which is determined by the measure of
+fluidity, and by the energy of the wind. Thus, because fresh water is
+considerably lighter than salt, a given wind will produce in a given
+distance for the run of the waves heavier surges in a lake than it
+will in the sea. For this reason the surges in a great storm which
+roll on the ocean shore, because of the wide water over which they
+have gathered their impetus, are in size very much greater than those
+of the largest lakes, which do not afford room for the development of
+great undulations.
+
+To the eye, a wave in the water appears to indicate that the fluid is
+borne on before the wind. Examination, however, shows that the amount
+of motion in the direction in which the wind is blowing is very
+slight. We may say, indeed, that the essential feature of a wave is
+found in the transmission of impulse rather than in the movement of
+the fluid matter. A strip of carpet when shaken sends through its
+length undulations which are almost exactly like water waves. If we
+imagine ourselves placed in a particle of water, moving in the
+swayings of a wave in the open and deep sea, we may conceive ourselves
+carried around in an ellipse, in each revolution returning through
+nearly the same orbit. Now and then, when the particle came to the
+surface, it would experience the slight drift which the continual
+friction of the wind imposes on the water. If the wave in which the
+journey was made lay in the trade winds, where the long-continued,
+steadfast blowing had set the water in motion to great depths, the
+orbit traversed would be moving forward with some rapidity; where also
+the wind was strong enough to blow the tops of the waves over, forming
+white-caps, the advance of the particle very near the surface would be
+speedy. Notwithstanding these corrections, waves are to be regarded
+each as a store of energy, urging the water to sway much in the manner
+of a carpet strip, and by the swaying conveying the energy in the
+direction of the wave movement.
+
+The rate of movement of wind waves increases with their height.
+Slight undulations go forward at the rate of less than half a mile an
+hour. The greater surges of the deeps when swept by the strongest
+winds move with the speed which, though not accurately determined, has
+been estimated by the present writer as exceeding forty miles an hour.
+As these surges often have a length transverse to the wind of a mile
+or more, a width of about an eighth of a mile, and a height of from
+thirty-five to forty-five feet, the amount of energy which they
+transmit is very great. If it could be effectively applied to the
+shores in the manner in which the energy of exploding gunpowder is
+applied by cannon shot, it is doubtful whether the lands could have
+maintained their position against the assaults of the sea. But there
+are reasons stated below why the ocean waves can use only a very small
+part of their energy in rending the rocks against which they strike on
+the coast line.
+
+In the first place, we should note that wind waves have very little
+influence on the bottom of the deep sea. If an observer could stand on
+the sea floor at the depth of a mile below a point over which the
+greatest waves were rolling, he could not with his unaided senses
+discern that the water was troubled. He would, indeed, require
+instruments of some delicacy to find out that it moved at all. Making
+the same observations at the depth of a thousand feet, it is possible
+that he would note a slight swaying motion in the water, enough
+sensibly to affect his body. At five hundred feet in depth the
+movement would probably be sufficient to disturb fine mud. At two
+hundred feet, the rasping of the surge on the bottom would doubtless
+be sufficient to push particles of coarse sand to and fro. At one
+hundred feet in depth, the passage of the surge would be strong enough
+to urge considerable pebbles before it. Thence up the slope the
+driving action would become more and more intense until we attained
+the point where the wave broke. It should furthermore be noted that,
+while the movement of the water on the floor of the deep sea as the
+wave passes overhead would be to and fro, with every advance in the
+shallowing and consequent increased friction on the bottom, the
+forward element in the movement would rapidly increase. Near the coast
+line the effect of the waves is continually to shove the detritus up
+the slopes of the continental shelf. Here we should note the fact that
+on this shelf the waves play a part exactly the opposite of that
+effected by the tides. The tides, as we have noted, tend to drag the
+particles down the slope, while the waves operate to roll them up the
+declivity.
+
+As the wave in advancing toward the shore ordinarily comes into
+continually shallowing water, the friction on the bottom is
+ever-increasing, and serves to diminish the energy the surge contains,
+and therefore to reduce its proportions. If this action operated
+alone, the subtraction which the friction makes would cause the surf
+waves which roll in over a continental shelf to be very low, probably
+in height less than half that which they now attain. In fact, however,
+there is an influence at work to increase the height of the waves at
+the expense of its width. Noting that the friction rapidly increases
+with the shallowing, it is easy to see that this resistance is
+greatest on the advancing front of the wave, and least on its seaward
+side. The result is that the front moves more slowly than the rear, so
+that the wave is forced to gain in height; but for the fact that the
+total friction which the wave encounters takes away most of its
+impetus, we might have combers a hundred feet high rolling upon the
+shelving shores which almost everywhere face the seas.
+
+As the wave shortens its width and gains in relative height, though
+not in actual elevation, another action is introduced which has
+momentous consequences. The water in the bottom of the wave is greatly
+retarded in its ongoing by its friction over the sea floor, while the
+upper part of the surge is much less affected in this way. The result
+is that at a certain point in the advance, the place of which is
+determined by the depth, the size, and the speed of the undulation,
+the front swiftly steepens until it is vertical, and the top shoots
+forward to a point where it is no longer supported by underlying
+water, when it plunges down in what is called the surf or breaker. In
+this part of the wave's work the application of the energy which it
+transmits differs strikingly from the work previously done. Before the
+wave breaks, the only geological task which it accomplishes is
+effected by forcing materials up the slope, in which movement they are
+slightly ground over each other until they come within the battering
+zone of the shore, where they may be further divided by the action of
+the mill which is there in operation.
+
+When the wave breaks on the shore it operates in the following manner:
+First, the overturning of its crest sends a great mass of water, it
+may be from the height of ten or more feet, down upon the shore. Thus
+falling water has not only the force due to its drop from the summit
+of the wave, but it has a share of the impulse due to the velocity
+with which the surge moved against the shore. It acts, in a word, like
+a hammer swung down by a strong arm, where the blow represents not
+only the force with which the weight would fall of itself, but the
+impelling power of the man's muscles. Any one who will expose his body
+to this blow of the surf will recognise how violent it is; he may, if
+the beach be pebbly, note how it drives the stones about; fragments
+the size of a man's head may be hurled by the stroke to the distance
+of twenty feet or more; those as large as the fist may be thrown clear
+beyond the limits of the wave. So vigorous is this stroke that the
+sound of it may sometimes be heard ten miles inland from the coast
+where it is delivered.
+
+Moving forward up the slope of a gently inclined beach, the fragments
+of the wave are likely to be of sufficient volume to permit them to
+regather into a secondary surge, which, like the first, though much
+smaller, again rises into a wall, forming another breaker. Under
+favourable conditions as many as four or five of these successive
+diminishing surf lines may be seen. The present writer has seen in
+certain cases as many as a dozen in the great procession, the lowest
+and innermost only a few inches high, the outer of all with a height
+of perhaps twenty feet.
+
+Along with the direct bearing action of the surf goes a to-and-fro
+movement, due to the rushing up and down of the water on the beach.
+This swashing affects not only the broken part of the waves, but all
+the water between the outer breaker and the shore. These swayings in
+the surf belt often swing the _debris_ on the inner margin over a
+range of a hundred feet or more, the movement taking place with great
+swiftness, affecting the pebbles to the depth of several inches, and
+grinding the bits together in a violent way. Listening to the turmoil
+of a storm, we can on a pebbly beach distinctly hear the sound of the
+downward stroke, a crashing tone, and the roar of the rolling stones.
+
+As waves are among the interesting things in the world, partly on
+account of their living quality and partly because of their immediate
+and often exceeding interest to man, we may here note one or two
+peculiar features in their action. In the first place, as the reader
+who has gained a sense of the changes in form of action may readily
+perceive, the beating of waves on the shore converts the energy which
+they possess into heat. This probably warms the water during great
+storms, so that by the hand we may note the difference in temperature
+next the coast line and in the open waters. This relative warmth of
+the surf water is perhaps a matter of some importance in limiting the
+development of ice along the shore line; it may also favour the
+protection of the coast life against the severe cold of the winter
+season.
+
+The waves which successively come against the shore in any given time,
+particularly if a violent wind is blowing on to the coast, are usually
+of about the same size. When, however, in times of calm an old sea, as
+it is called, is rolling in, the surges may occasionally undergo very
+great variations in magnitude. Not infrequently these occasional waves
+are great enough to overwhelm persons who are upon the rocks next the
+shore. These greater surges are probably to be accounted for by the
+fact that in the open sea waves produced by winds blowing in different
+directions may run on with their diverse courses and varied intervals
+until they come near the shore. Running in together, it very well
+happens that two of the surges belonging to different sets may combine
+their forces, thus doubling the swell. The danger which these
+conjoined waves bring is obviously greatest on cliff shores, where, on
+account of the depth of water, the waves do not break until they
+strike the steep.
+
+                  *       *       *       *       *
+
+Having considered in a general way the action of waves as they roll in
+to the shore, bearing with them the solar energy which was contributed
+to them by the winds, we shall now take up in some detail the work
+which goes on along the coast line--work which is mainly accomplished
+by wave action.
+
+On most coast lines the observer readily notes that the shore is
+divided into two different kinds of faces--those where the inner
+margin of the wave-swept belt comes against rocky steeps, and those
+bordered by a strand altogether composed of materials which the surges
+have thrown up. These may be termed for convenience cliff shores and
+wall-beach shores. We shall begin our inquiry with cliff shores, for
+in those sections of the coast line the sea is doing its most
+characteristic and important work of assaulting the land. If the
+student has an opportunity to approach a set of cliffs of hard rock in
+time of heavy storm, when the waves have somewhere their maximum
+height, he should seek some headland which may offer him safe foothold
+whence he can behold the movements which are taking place. If he is so
+fortunate as to have in view, as well may be the case, cliffs which
+extend down into deep water, and others which are bordered by rude
+and generally steeply sloping beaches covered with large stones, he
+may perceive that the waves come in against the cliffs which plunge
+into deep water without taking on the breaker form. In this case the
+undulation strikes but a moderate blow; the wave is not greatly
+broken. The part next the rock may shoot up as a thin sheet to a
+considerable height; it is evident that while the ongoing wave applies
+a good deal of pressure to the steep, it does not deliver its energy
+in the effective form of a blow as when the wave overturns, or in the
+consequent rush of the water up a beach slope. It is easy to perceive
+that firm-set rock cliffs, with no beaches at their bases, can almost
+indefinitely withstand the assaults. On the steep and stony beach,
+because of its relatively great declivity, the breaker or surf forms
+far in, and even in its first plunge often attains the base of the
+precipice. The blow of the overfalling as well as that of the inrush
+moves about stones of great size; those three feet or more in diameter
+are often hurled by the action against the base of the steep, striking
+blows, the sharp note of which can often be heard above the general
+roar which the commotion produces. The needlelike crags forming isles
+standing at a distance from the shore, such as are often found along
+hard rock coasts, are singularly protected from the action of
+effective waves. The surges which strike against them are unarmed with
+stones, and the water at their bases is so deep that it does not sway
+with the motion with sufficient energy to move them on the bottom.
+Where a cliff is in this condition, it may endure until an elevation
+of the coast line brings its base near the level of the sea, or until
+the process of decay has detached a sufficient quantity of stone to
+form a talus or inclined plane reaching near to the water level.
+
+As before noted, it is the presence of a sloping beach reaching to
+about the base of the cliff which makes it possible for the waves to
+strike at with a hammer instead of with a soft hand. Battering at the
+base of the cliff, the surges cut a crease along the strip on which
+they strike, which gradually enters so far that the overhanging rock
+falls of its own weight. The fragments thus delivered to the sea are
+in turn broken up and used as battering instruments until they are
+worn to pieces. We may note that in a few months of heavy weather the
+stones of such a fall have all been reduced to rudely spherical forms.
+Observations made on the eastern face of Cape Ann, Mass., where the
+seas are only moderately heavy, show that the storms of a single
+winter reduce the fragments thrown into the sea from the granite
+quarries to spheroidal shapes, more than half of their weight commonly
+being removed in the form of sand and small pebbles which have been
+worn from their surfaces.
+
+We can best perceive the effect of battering action which the sea
+applies to the cliffs by noting the points where, owing to some chance
+features in the structure in the rock, it has proved most effective.
+Where a joint or a dike, or perhaps a softer layer, if the rocks be
+bedded, causes the wear to go on more rapidly, the waves soon excavate
+a recess in which the pebbles are retained, except in stormy weather,
+in an unmoved condition. When the surges are heavy, these stones are
+kept in continuous motion, receding as the wave goes back, and rushing
+forward with its impulse until they strike against the firm-set rock
+at the end of the chasm. In this way they may drive in a cut having
+the length of a hundred feet or more from the face of the precipice.
+In most cases the roofs over these sea caves fall in, so that the
+structure is known as a chasm. Occasionally these roofs remain, in
+which case, for the reason that the floor of the cutting inclines
+upward, an opening is made to the surface at their upper end, forming
+what is called in New England a "spouting horn"; from the inland end
+of the tunnel the spray may be thrown far into the air. As long as the
+cave is closed at this inner end, and is not so high but that it may
+be buried beneath a heavy wave, the inrushing water compresses the
+air in the rear parts of the opening. When the wave begins to retreat
+this air blows out, sending a gust of spray before it, the action
+resembling the discharge of a great gun from the face of a
+fortification. It often happens that two chasms converging separate a
+rock from the cliff. Then a lowering of the coast may bring the mass
+to the state of a columnar island, such as abound in the Hebrides and
+along various other shores.
+
+If a cliff shore retreats rapidly, it may be driven back into the
+shore, and its face assumes the curve of a small bay. With every step
+in this change the bottom is sure to become shallower, so that the
+waves lose more and more of their energy in friction over the bottom.
+Moreover, in entering a bay the friction which the waves encounter in
+running along the sides is greater than that which they meet in
+coming in upon a headland or a straight shore. The result is, with the
+inward retreat of the steep it enters on conditions which diminish the
+effectiveness of the wave stroke. The embayment also is apt to hold
+detritus, and so forms in time a beach at the foot of the cliff, over
+which the waves rarely are able to mount with such energy as will
+enable them to strike the wall in an effective manner. With this
+sketch of the conditions of a cliff shore, we will now consider the
+fate of the broken-tip rock which the waves have produced on that
+section of the coast land.
+
+By observation of sea-beaten cliffs the student readily perceives that
+a great amount of rocky matter has been removed from most cliff-faced
+shores. Not uncommonly it can be shown that such sea faces have
+retreated for several miles. The question now arises, What becomes of
+the matter which has been broken up by the wave action? In some part
+the rock, when pulverized by the pounding to which it is subjected,
+has dissolved in the water. Probably ninety per cent of it, however,
+retains the visible state, and has a fate determined by the size of
+the fragments of which it is composed. If these be as fine as mud, so
+that they may float in the water, they are readily borne away by the
+currents which are always created along a storm-swept shore,
+particularly by the undertow or bottom outcurrent--the "sea-puss," as
+it is sometimes called--that sweeps along the bottom from every shore,
+against which the waves form a surf. If as coarse as sand grains, or
+even very small pebbles, they are likely to be drawn out, rolling over
+the bottom to an indefinite distance from the sea margin. The coarser
+stones, however, either remain at the foot of the cliff until they are
+beaten to pieces, or are driven along the shore until they find some
+embayment into which they enter. The journey of such fragments may,
+when the wind strikes obliquely to the shore, continue for many miles;
+the waves, running with the wind, drive the fragments in oscillating
+journeys up and down the beach, sometimes at the rate of a mile or
+more a day. The effect of this action can often be seen where a vessel
+loaded with brick or coal is wrecked on the coast. In a month
+fragments of the materials may be stretched along for the distance of
+many miles on either side of the point where the cargo came ashore.
+Entering an embayment deep enough to restrain their further journey,
+the fragments of rock form a boulder beach, where the bits roll to and
+fro whenever they are struck by heavy surges. The greater portion of
+them remain in this mill until they are ground to the state of sand
+and mud. Now and then one of the fragments is tossed up beyond the
+reach of the waves, and is contributed to the wall of the beach. In
+very heavy storms these pebbles which are thrown inland may amount in
+weight to many tons for each mile of shore.
+
+The study of a pebbly beach, drawn from crest to the deep water
+outside, will give an idea as to the history of its work. On either
+horn of the crescent by which the pebbles are imported into the pocket
+we find the largest fragments. If the shore of the bay be long, the
+innermost part of the recess may show even only very small pebbles, or
+perhaps only fine sand, the coarser material having been worn out in
+the journey. On the bottom of the bay, near low tide, we begin to find
+some sand produced by the grinding action. Yet farther out, below
+high-tide mark, there is commonly a layer of mud which represents the
+finer products of the mill.
+
+Boulder beaches are so quick in answering to every slight change in
+the conditions which affect them that they seem almost alive. If by
+any chance the supply of detritus is increased, they fill in between
+the horns, diminish the incurve of the bay, and so cause its beach to
+be more exposed to heavy waves. If, on the other hand, the supply of
+grist to the mill is diminished, the beach becomes more deeply
+incurved, and the wave action is proportionately reduced. We may say,
+in general, that the curve of these beaches represents a balance
+between the consumption and supply of the pebbles which they grind up.
+The supply of pebbles brought along the shore by the waves is in many
+cases greatly added to by a curious action of seaweeds. If the bottom
+of the water off the coast is covered by these fragments, as is the
+case along many coast lines within the old glaciated districts, the
+spores of algae are prone to take root upon them. Fastening themselves
+in those positions, and growing upward, the seaweeds may attain
+considerable size. Being provided with floats, the plant exercises a
+certain lifting power on the stone, and finally the tugging action of
+the waves on the fronds may detach the fragments from the bottom,
+making them free to journey toward the shore. Observing from near at
+hand the straight wall of the wave in times of heavy storm, the
+present writer has seen in one view as many as a dozen of these
+plant-borne stones, sometimes six inches in diameter, hanging in the
+walls of water as it was about to topple over. As soon as they strike
+the wave-beaten part of the shore these stones are apt to become
+separated from the plants, though we can often notice the remains or
+prints of the attachments adhering to the surface of the rock. Where
+the pebbles off the shore are plenty, a rocky beach may be produced
+by this process of importation through the agency of seaweeds without
+any supply being brought by the waves along the coast line.
+
+Returning to sand beaches, we enter the most interesting field of
+contact between seas and lands. Probably nine tenths of all the coast
+lines of the open ocean are formed of arenaceous material. In general,
+sand consists of finely broken crystals of silica or quartz. These
+bits are commonly distinctly faceted; they rarely have a spherical
+form. Not only do accumulations of sand border most of the shore line,
+but they protect the land against the assaults of the sea, and this in
+the following curious manner: When shore waves beat pebbles against
+each other, they rapidly wear to bits; we can hear the sound of the
+wearing action as the wave goes to and fro. We can often see that the
+water is discoloured by the mud or powdered rock. When, however, the
+waves tumble on a sandy coast, they make but a muffled sound, and
+produce no mud. In fact, the particles of sand do not touch each other
+when they receive the blow. Between them there lies a thin film of
+water, drawn in by the attraction known as capillarity, which sucks
+the fluid into a sponge or between plates of glass placed near
+together. The stroke of the waves slightly compresses this capillary
+water, but the faces of the grains are kept apart as sheets of glass
+may be observed to be restrained from contact when water is between
+them. If the reader would convince himself as to the condition of the
+sand grains and the water which is between them, he may do so by
+pressing his foot on the wet beach which the wave has just left. He
+will observe that it whitens and sinks a little under the pressure,
+but returns in good part to its original form when the foot is lifted.
+In the experiment he has pushed a part of the contained water aside,
+but he has not brought the grains together; they do not make the sound
+which he will often hear when the sand is dry. The result is that the
+sand on the seashore may wear more in going the distance of a mile in
+the dry sand dune than in travelling for hundreds along the wet shore.
+
+If the rock matter in the state of sand wore as rapidly under the
+heating of the waves as it does in the state of pebbles, the
+continents would doubtless be much smaller than they are. Those coasts
+which have no other protection than is afforded by a low sand beach
+are often better guarded against the inroads of the sea than the
+rock-girt parts of the continents. It is on account of this remarkable
+endurance of sand of the action of the waves that the stratified rocks
+which make up the crust of the earth are so thick and are to such an
+extent composed of sand grains.
+
+The tendency of the _debris_-making influences along the coast line is
+to fill in the irregularities which normally exist there; to batter
+off the headlands, close up the bays and harbours, and generally to
+reduce the shores to straight lines. Where the tide has access to
+these inlets, it is constantly at work in dragging out the detritus
+which the waves make and thrust into the recesses. These two actions
+contend with each other, and determine the conditions of the coast
+line, whether they afford ports for commerce or are sealed in by sand
+bars, as are many coast lines which are not tide-swept, as that of
+northern Africa, which faces the Mediterranean, a nearly tideless sea.
+The same is the case with the fresh-water lakes; even the greater of
+them are often singularly destitute of shelters which can serve the
+use of ships, and this because there are no tides to keep the bays and
+harbours open.
+
+
+                        THE OCEAN CURRENTS.
+
+The system of ocean currents, though it exhibits much complication in
+detail, is in the main and primarily dependent on the action of the
+constant air streams known as the trade winds. With the breath from
+the lips over a basin of water we can readily make an experiment which
+shows in a general way the method in which the winds operate in
+producing the circulation of the sea. Blowing upon the surface of the
+water in the basin, we find that even this slight impulse at once sets
+the upper part in motion, the movement being of two kinds--pulsating
+movements or waves are produced, and at the same time the friction of
+the air on the surface causes its upper part to slide over the under.
+With little floats we can shortly note that the stream which forms
+passes to the farther side of the vessel, there divides, and returns
+to the point of beginning, forming a double circle, or rather two
+ellipses, the longer sides of which are parallel with the line of the
+air current. Watching more closely, aiding the sight by the particles
+which float at various distances below the surface, we note the fact
+that the motion which was at first imparted to the surface gradually
+extends downward until it affects the water to the depth of some
+inches.
+
+In the trade-wind belt the ocean waters to the depth of some hundreds
+of feet acquire a continuous movement in the direction in which they
+are impelled by those winds. This motion is most rapid at the surface
+and near the tropics. It diminishes downwardly in the water, and also
+toward the polar sides of the trade-wind districts. Thus the trades
+produce in the sea two broad, slow-moving, deep currents, flowing in
+the northern hemisphere toward the southwest, and in the southern
+hemisphere toward the northwest. Coming down upon each other
+obliquely, these broad streams meet about the middle of the tropical
+belt. Here, as before noted, the air of the trade winds leaves the
+surface and rises upward. The waters being retained on their level,
+form a current which moves toward the west. If the earth within the
+tropics were covered by a universal sea, the result of this movement
+would be the institution of a current which, flowing under the
+equator, would girdle the sphere.
+
+With a girdling equatorial current, because of the intense heat of the
+tropics and the extreme cold of the parallels beyond the fortieth
+degree of latitude, the earth would be essentially uninhabitable to
+man, and hardly so to any forms of life. Its surface would be visited
+by fierce winds induced by the very great differences of temperature
+which would then prevail. Owing, however, to the barriers which the
+continents interpose to the motions of these windward-setting tropical
+currents, all the water which they bear, when it strikes the opposing
+shores, is diverted to the right and left, as was the stream in the
+experiment with the basin and the breath, the divided currents seeking
+ways toward high latitudes, conveying their store of heat to the
+circumpolar lands. So effective is this transfer of temperature that a
+very large part of the heat which enters the waters in the tropical
+region is taken out of that division of the earth's surface and
+distributed over the realms of sea and land which lie beyond the
+limits of the vertical sun. Thus the Gulf Stream, the northern branch
+of the Atlantic tropical current, by flowing into the North Atlantic,
+contributes to the temperature of the region within the Arctic Circle
+more heat than actually comes to that district by the direct influx
+from the sun.
+
+The above statements as to the climatal effect of the ocean streams
+show us how important it is to obtain a sufficient conception as to
+the way in which these currents now move and what we can of their
+history during the geologic ages. This task can not yet be adequately
+done. The fields of the sea are yet too imperfectly explored to afford
+us all the facts required to make out the whole story. Only in the
+case of our Gulf Stream can we form a full conception as to the
+journey which the waters undergo and the consequence of their motion.
+In the case of this current, observations clearly show that it arises
+from the junction near the equatorial line of the broad stream created
+by the two trade-wind belts. Uniting at the equator, these produce a
+westerly setting current, having the width of some hundred miles and a
+depth of several hundred feet. Its velocity is somewhat greater than a
+mile an hour. The centre of the current, because of the greater
+strength of the northern as compared with the southern trades, is
+considerably south of the equator. When this great slow-moving stream
+comes against the coast of South America, it encounters the projecting
+shoulder of that land which terminates at Cape St. Roque. There it
+divides, as does a current on the bows of an anchored ship, a
+part--rather more than one half--of the stream turning to the
+northward, the remainder passing toward the southern pole; this
+northerly portion becomes what is afterward known as the Gulf Stream,
+the history of which we shall now briefly follow.
+
+Flowing by the northwesterly coast of South America, the northern
+share of the tropical current, being pressed in against the land by
+the trade winds, is narrowed, and therefore acquires at once a swifter
+flow, the increased speed being due to conditions like those which add
+to the velocity of the water flowing through a hose when it comes to
+the constriction of the nozzle. Attaining the line of the southeastern
+or Lesser Antilles, often known as the Windward Islands, a part of
+this current slips through the interspaces between these isles and
+enters the Gulf of Mexico. Another portion, failing to find sufficient
+room through these passages, skirts the Antilles on their eastern and
+northern sides, passes by and among the Bahama Islands, there to
+rejoin the part of the stream which entered the Caribbean. This
+Caribbean portion of the tide spreads widely in that broad sea, is
+constricted again between Cuba and Yucatan, again expands in the Gulf
+of Mexico, and is finally poured forth through the Straits of Florida
+as a stream having the width of forty or fifty miles, a depth of a
+thousand feet or more, and a speed of from three to five miles an
+hour, exceeding in its rate of flow the average of the greatest
+rivers, and conveying more water than do all the land streams of the
+earth. In this part of its course the deep and swift stream from the
+Gulf of Mexico, afterward to be named the Gulf Stream, receives the
+contribution of slower moving and shallower currents which skirted the
+Antilles on their eastern verge. The conjoined waters then move
+northward, veering toward the east, at first as a swift river of the
+sea having a width of less than a hundred miles and of great depth;
+with each step toward the pole this stream widens, diminishing
+proportionately in depth; the speed of its current decreases as the
+original impetus is lost, and the baffling winds set its surface
+waters to and fro in an irregular way. Where it passes Cape Hatteras
+it has already lost a large share of its momentum and much of its
+heat, and is greatly widened.
+
+Although the current of the Gulf Stream becomes more languid as we go
+northward, it for a very long time retains its distinction from the
+waters of the sea through which it flows. Sailing eastward from the
+mouth of the Chesapeake, the navigator can often observe the moment
+when he enters the waters of this current. This is notable not only in
+the temperature, but in the hue of the sea. North of that line the
+sharpness of the parting wall becomes less distinct, the stream
+spreads out broadly over the surface of the Atlantic, yet its
+thermometric effects are distinctly traceable to Iceland and Nova
+Zembla, and the tropical driftwood which it carries affords the
+principal timber supply of the inhabitants of the first-named isle.
+Attaining this circumpolar realm, and finally losing the impulse which
+bore it on, the water of the Gulf Stream partly returns to the
+southward in a relatively slight current which bears the fluid along
+the coast of Europe until it re-enters the system of tropical winds
+and the currents which they produce. A larger portion stagnates in the
+circumpolar region, in time slowly to return to the tropical district
+in a manner afterward to be described. Although the Gulf Stream in the
+region north of Cape Hatteras is so indistinct that its presence was
+not distinctly recognised until the facts were subjected to the keen
+eye of Benjamin Franklin, its effects in the way of climate are so
+great that we must attribute the fitness of northern Europe for the
+uses of civilized man to its action. But for the heat which this
+stream brings to the realm of the North Atlantic, Great Britain would
+be as sterile as Labrador, and the Scandinavian region, the
+cradle-land of our race, as uninhabitable as the bleakest parts of
+Siberia.
+
+It is a noteworthy fact that when the equatorial current divides on
+the continents against which it flows, the separate streams, although
+they may follow the shores for a certain distance toward the poles,
+soon diverge from them, just as the Gulf Stream passes to the seaward
+from the eastern coast of the United States. The reason for this
+movement is readily found in the same principle which explains the
+oblique flow of the trades and counter trades in their passage to and
+from the equatorial belt. The particle of water under the equator,
+though it flows to the west, has, by virtue of the earth's rotation,
+an eastward-setting velocity of a thousand miles an hour. Starting
+toward the poles, the particle is ever coming into regions of the sea
+where the fluid has a less easterly movement, due to the earth's
+rotation on its axis. Consequently the journeying water by its
+momentum tends to move off in an easterly course. Attaining high
+latitudes and losing its momentum, it abides in the realm long enough
+to become cooled.
+
+We have already noted the fact that only a portion of the waters sent
+northward in the Gulf Stream and the other currents which flow from
+the equator to the poles is returned by the surface flow which sets
+toward the equator along the eastern side of the basins. The largest
+share of the tide effects its return journey in other ways. Some
+portion of this remainder sets equatorward in local cold streams, such
+as that which pours forth through Davis Strait into Baffin Bay,
+flowing under the Gulf Stream waters for an unknown distance toward
+the tropics. There are several of these local as yet little known
+streams, which doubtless bring about a certain amount of circulation
+between the polar regions and the tropical districts. Their effect is,
+however, probably small as compared with that massive drift which we
+have now to note.
+
+The tropical waters when they attain high latitudes are constantly
+cooled, and are overlaid by the warmer contributions of that tide, and
+are thus brought lower and lower in the sea. When they start downward
+they have, as observations show, a temperature not much above the
+freezing point of salt water. They do not congeal for the reason that
+the salt of the ocean lowers the point at which the water solidifies
+to near 28 deg. Fahr. The effect of this action is gradually to press down
+the surface cold water until it attains the very bottom in all the
+circumpolar regions. At the same time this descending water drifts
+along the bottom of the ocean troughs toward the equatorial realm. As
+this cold water is heavier than that which is of higher temperature
+and nearer the surface, it has no tendency to rise. Being below the
+disturbing influences of any current save its own, it does not tend,
+except in a very small measure, to mingle with the warmer overlying
+fluid. The result is that it continues its journey until it may come
+within the tropics without having gained a temperature of more than
+35 deg. Fahr., the increase in heat being due in small measure to that
+which it receives from the earth's interior and that which it acquires
+from the overlying warmer water. Attaining the region of the tropical
+current, this drift water from the poles gradually rises, to take the
+place of that which goes poleward, becomes warm, and again starts on
+its surface journey toward the arctic and antarctic regions.
+
+Nothing is known as to the rate of this bottom drift from the polar
+districts toward the equator, but, from some computation which he has
+made, the writer is of the opinion that several centuries is doubtless
+required for the journey from the Arctic Circle to the tropics. The
+speed of the movement probably varies; it may at times require some
+thousand years for its accomplishment. The effect of the bottom drift
+is to withdraw from seas in high latitudes the very cold water which
+there forms, and to convey it beneath the seas of middle latitudes to
+a realm where it is well placed for the reheating process. If all the
+cold water of circumpolar regions had to journey over the surface to
+the equator, the perturbing effect of its flow on the climates of
+various lands would be far greater than it is at present. Where such
+cold currents exist the effect is to chill the air without adding much
+to the rainfall; while the currents setting northward not only warm
+the regions near which they flow, but by so doing send from the water
+surfaces large quantities of moisture which fall as snow or rain. Thus
+the Gulf Stream, directly and indirectly, probably contributes more
+than half the rainfall about the Atlantic basin. The lack of this
+influence on the northern part of North America and Asia causes those
+lands to be sterilized by cold, although destitute of permanent ice
+and snow upon their surfaces.
+
+We readily perceive that the effect of the oceanic circulation upon
+the temperatures of different regions is not only great but widely
+contrasted. By taking from the equatorial belt a large part of the
+heat which falls within that realm, it lowers the temperature to the
+point which makes the district fit for the occupancy of man, perhaps,
+indeed, tenable to all the higher forms of life. This same heat
+removed to high latitudes tempers the winter's cold, and thus makes a
+vast realm inhabitable which otherwise would be locked in almost
+enduring frosts. Furthermore, this distribution of temperatures tends
+to reduce the total wind energy by diminishing the trades and counter
+trades which are due to the variations of heat which are encountered
+in passing polarward from the equator. Still further, but for this
+circulation of water in the sea, the oceans about the poles would be
+frozen to their very bottom, and this vast sheet of ice might be
+extended southward to within the parallels of fifty degrees north and
+south latitude, although the waters under the equator might at the
+same time be unendurably hot and unfit for the occupancy of living
+beings.
+
+A large part of the difficulties which geologists encounter in
+endeavouring to account for the changes of the past arise from the
+evidences of great climatal revolutions which the earth has undergone.
+In some chapters of the great stone book, whose leaves are the strata
+of the earth, we find it plainly written in the impressions made by
+fossils that all the lands beyond the equatorial belt have undergone
+changes which can only be explained by the supposition that the heat
+and moisture of the countries have been subjected to sudden and
+remarkable changes. Thus in relatively recent times thick-leaved
+plants which retained their vegetation in a rather tender state
+throughout the year have flourished near to the poles, while shortly
+afterward an ice sheet, such as now covers the greater part of
+Greenland, extended down to the line of the Ohio River at Cincinnati.
+Although these changes of climate are, as we shall hereafter note,
+probably due to entangled causes, we must look upon the modifications
+of the ocean streams as one of the most important elements in the
+causation. We can the more readily imagine such changes to be due to
+the alterations in the course and volume of the ocean current when we
+note how trifling peculiarities in the geography of the
+shores--features which are likely to be altered by the endless changes
+which occur in the form of a continent--affect the run of these
+currents. Thus the growth of coral reefs in southern Florida, and, in
+general, the formation of that peninsula, by narrowing the exit of the
+great current from the Gulf of Mexico, has probably increased its
+velocity. If Florida should again sink down, that current would go
+forth into the North Atlantic with the speed of about a mile an hour,
+and would not have momentum enough to carry its waters over half the
+vast region which they now traverse. If the lands about the western
+border of the Caribbean Sea, particularly the Isthmus of Darien,
+should be depressed to a considerable depth below the ocean level,
+the tropical current would enter the Pacific Ocean, adding to the
+temperature of its waters all the precious heat which now vitalizes
+the North Atlantic region. Such a geographic accident would not only
+profoundly alter the life conditions of that part of the world, but it
+would make an end of European civilization.
+
+In the chapter on climatal changes further attention will be given to
+the action of ocean currents from the point of view of their influence
+on the heat and moisture of different parts of the world. We now have
+to consider the last important influence of ocean currents--that which
+they directly exercise on the development of organic life. The most
+striking effect of this nature which the sea streams bring about is
+caused by the ceaseless transportation to which they subject the eggs
+and seeds of animals and plants, as well as the bodies of the mature
+form which are moved about by the flowing waters. But for the
+existence of these north and south flowing currents, due to the
+presence of the continental barriers, the living tenants of the seas
+would be borne along around the earth, always in the same latitude,
+and therefore exposed to the same conditions of temperature. In this
+state of affairs the influences which now make for change in organic
+species would be far less than they are. Journeying in the great
+whirlpools which the continental barriers make out of the westward
+setting tropical currents, these organic species are ever being
+exposed to alterations in their temperature conditions which we know
+to be favourable to the creation of those variations on which the
+advance of organic life so intimately depends. Thus the ocean currents
+not only help to vary the earth by producing changes in the climate of
+both sea and land, breaking up the uniformity which would otherwise
+characterize regions at the same distance from the equator, but they
+induce, by the consequences of the migrations which they enforce,
+changes in the organic tenants of the sea.
+
+Another immediate effect of ocean streams arises where their currents
+of warm water come against shores or shallows of the sea. At these
+points, if the water have a tropical temperature, we invariably find a
+vast and rapid development of marine animals and plants, of which the
+coral-making polyps are the most important. In such positions the
+growth of forms which secrete solid skeletons is so rapid that great
+walls of their remains accumulate next the shore, the mass being built
+outwardly by successive growths until the realm of the land may be
+extended for scores of miles into the deep. In other cases vast mounds
+of this organic _debris_ may be accumulated in mid ocean until its
+surface is interspersed with myriads of islands, all of which mark the
+work due to the combined action of currents and the marine life which
+they nourish. Probably more than four fifths of all the islands in the
+tropical belt are due in this way to the life-sustaining action of the
+currents which the trade winds create.
+
+There are many secondary influences of a less important nature which
+are due to the ocean streams. The reader will find on most wall-maps
+of the world certain areas in the central part of the oceans which are
+noted as Sargassum seas, of which that of the North Atlantic, west and
+south of the Azore Islands, is one of the most conspicuous. In these
+tracts, which in extent may almost be compared with the continents, we
+find great quantities of floating seaweed, the entangled fronds of
+which often form a mass sufficiently dense to slightly restrain the
+speed of ships. When the men on the caravels of Columbus entered this
+tangle, they were alarmed lest they should be unable to escape from
+its toils. It is a curious fact that these weeds of the sea while
+floating do not reproduce by spores the structures which answer to the
+seeds of higher plants, but grow only by budding. It seems certain
+that they could not maintain their place in the ocean but for the
+action of the currents which convey the bits rent off from the shores
+where the plant is truly at home. This vast growth of plant life in
+the Sargassum basins doubtless contributed considerable and important
+deposits of sediment to the sea floors beneath the waters which it
+inhabits. Certain ancient strata, known as the Devonian black shale,
+occupying the Ohio valley and the neighbouring parts of North America
+to the east and north of that basin, appear to be accumulations which
+were made beneath an ancient Sargassum sea.
+
+The ocean currents have greatly favoured and in many instances
+determined the migrations not only of marine forms, but of land
+creatures as well. Floating timber may bear the eggs and seeds of many
+forms of life to great distances until the rafts are cast ashore in a
+realm where, if the conditions favour, the creatures may find a new
+seat for their life. Seeds of plants incased in their often dense
+envelopes may, because they float, be independently carried great
+distances. So it comes about that no sooner does a coral or other
+island rise above the waters of the sea than it becomes occupied by a
+varied array of plants. The migrations of people, even down to the
+time of the voyages which discovered America, have in large measure
+been controlled by the run of the ocean streams. The tropical set of
+the waters to the westward helped Columbus on his way, and enabled him
+to make a journey which but for their assistance could hardly have
+been accomplished. This same current in the northern part of the Gulf
+Stream opposed the passage of ships from northern Europe to the
+westward, and to this day affects the speed with which their voyages
+are made.
+
+
+                    THE CIRCUIT OF THE RAIN.
+
+We have now to consider those movements of the water which depend upon
+the fact that at ordinary temperatures the sea yields to the air a
+continued and large supply of vapour, a contribution which is made in
+lessened proportion by water in all stages of coldness, and even by
+ice when it is exposed to dry air. This evaporation of the sea water
+is proportional to the temperature and to the dryness of the air where
+it rests upon the ocean. It probably amounts on the average to
+somewhere about three feet per annum; in regions favourably situated
+for the process, as on the west coast of northern Africa, it may be
+three or four times as much, while in the cold and humid air about the
+poles it may be as little as one foot. When contributed to the air,
+the water enters on the state of vapour, in which state it tends to
+diffuse itself freely through the atmosphere by virtue of the motion
+which is developed in particles when in the vaporous or gaseous state.
+
+The greater part of the water evaporated from the seas probably finds
+its way as rain at once back into the deep, yet a considerable portion
+is borne away horizontally until it encounters the land. The
+precipitation of the water from the air is primarily due to the
+cooling to which it is subjected as it rises in the atmosphere. Over
+the sea the ascent is accomplished by the simple diffusion of the
+vapour or by the uprise through the aerial shaft, such as that near
+the equator or over the centres of the whirling storms. It is when the
+air strikes the slopes of the land that we find it brought into a
+condition which most decidedly tends to precipitate its moisture.
+Lifted upward, the air as it ascends the slopes is brought into cooler
+and more rarefied conditions. Losing temperature and expanding, it
+parts with its water for the same reason that it does in the ascending
+current in the equatorial belt or in the chimneys of the whirl storms.
+A general consequence of this is that wherever moisture-laden winds
+from the sea impinge upon a continent they lay down a considerable
+part of the water which they contain.
+
+If all the lands were of the same height, the rain would generally
+come in largest proportion upon their coastal belt, or those portions
+of the shore-line districts over which the sea winds swept. But as
+these winds vary in the amount of the watery vapour which they
+contain, and as the surface of the land is very irregular, the
+rainfall is the most variable feature in the climatal conditions of
+our sphere. Near the coasts it ranges from two or three inches in arid
+regions--such as the western part of the Sahara and portions of the
+coast regions of Chili and Peru--to eight hundred inches about the
+head waters of the Brahmapootra River in northern India, where the
+high mountains are swept over by the moisture-laden airs from the
+neighbouring sea. Here and there detached mountainous masses produce a
+singular local increase in the amount of the rainfall. Thus in the
+lake district in northwestern England the rainfall on the seaward side
+of mountains, not over four thousand feet high, is very much greater
+than it is on the other slope, less than a score of miles away. These
+local variations are common all over the world, though they are but
+little observed.
+
+In general, the central parts of continents are likely to receive much
+less rainfall than their peripheral portions. Thus the central
+districts of North America, Asia, and Australia--three out of the five
+continental masses--have what we may call interior deserts. Africa has
+one such, though it is north of the centre, and extends to the shores
+of the Mediterranean and the Atlantic. The only continent without this
+central nearly rainless field is South America, where the sole
+characteristic arid district is situated on the western slope of the
+Cordilleran range. In this case the peculiarity is due to the fact
+that the strong westerly setting winds which sweep over the country
+encounter no high mountains until they strike the Andean chain. They
+journey up a long and rather gradual slope, where the precipitation is
+gradually induced, the process being completed when they strike the
+mountain wall. Passing over its summit, they appear as dry winds on
+the Pacific coast.
+
+Even while the winds frequently blow in from the sea, as along the
+western coast of the Americas, they may come over water which is
+prevailingly colder than the land. This is characteristically the case
+on the western faces of the American continent, where the sea is
+cooled by the currents setting toward the equator from high latitudes.
+Such cool sea air encountering the warm land has its temperature
+raised, and therefore does not tend to lay down its burden of
+moisture, but seeks to take up more. On this account the rainfall in
+countries placed under such conditions is commonly small.
+
+By no means all the moisture which comes upon the earth from the
+atmosphere descends in the form of rain or snow. A variable, large,
+though yet undetermined amount falls in the form of dew. Dew is a
+precipitation of moisture which has not entered the peculiar state
+which we term fog or cloud, but has remained invisible in the air. It
+is brought to the earth through the radiation of heat which
+continually takes place, but which is most effective during the
+darkened half of the day, when the action is not counterbalanced by
+the sun's rays. While the sun is high and the air is warm there is a
+constant absorption of moisture in large part from the ground or from
+the neighbouring water areas, probably in some part from those
+suspended stores of water, the clouds, if such there be in the
+neighbourhood. We can readily notice how clouds drifting in from the
+sea often melt into the dry air which they encounter. Late in the
+afternoon, even before the sun has sunk, the radiation of heat from
+the earth, which has been going on all the while, but has been less
+considerable than the incurrent of temperature, in a way overtakes
+that influx. The air next the surface becomes cooled from its contact
+with the refrigerating earth, and parts with its moisture, forming a
+coating of water over everything it touches. At the same time the
+moisture escaping from the warmed under earth likewise drops back upon
+its cooled surface almost as soon as it has escaped. The thin sheet of
+water precipitated by this method is quickly returned to the air when
+it becomes warmed by the morning sunshine, but during the night
+quantities of it are absorbed by the plants; very often, indeed, with
+the lowlier vegetation it trickles down the leaves and enters the
+earth about the base of the stem, so that the roots may appropriate
+it. Our maize, or Indian corn, affords an excellent example of a plant
+which, having developed in a land of droughts, is well contrived,
+through its capacities for gathering dew, to protect itself against
+arid conditions. In an ordinary dew-making night the leaves of a
+single stem may gather as much as half a pint of water, which flows
+down their surfaces to the roots. So efficient is this dew supply,
+this nocturnal cloudless rain, that on the western coast of South
+America and elsewhere, where the ordinary supply of moisture is almost
+wanting, many important plants are able to obtain from it much of the
+water which they need. The effect is particularly striking along
+seashores, where the air, although it may not have the humidity
+necessary for the formation of rain, still contains enough to form
+dew.
+
+It is interesting to note that the quantity of dew which falls upon an
+area is generally proportioned to the amount of living vegetation
+which it bears. The surfaces of leaves are very efficient agents of
+radiation, and the tangle which they make offers an amount of
+heat-radiating area many times as great as that afforded by a surface
+of bared earth. Moreover, the ground itself can not well cool down to
+the point where it will wring the moisture out of the air, while the
+thin membranes of the plants readily become so cooled. Thus vegetation
+by its own structure provides itself with means whereby it may be in a
+measure independent of the accidental rainfall. We should also note
+the fact that the dewfall is a concomitant of cloudless skies. The
+quantity which is precipitated in a cloudy night is very small, and
+this for the reason that when the heavens are covered the heat from
+the earth can not readily fly off into space. Under these conditions
+the temperature of the air rarely descends low enough to favour the
+precipitation of dew.
+
+Having noted the process by which in the rain circuit the water
+leaves the sea and the conditions of distribution when it returns to
+the earth, we may now trace in more detail the steps in this great
+round. First, we should take note of the fact that the water after it
+enters the air may come back to the surface of the earth in either of
+two ways--directly in the manner of dewfall, or in a longer circuit
+which leads it through the state of clouds. As yet we are not very
+well informed as to the law of the cloud-making, but certain features
+in this picturesque and most important process have been tolerably
+well ascertained.
+
+Rising upward from the sea, the vapour of water commonly remains
+transparent and invisible until it attains a considerable height above
+the surface, where the cooling tends to make it assume again the
+visible state of cloud particles. The formation of these cloud
+particles is now believed to depend on the fact that the air is full
+of small dust motes, exceedingly small bits of matter derived from the
+many actions which tend to bring comminuted solid matter into the air,
+as, for instance, the combustion of meteoric stones, which are greatly
+heated by friction in their swift course through the air, the
+ejections of volcanoes, the smoke of forest and other fires, etc.
+These tiny bits, floating in the air, because of their solid nature
+radiate their heat, cool the air which lies against them, and thereby
+precipitate the water in the manner of dew, exactly as do the leaves
+and other structures on the surface of the earth. In fact, dew
+formation is essentially like cloud formation, except that in the one
+case the water is gathered on fixed bodies, and in the other on
+floating objects. Each little dust raft with its cargo of condensed
+water tends, of course, to fall downward toward the earth's surface,
+and, except for the winds which may blow upward, does so fall, though
+with exceeding slowness. Its rate of descent may be only a few feet a
+day. It was falling before it took on the load of water; it will fall
+a little more rapidly with the added burden, but even in a still air
+it might be months or years before it would come to the ground. The
+reason for this slow descent may not at first sight be plain, though a
+little consideration will make it so.
+
+If we take a shot of small size and a feather of the same weight, we
+readily note that their rate of falling through the air may vary in
+the proportion of ten to one or more. It is easy to conceive that this
+difference is due to the very much less friction which the smaller
+body encounters in its motion by the particles of air. With this point
+in mind, the student should observe that the surface presented by
+solid bodies in relation to their solid contents is the greater the
+smaller the diameter. A rough, though not very satisfactory, instance
+of this principle may be had by comparing the surface and interior
+contents of two boxes, one ten feet square and the other one foot
+square. The larger has six hundred feet of surface to one thousand
+cubic feet of interior, or about half a square foot of outer surface
+to the cubic foot of contents; while the smaller box has six feet of
+surface for the single cubic foot of interior, or about ten times the
+proportion of exterior to contents. The result is that the smaller
+particles encounter more friction in moving toward the earth, until,
+in the case of finely divided matter, such as the particles of carbon
+in the smoke from an ordinary fire, the rate of down-falling may be so
+small as to have little effect in the turbulent conditions of
+atmospheric motion.
+
+[Illustration: _Pocket Creek, Cape Ann, Massachusetts. Note the
+relatively even size of the pebbles, and the splash wave which sets
+them in motion._]
+
+The little drops of water which gather round dust motes, falling but
+slowly toward the earth, are free to obey the attractions which they
+exercise upon each other--impulses which are partly gravitative and
+partly electrical. We have no precise knowledge concerning these
+movements, further than that they serve to aggregate the myriad little
+floats into cloud forms, in which the rafts are brought near together,
+but do not actually touch each other. They are possibly kept apart by
+electrical repulsion. In this state of association without union the
+divided water may undergo the curiously modified aggregations which
+give us the varied forms of clouds. As yet we know little as to the
+cause of cloud shapes. We remark the fact that in the higher of these
+agglomerations of condensed vapour, the clouds which float at an
+elevation of from twenty to thirty thousand feet or more, the masses
+are generally thin, and arranged more or less in a leaflike form,
+though even here a tendency to produce spherical clouds is apparent.
+In this high realm floating water is probably in the frozen state,
+answering to the form of dew, which we call hoar frost. The lower
+clouds, gathering in the still air, show very plainly the tendency to
+agglomerate into spheres, which appears to be characteristic of all
+vaporous material which is free to move by its own impulses. It is
+probable that the spherical shape of clouds is more or less due to the
+same conditions as gathered the stellar matter from the ancient
+nebular chaos into the celestial spheres. Upon these spherical
+aggregations of the clouds the winds act in extremely varied ways. The
+cloud may be rubbed between opposite currents, and so flattened out
+into a long streamer; it may take the same form by being carried off
+by a current in the manner of smoke from a fire; the spheres may be
+kept together, so as to form the patchwork which we call "mackerel"
+sky; or they may be actually confounded with each other in a vast
+common cloud-heap. In general, where the process of aggregation of two
+cloud bodies occurs, changes of temperature are induced in the masses
+which are mixed together. If the temperature resulting from this
+association of cloud masses is an average increase, the cloud may
+become lighter, and in the manner of a balloon move upward. Each of
+the motes in the cloud with its charge of vapour may be compared with
+the ballast of the balloon; if they are warmed, they send forth a part
+of their load of condensed water again to the state of invisible
+vapour. Rising to a point where it cools, the vapour gathers back on
+the rafts and tends again to weight the cloud downward. The ballast of
+an ordinary balloon has to be thrown away from its car; but if some
+arrangement for condensing the moisture from the air could be
+contrived, a balloon might be brought into the adjustable state of a
+cloud, going up or down according as it was heated or cooled.
+
+When the formation of the drop of water or snowflake begins, the mass
+is very small. If in descending it encounters great thickness of
+cloud, the bit may grow by further condensation until it becomes
+relatively large. Generally in this way we may account for the
+diversities in the size of raindrops or snowflakes. It often happens
+that the particles after taking on the form of snowflakes encounter in
+their descent air so warm that they melt into raindrops, or, if only
+partly melted, reach the surface as sleet. Or, starting as raindrops,
+they may freeze, and in this simple state may reach the earth, or
+after freezing they may gather other frozen water about them, so that
+the hailstone has a complicated structure which, from the point of
+view of classification, is between a raindrop and a snowflake.
+
+In the process of condensation--indeed, in the steps which precede the
+formation of rain and snow--there is often more or less trace of
+electrical action; in fact, a part of the energy which was involved in
+the vapourization of water, on its condensation, even on the dust
+motes appears to be converted into electrical action, which probably
+operates in part to keep the little aggregates of water asunder. When
+they coalesce in drops or flakes, this electricity often assumes the
+form of lightning, which represents the swift passage of the electric
+store from a region where it is most abundant to one where it is less
+so. The variations in this process of conveying the electricity are
+probably great. In general, it probably passes, much as an electric
+current is conveyed, through a wire from the battery which produces
+the force. In other cases, where the tension is high, or, in other
+words, where the discharge has to be hastened, we have the phenomena
+of lightning in which the current burns its way along its path, as it
+may traverse a slender wire, vapourizing it as it goes. In general,
+the lightning flash expends its force on the air conductors, or lines
+of the moist atmosphere along which it breaks its path, its energy
+returning into the vapour which it forms or the heat which it produces
+in the other parts of the air. In some cases, probably not one in the
+thousand of the flashes, the charge is so heavy that it is not used up
+in its descent toward the earth, and so electrifies, or, as we say,
+strikes, some object attached to the earth, through which it passes to
+the underlying moisture, where it finds a convenient place to take on
+a quiet form. Almost all these hurried movements of electrical energy
+which intensely heat and light the air which they traverse fly from
+one part of a cloud to another, or cross from cloud sphere to cloud
+sphere; of those which start toward the earth, many are exhausted
+before they reach its surface, and even those that strike convey but a
+portion of their original impulse to the ground.
+
+The wearing-out effect of lightning in its journey along the air
+conductors in its flaming passages is well illustrated by what happens
+when the charge strikes a wire which is not large enough freely to
+convey it. The wire is heated, generally made white hot, often melted,
+and perhaps scattered in the form of vapour. In doing this work the
+electricity may, and often is, utterly dissipated--that is, changed
+into heat. It has been proposed to take advantage of this principle in
+protecting buildings from lightning by placing in them many thin
+wires, along which the current will try to make its way, being
+exhausted in melting or vaporizing the metal through which it passes.
+
+There are certain other forms of lightning, or at least of electrical
+discharges, which produce light and which may best be described in
+this connection. It occasionally happens that the earth becomes so
+charged that the current proceeds from its surface to the clouds. More
+rarely, and under conditions which we do not understand, the electric
+energy is gathered into a ball-like form, which may move slowly along
+the surface until it suddenly explodes. It is a common feature of all
+these forms of lightning which we have noted that they ordinarily make
+in their movement considerable noise. This is due to the sudden
+displacement of the air which they traverse--displacement due to the
+action of heat in separating the particles. It is in all essential
+regards similar to the sounds made by projectiles, such as meteors or
+swift cannon shots, as they fly through the air. It is even more
+comparable to the sound produced by exploding gunpowder. The first
+sound effect from the lightning stroke is a single rending note, which
+endures no longer--indeed, not as long--as the explosion of a cannon.
+Heard near by, this note is very sharp, reminding one of the sound
+made by the breaking of glass. The rolling, continuous sound which we
+commonly hear in thunder is, as in the case of the noise produced by
+cannon, due to echo from the clouds and the earth. Thunder is
+ordinarily much more prolonged and impressive in a mountainous country
+than in a region of plains, because the steeps about the hearer
+reverberate the original single crash.
+
+The distribution of thunderstorms is as yet not well understood, but
+it appears in many cases that they are attendants on the advancing
+face of cyclones and hurricanes, the area in front of these great
+whirlstorms being subjected to the condensation and irregular air
+movements which lead to the development of much electrical energy.
+There are, however, certain parts of the earth which are particularly
+subjected to lightning flashes. They are common in the region near the
+equator, where the ascending currents bring about heavy rains, which
+mean a rapid condensation and consequent liberation of electrical
+energy. They diminish in frequency toward the arctic regions. An
+observer at the pole would probably fail ever to perceive strong
+flashes. For the same reason thunderstorms are more frequent in
+summer, the time when the difference in temperature between the
+surface and the upper air is greatest, when, therefore, the uprushes
+of air are likely to be most violent. They appear to be more common in
+the night than in the daytime, for the reason that condensation is
+favoured by the cooling which occurs in the dark half of the day. It
+is rare, indeed, that a thunderstorm occurs near midday, a period when
+the air is in most cases taking up moisture on account of the swiftly
+increasing heat.
+
+There are other forms of electrical discharges not distinctly
+connected with the then existing condensation of moisture. What the
+sailors call St. Elmo's fire--a brush of electric light from the mast
+tops and other projections of the ship--indicates the passage of
+electrical energy between the vessel and the atmosphere. Similar
+lights are said sometimes to be seen rising from the surface of the
+water. Such phenomena are at present not satisfactorily explained.
+Perhaps in the same group of actions comes the so-called
+"Jack-o'-lantern" or "Will-o'-the-wisp" fires flashing from the earth
+in marshy places, which are often described by the common people, but
+have never been observed by a naturalist. If this class of
+illuminations really exists, we have to afford them some other
+explanation than that they are emanations of self-inflamed
+phosphoretted hydrogen, a method of accounting for them which
+illogically finds a place in many treatises on atmospheric phenomena.
+A gas of any kind would disperse itself in the air; it could not dance
+about as these lights are said to do, and there is no chemical means
+known whereby it could be produced in sufficient purity and quantity
+from the earth to produce the effects which are described.[3]
+
+[Footnote 3: The present writer has made an extended and careful study
+of marsh and swamp phenomena, and is very familiar with the aspect of
+these fields in the nighttime. He has never been able to see any sign of
+the Jack-o'-lantern light. Looking fixedly into any darkness, such as is
+afforded by the depths of a wood, the eye is apt to imagine the
+appearance of faint lights. Those who have had to do with outpost duty
+in an army know how the anxious sentry, particularly if he is new to the
+soldier's trade, will often imagine that he sees lights before him.
+Sometimes the pickets will be so convinced of the fact that they see
+lights that they will fire upon the fiction of the imaginations. These
+facts make it seem probable that the Jack-o'-lantern and his companion,
+the Will-o'-the-wisp, are stories of the overcredulous.]
+
+In the upper air, or perhaps even beyond the limits of the field
+which deserves the name, in the regions extending from the poles to
+near the tropics, there occur electric glowings commonly known as the
+aurora borealis. This phenomenon occurs in both hemispheres. These
+illuminations, though in some way akin to those of lightning, and
+though doubtless due to some form of electrical action, are peculiar
+in that they are often attended by glows as if from clouds, and by
+pulsations which indicate movements not at electric speed. As yet but
+little is known as to the precise nature of these curious storms. It
+has been claimed, however, that they are related to the sun spots;
+those periods when the solar spots are plenty, at intervals of about
+eleven years, are the times of auroral discharges. Still further, it
+seems probable that the magnetic currents of the earth, that circling
+energy which encompasses the sphere, moving round in a general way
+parallel to the equator, are intensified during these illuminations of
+the circumpolar skies.
+
+
+                    GEOLOGICAL WORK OF WATER.
+
+We turn now to the geological work which is performed by falling
+water. Where the rain or snow returns from the clouds to the sea, the
+energy of position given to the water by its elevation above the earth
+through the heat which it acquired from the sun is returned to the air
+through which it falls or to the ocean surface on which it strikes. In
+this case the circuit of the rain is short and without geological
+consequence which it is worth while to consider, except to note that
+the heat thus returned is likely to be delivered in another realm than
+that in which the falling water acquired the store, thus in a small
+way modifying the climate. When, however, the precipitation occurs on
+the surface of the land, the drops of frozen or fluid water apply a
+part of their energy in important geological work, the like of which
+is not done where they return at once to the sea.
+
+[Illustration: Fig. 10.--Showing the diverse action of rain on wooded
+and cleared fields, _a_, wooded area; _b_, tilled ground.]
+
+We shall first consider what takes place when the water in the form of
+drops of rain comes to the surface of the land. Descending as they do
+with a considerable speed, these raindrops apply a certain amount of
+energy to the surface on which they fall. Although the beat of a
+raindrop is proverbially light, the stroke is not ineffective.
+Observing what happens where the action takes place on the surface of
+bare rock, we may notice that the grains of sand or small pebbles
+which generally abound on such surfaces, if they be not too steeply
+inclined, dance about under the blows which they receive. If we could
+cover hard plate glass, a much firmer material than ordinary stone,
+with such bits, we should soon find that its surface would become
+scratched all over by the friction. Moreover, the raindrops
+perceptibly urge the small detached bits of stone down the slopes
+toward the streams.
+
+If all the earth's surface were bare rocks, the blow of the raindrops
+would deserve to be reckoned among the important influences which lead
+to the wearing of land. As it is, when a country is in a state of
+Nature, only a small part of its surface is exposed to this kind of
+wearing. Where there is rain enough to effect any damage, there is
+sure to be sufficient vegetation to interpose a living and
+self-renewed covering between the rocks and the rain. Even the lichens
+which coat what at first sight often seems to be bare rock afford an
+ample covering for this purpose. It is only where man bares the field
+by stripping away and overturning this protecting vegetation that the
+raindrops cut away the earth. The effect of their action can often be
+noted by observing how on ploughed ground a flat stone or a potsherd
+comes after a rain to cap a little column. The geologist sometimes
+finds in soft sandstones that the same action is repeated in a larger
+way where a thin fragment of hard rock has protected a column many
+feet in height against the rain work which has shorn down the
+surrounding rock.
+
+When water strikes the moistened surface it at once loses the droplike
+form which all fluids assume when they fall through the air.[4]
+
+[Footnote 4: This principle of the spheroidal form in falling fluids is
+used in making ordinary bird shot. The melted lead drops through
+sievelike openings, the resulting spheres of the metal being allowed to
+fall into water which chills them. Iron shot, used in cutting stone,
+where they are placed between the saw and the surface of the rock, are
+also made in the same manner. The descending fluid divides into drops
+because it is drawn out by the ever-increasing speed of the falling
+particles, which soon make the stream so thin that it can not hold
+together.]
+
+When the raindrops coalesce on the surface of the earth, the role of
+what we may call land water begins. Thenceforward until the fluid
+arrives at the surface of the sea it is continually at work in
+effecting a great range of geological changes, only a few of which can
+well be traced by the general student. The work of land water is due
+to three classes of properties--to the energy with which it is endowed
+by virtue of its height above the sea, a power due to the heat of the
+sun; to the capacity it has for taking substances into solution; and
+to its property of giving some part of its own substance to other
+materials with which it comes in contact. The first of these groups of
+properties may be called dynamical; the others, chemical.
+
+The dynamic value of water when it falls upon the land is the amount
+of energy it can apply in going down the slope which separates it from
+the sea. A ton of the fluid, such as may gather in an ordinary rain on
+a thousand square feet of ground in the highlands of a country--say at
+an elevation of a thousand feet above the sea--expends before it comes
+to rest in the great reservoir as much energy as would be required to
+lift that weight from the ocean's surface to the same height. The ways
+in which this energy may be expended we shall now proceed in a general
+way to trace.
+
+As soon as the water has been gathered, from its drop to its sheet
+state--a process which takes place as soon as it falls--the fluid
+begins its downward journey. On this way it is at once parted into two
+distinct divisions, the surface water and the ground water: the former
+courses more or less swiftly, generally at the rate of a mile or more
+an hour, in the light of day; the latter enters the interstices of the
+earth, slowly descends therein to a greater or less depth, and
+finally, journeying perhaps at the rate of a mile a year, rejoins the
+surface water, escaping through the springs. The proportion of these
+two classes, the surface and the ground water, varies greatly, and an
+intermixture of them is continually going on. Thus on the surface of
+bare rock or frozen earth all the rain may go away without entering
+the ground. On very sandy fields the heaviest rainfall may be taken
+up by the porous earth, so that no streams are found. On such surfaces
+the present writer has observed that a rainfall amounting to six
+inches in depth in two hours produced no streams whatever. We shall
+first follow the history of the surface water, afterward considering
+the work which the underground movements effect.
+
+If the student will observe what takes place on a level ploughed
+field--which, after all, will not be perfectly level, for all fields
+are more or less undulating--he will note that, though the surface may
+have been smoothed by a roller until it appears like a floor, the
+first rain, where the fall takes place rapidly enough to produce
+surface streams, will create a series of little channels which grow
+larger as they conjoin, the whole appearing to the eye like a very
+detailed map, or rather model, of a river system; it is, indeed, such
+a system in miniature. If he will watch the process by which these
+streamlet beds are carved, he will obtain a tolerably clear idea as to
+that most important work which the greater streams do in carving the
+face of the lands. The water is no sooner gathered into a sheet than,
+guided by the slightest irregularities which it encounters, it begins
+to flow. At first the motion is so slow that it does not disturb its
+bed, but at some points in the bottom of the sheet the movement soon
+becomes swift enough to drag the grains of sand and clay from their
+adhesions, bearing them onward. As soon as this beginning of a channel
+is formed the water moves more swiftly in the clearer way; it
+therefore cuts more rapidly, deepening and enlarging its channel, and
+making its motion yet more free. The tiny rills join the greater, all
+their channels sway to and fro as directed this way and that by chance
+irregularities, until something like river basins are carved out,
+those gentle slopes which form broad valleys where the carving has
+been due to the wanderings of many streams. If the field be large,
+considerable though temporary brooks may be created, which cut
+channels perhaps a foot in depth. At the end of this miniature stream
+system we always find some part of the waste which has been carved
+out. If the streamlet discharges into a pool, we find the tiny
+representative of deltas, which form such an important feature on the
+coast line where large rivers enter seas or lakes. Along the lines of
+the stream we may observe here and there little benches, which are the
+equivalent in all save size of the terraces that are generally to be
+observed along the greater streams. In fact, these accidents of an
+acre help in a most effective way the student to understand the
+greater and more complicated processes of continental erosion.
+
+A normal river--in fact, all the greater streams of the
+earth--originates in high country, generally in a region of mountains.
+Here, because of the elevation of the region, the streams have cut
+deep gorges or extensive valleys, all of which have slopes leading
+steeply downward to torrent beds. Down these inclined surfaces the
+particles worn off from the hard rock by frost and by chemical decay
+gradually work their way until they attain the bed of the stream. The
+agents which assist gravitation in bearing this detritus downward are
+many, but they all work together for the same end. The stroke of the
+raindrop accomplishes something, though but little; the direct washing
+action of the brooklets which form during times of heavy rain, but dry
+out at the close of the storm, do a good deal of the work; thawing and
+freezing of the water contained in the mass of detritus help the
+movement, for, although the thrust is in both directions, it is most
+effective downhill; the wedges of tree roots, which often penetrate
+between and under the stones, and there expand in their process of
+growth, likewise assist the downward motion. The result is that on
+ordinary mountain slopes the layer of fragments constituting the rude
+soil is often creeping at the rate of from some inches to some feet a
+year toward the torrent bed. If there be cliffs at the top of the
+slope, as is often the case, very extensive falls of rock may take
+place from it, the masses descending with such speed that they
+directly attain the stream. If the steeps be low and the rock divided
+into vertical joints, especially where there is a soft layer at the
+base of the steep, detached masses from the precipice may move slowly
+and steadfastly down the slope, so little disturbed in their journey
+that trees growing upon their summits may continue to develop for the
+thousands of years before the mass enters the stream bed.
+
+Although the fall of rocks from precipices does not often take place
+in a conspicuously large way, all great mountain regions which have
+long been inhabited by man abound in traditions and histories of such
+accidents. Within a century or two there have been a dozen or more
+catastrophes of this nature in the inhabited valleys of the Alps. As
+these accidents are at once instructive and picturesque, it is well to
+note certain of them in some detail. At Yvorgne, a little parish on
+the north shore of the Rhone, just above the lake of Geneva, tradition
+tells that an ancient village of the name was overwhelmed by the fall
+of a great cliff. The vast _debris_ forming the steep slope which was
+thus produced now bears famous vineyards, but the vintners fancy that
+they from time to time hear deep in the earth the ringing of the bells
+which belonged to the overwhelmed church. In 1806 the district of
+Goldau, just north of Lake Lucerne, was buried beneath the ruins of a
+peak which, resting upon a layer of clay, slipped away like a
+launching ship on the surface of the soft material. The _debris_
+overwhelmed a village and many detached houses, and partly filled a
+considerable lake. The wind produced by this vast rush of falling rock
+was so great that people were blown away by it; some, indeed, were
+killed in this singular manner.
+
+The most interesting field of these Swiss mountain falls is a high
+mountain valley of amphitheatrical form, known as the Diablerets, or
+the devil's own district. This great circus, which lies at the height
+of about four thousand feet above the sea, is walled around on its
+northern side by a precipice, above which rest, or rather once
+rested, a number of mountain peaks of great bulk. The region has long
+been valued for the excellent pasturage which the head of the valley
+affords. Two costly roads, indeed, have been built into it to afford
+footpaths for the flocks and herds and their keepers in the summer
+season. Through this human experience with the valley, we have a
+record of what has gone on in this part of the mountain wilderness.
+Within the period of history and tradition, three very great mountain
+falls have occurred in this field, each having made its memory good by
+widespread disaster which it brought to the people of the _chalets_.
+The last of these was brought about by the fall of a great peak which
+spread itself out in a vast field of ruins in the valley below. The
+belt of destruction was about half a mile wide and three miles long.
+When the present writer last saw it, a quarter of a century ago, it
+was still a wilderness of great rocks, but here and there the process
+of their decay was giving a foothold for herbage, and in a few
+centuries the field will doubtless be so verdure-clad that its story
+will not be told on its face. It is likely, however, to be preserved
+in the memory of the people, and this through a singular and pathetic
+tradition which has grown up about the place, one which, if not true,
+comes at least among the legends which we should like to believe.
+
+As told the present writer by a native of the district, it happened
+when, in the nighttime the mountain came down, the herdsmen and their
+cows gathered in the _chalets_--stout buildings which are prepared to
+resist avalanches of snow. In one of these, which was protected from
+crushing by the position of the stones which covered it, a solitary
+herdsman found himself alive in his unharmed dwelling. With him in the
+darkness were the cows, a store of food and water, and his provisions
+for the long summer season. With nothing but hope to animate him, he
+set to work burrowing upward among the rocks, storing the _debris_ in
+the room of the _chalet_. He toiled for some months, but finally
+emerged to the light of day, blanched by his long imprisonment in the
+darkness, but with the strength to bear him to his home. In place of
+the expected warm welcome, the unhappy man found himself received as a
+ghost. He was exorcised by the priest and driven away to the distance.
+It was only when long afterward his path of escape was discovered that
+his history became known.
+
+Returning to the account of the _debris_ which descends at varied
+speed into the torrents, we find that when the detritus encounters the
+action of these vigorous streams it is rapidly ground to pieces while
+it is pushed down the steep channels to the lower country. Where the
+stones are of such size that the stream can urge them on, they move
+rapidly; at least in times when the torrent is raging. They beat over
+each other and against the firm-set rocks; the more they wear, the
+smaller they become, and the more readily they are urged forward.
+Where the masses are too large to be stirred by the violent current,
+they lie unmoved until the pounding of the rolling stones reduces them
+to the proportions where they may join the great procession.
+Ordinarily those who visit mountains behold their torrents only in
+their shrunken state, when the waters stir no stones, and fail even to
+bear a charge of mud, all detachable materials having been swept away
+when the streams course with more vigour. In storm seasons the
+conditions are quite otherwise; then the swollen torrents, their
+waters filled with clay and sand, bear with them great quantities of
+boulders, the collisions of which are audible above the muffled roar
+of the waters, attesting the very great energy of the action.
+
+When the waste on a mountain slope lies at a steep angle, particularly
+where the accumulation is due to the action of ancient glaciers, it
+not infrequently happens that when the ground is softened with frost
+great masses of the material rush down the slope in the manner of
+landslides. The observer readily notes that in many mountain regions,
+as, for instance, in the White Mountains of New Hampshire, the steep
+slopes are often seamed by the paths of these great landslides. Their
+movement, indeed, is often begun by sliding snow, which gives an
+impulse to the rocks and earth which it encounters in its descent. At
+a place known as the Wylie Notch, in the White Mountains, in the early
+part of this century, a family of that name was buried beneath a mass
+of glacial waste which had hung on the mountain slope from the ancient
+days until a heavy rain, following on a period of thaw, impelled the
+mass down the slope. Although there have been few such catastrophes
+noted in this country, it is because our mountains have not been much
+dwelt in. As they become thickly inhabited as the Alps are, men are
+sure to suffer from these accidents.
+
+As the volume of a mountain torrent increases through the junction of
+many tributaries, the energy of its moving waters becomes sufficient
+to sweep away the fragments which come to its bed. Before this stage
+is attained the stream rarely touches the solid under rock of the
+mountain, the base of the current resting upon the larger loose stones
+which it was unable to stir. In this pebble-paved section, because the
+stream could not attack the foundation rock, we find no gorges--in
+fact, the whole of this upper section of the torrent system is
+peculiarly conditioned by the fact that the streams are dealing not
+with bed-rock, but with boulders or smaller loose fragments. If they
+cut a little channel, the materials from either side slip the faster,
+and soon repave the bed. But when the streams have by a junction
+gained strength, and can keep their beds clear, they soon carve down a
+gorge through which they descend from the upper mountain realm to the
+larger valleys, where their conjoined waters take on a riverlike
+aspect. It should be noted here that the cutting power of the water
+moving in the torrent or in the wave, the capacity it has for abrading
+rock, resides altogether in the bits of stone or cutting tools with
+which it is armed. Pure water, because of its fluidity, may move over
+or against firm-set stones for ages without wearing them; but in
+proportion as it moves rocky particles of any size, the larger they
+are, the more effective the work, it wears the rock over which it
+flows. A capital instance of this may be found where a stream from a
+hose is used in washing windows. If the water be pure, there is no
+effect upon the glass; but if it be turbid, containing bits of sand,
+in a little while the surface will appear cloudy from the multitude of
+line scratches which the hard bits impelled by the water have
+inflicted upon it. A somewhat similar case occurs where the wind bears
+sand against window panes or a bottle which has long lain on the
+shore. The glass will soon be deeply carved by the action, assuming
+the appearance which we term "ground." This principle is made use of
+in the arts. Glass vessels or sheets are prepared for carving by
+pasting paper cut into figures on their surfaces. The material is then
+exposed to a jet of air or steam-impelling sand grains; in a short
+time all the surface which has not been protected by paper has its
+polish destroyed and is no longer translucent.
+
+The passage from the torrent to the river, though not in a
+geographical way distinct, is indicated to the observant eye by a
+simple feature--namely, the appearance of alluvial terraces, those
+more or less level heaps of water-borne _debris_ which accumulate
+along the banks of rivers, which, indeed, constitute the difference
+between those streams and torrents. Where the mountain waters move
+swiftly, they manage to bear onward the waste which they receive. Even
+where the blocks of stone cling in the bed, it is only a short time
+before they are again set in motion or ground to pieces. If by chance
+the detritus accumulates rapidly, the slope is steepened and the work
+of the torrent made more efficient. As the torrent comes toward the
+base of the mountains, where it neither finds nor can create steep
+slopes over which to flow, its speed necessarily diminishes. With each
+reduction in this feature its carrying power very rapidly diminishes.
+Thus water flowing at the rate of ten miles an hour can urge stones
+four times the mass that it can move when its speed is reduced to half
+that rate. The result is that on the lowlands, with their relatively
+gentle slopes, the combined torrents, despite the increase in the
+volume of the stream arising from their confluence, have to lay down a
+large part of their load of detritus.
+
+If we watch where a torrent enters a mountain river, we observe that
+the main stream in a way sorts over the waste contributed to it,
+bearing on only those portions which its rate of flow will permit it
+to carry, leaving the remainder to be built into the bank in the form
+of a rude terrace. This accumulation may not extend far below the
+point where the torrent which imported the _debris_ joins the main
+stream; a little farther down, however, we are sure to find another
+such junction and a second accumulation of terrace material. As these
+contributions increase, the terrace accumulations soon become
+continuous, lying on one side or the other of the river, sometimes
+bordering both banks of the stream. In general, it can be said that so
+long as the rate of fall of the torrent exceeds one hundred feet to
+the mile it does not usually exhibit these shelves of detritus. Below
+that rate of descent they are apt to be formed. Much, however, depends
+upon the amount of detritus which the stream bears and the coarseness
+of it; moreover, where the water goes through a gorge in the manner of
+a flume with steep rocky sides, it can urge a larger amount before it
+than when it traverses a wide valley, through which it passes, it may
+be, in a winding way.
+
+At first sight it may seem rather a fine distinction to separate
+torrents from rivers by the presence or absence of terraces. As we
+follow down the stream, however, and study its action in relation to
+these terraces, and the peculiar history of the detritus of which they
+are composed, we perceive that these latter accumulations are very
+important features. Beginning at first with small and imperfect
+alluvial plains, the river, as it descends toward the sea, gaining in
+store of water and in the amount of _debris_ which comes with that
+water from the hills, while the rate of fall and consequent speed of
+the current are diminished, soon comes to a stage where it is engaged
+in an endless struggle with the terrace materials. In times of flood,
+the walls of the terraces compel the tide to flow over the tops of
+these accumulations. Owing to the relative thinness of the water
+beyond the bed, and to the growth of vegetation there, the current
+moves more slowly, and therefore lays down a considerable deposit of
+the silt and sand which it contains. This may result during a single
+flood in lifting the level of the terrace by some inches in height,
+still further serving to restrict the channel. Along the banks of the
+Mississippi and other large rivers the most of this detritus falls
+near the stream; a little of it penetrates to the farther side of the
+plains, which often have a width of ten miles or more. The result is
+that a broad elevation is constructed, a sort of natural mole or
+levee, in a measure damming the flood waters, which can now only enter
+the "back swamps" through the channels of the tributary streams. Each
+of these back swamps normally discharges into the main stream through
+a little river of its own, along the banks of which the natural levees
+do not develop.
+
+We have now to note a curious swinging movement of rivers which was
+first well observed by the skilful engineers of British India. This
+movement can best be illustrated by its effects. If on any river which
+winds through alluvial plains a jetty is so constructed as to deflect
+the stream at any point, the course which it follows will be altered
+during its subsequent flow, it may be, for the distance of hundreds of
+miles. It will be perceived that in its movements a river normally
+strikes first against one shore and then against the other. Its water
+in a general way moves as does a billiard ball when it flies from one
+cushion to another. It is true that in a torrent we have the same
+conditions of motion; but there the banks are either of hard rock or,
+if of detritus, they are continually moving into the stream in the
+manner before described. In the case of the river, however, its points
+of collision are often on soft banks, which are readily undermined by
+the washing action of the stream. In the ordinary course of events,
+the river beginning, we may imagine, with a straight channel, had its
+current deflected by some obstacle, it may be even by the slight
+pressure of a tributary stream, is driven against one bank; thence it
+rebounds and strikes the other. At each point of impinge it cuts the
+alluvium away. It can bear on only a small portion of that which it
+thus obtains; the greater part of the material is deposited on the
+opposite side of the stream, but a little lower down, where it makes a
+shallow. On these shallows water-loving plants and even certain trees,
+such as the willows and poplars, find a foothold. When the stream
+rises, the sediment settles in this tangle, and soon extends the
+alluvial plain from the neighbouring bank, or in rarer cases the river
+comes to flow on either side of an island of its own construction. The
+natural result of this billiard-ball movement of the waters is that
+the path of the stream is sinuous. The less its rate of fall and the
+greater the amount of silt it obtains from its tributaries, the more
+winding its course becomes. This gain in those parts of the river's
+curvings where deposition tends to take place may be accelerated by
+tree-planting. Thus a skilful owner of a tract of land on the south
+bank of the Ohio River, by assiduously planting willow trees on the
+front of his property, gained in the course of thirty years more than
+an acre in the width of his arable land. When told by the present
+writer that he was robbing his neighbours on the other side of the
+stream, he claimed that their ignorance of the laws of river motion
+was sufficient evidence that they did not deserve to own land.
+
+In the primitive state of a country the water-loving plants,
+particularly the trees which flourish in excessively humid conditions,
+generally make a certain defence against these incursions of the
+streams. But when a river has gained an opening in the bank it can,
+during a flood, extend its width often to the distance of hundreds of
+feet. During the inundations of the Mississippi the river may at times
+be seen to eat away acres of land in a single day along one of the
+outcurves of its banks. The undermined forests falling into the flood
+join the great procession of drift timber, composed of trees which
+have been similarly uprooted, which occupies the middle part of the
+stream. This driftwood belt often has a width of three or four hundred
+feet, the entangled stems and branches making it difficult for a boat
+to pass from one side of the river to the other.
+
+[Illustration: Fig. 11.--Oxbows and cut-off. Showing the changes in
+the course of a river in its alluvial plain.]
+
+When the curves of a river have been developed to a certain point (see
+Fig. 11), when they have attained what is called the "oxbow" form, it
+often happens that the stream breaks through the isthmus which
+connects one of the peninsulas with the mainland. Where, as is not
+infrequently the case, the bend has a length of ten miles or more, the
+water just above and below the new-made opening is apt to differ in
+height by some feet. Plunging down the declivity, the stream, flowing
+with great velocity, soon enlarges the channel so that its whole tide
+may take the easier way. When this result is accomplished, the old
+curve is deserted, sand bars are formed across their mouths, which may
+gradually grow to broad alluvial plains, so that the long-surviving,
+crescent-shaped lake, the remnant of the river bed, may be seen far
+from the present course of the ever-changing stream. Gradually the
+accumulations of vegetable matter and the silt brought in by floods
+efface this moat or oxbow cut-off, as it is so commonly termed.
+
+As soon as the river breaks through the neck of a peninsula in the
+manner above described, the current of the stream becomes much swifter
+for many miles below and above the opening. Slowly, however, the
+slopes are rearranged throughout its whole course, yet for a time the
+stream near the seat of the change becomes straighter than before, and
+this for the reason that its swifter current is better able to dispose
+of the _debris_ which is supplied to it. The effect of a change in the
+current produced by such new channels as we have described as forming
+across the isthmuses of bends is to perturb the course of the stream
+in all its subsequent downward length. Thus an oxbow cut-off formed
+near the junction of the Ohio and Mississippi may tend more or less to
+alter the swings of the Mississippi all the way to the Gulf of Mexico.
+
+Although the swayings of the streams to and fro in their alluvial
+plains will give the reader some idea as to the struggle which the
+greater rivers have with the _debris_ which is committed to them, the
+full measure of the work and its consequences can only be appreciated
+by those who have studied the phenomena on the ground. A river such
+as the Mississippi is endlessly endeavouring to bear its burden to the
+sea. If its slope were a uniform inclined plane, the task might
+readily be accomplished; but in this, as in almost all other large
+water ways, the slope of the bed is ever diminishing with its onward
+course. The same water which in the mountain torrent of the
+Appalachians or Cordilleras rolled along stones several feet in
+diameter down slopes of a hundred feet or more to the mile can in the
+lower reaches of the stream move no pebbles which are more than one
+fourth of an inch in diameter over slopes which descend on the average
+about half a foot in a mile. Thus at every stage from the torrent to
+the sea the detritus has from time to time to rest within the alluvial
+banks, there awaiting the decay which slowly comes, and which may
+bring it to the state where it may be dissolved in the water, or
+divided into fragments so small that the stream may bear them on. A
+computation which the present writer has made shows that, on the
+average, it requires about forty thousand years for a particle of
+stone to make its way down the Mississippi to the sea after it has
+been detached from its original bed. Of course, some bits may make the
+journey straightforwardly; others may require a far greater time to
+accomplish the course which the water itself makes at most in a few
+weeks. This long delay in the journey of the detritus--a delay caused
+by its frequent rests in the alluvial plain--brings about important
+consequences which we will now consider.
+
+As an alluvial plain is constructed, we generally find at the base
+pebbly material which fell to the bottom in the current of the main
+stream as the shores grew outward. Above this level we find the
+deposits laid down by the flood waters containing no pebbles, and this
+for the reason that those weightier bits remained in the stream bed
+when the tide flowed over the plain. As the alluvial deposit is laid
+down, a good deal of vegetable matter was built into it. Generally
+this has decayed and disappeared. On the surface of the plain there
+has always been growing abundant vegetation, the remains of which
+decayed on the surface in the manner which we may observe at the
+present day. This decomposing vegetable matter within and upon the
+porous alluvial material produces large quantities of carbonic acid, a
+gas which readily enters the rain water, and gives it a peculiar power
+of breaking up rock matter. Acting on the _debris_, this gas-charged
+water rapidly brings about a decay of the fragments. Much of the
+material passes at once into solution in this water, and drains away
+through the multitudinous springs which border the river. As this
+matter is completely dissolved, as is sugar in water, it goes straight
+away to the sea without ever again entering the alluvium. In many, if
+not most, cases this dissolving work which is going on in alluvial
+terraces is sufficient to render a large part of the materials which
+they contain into the state where it disappears in an unseen manner;
+thus while the annual floods are constantly laying down accumulations
+on the surface of these plains, the springs are bearing it away from
+below.
+
+In this way, through the decomposition which takes place in them, all
+those river terraces where much vegetable matter is mingled with the
+mineral substances, become laboratories in which substances are
+brought into solution and committed to the seas. We find in the water
+of the ocean a great array of dissolved mineral substances; it,
+indeed, seems probable that the sea water contains some share, though
+usually small, of all the materials which rivers encounter in their
+journey over and under the lands. As the waters of the sea obtain but
+little of this dissolved matter along the coast, it seems likely that
+the greater share of it is brought into the state of solution in the
+natural laboratories of the alluvial plains.
+
+Here and there along the sides of the valleys in which the rivers flow
+we commonly find the remains of ancient plains lying at more or less
+considerable heights above the level of the streams. Generally these
+deposits, which from their form are called terraces, represent the
+stages of down-wearing by which the stream has carved out its way
+through the rocks. The greater part of these ancient alluvial plains
+has been removed through the ceaseless swinging of the stream to and
+fro in the valley which it has excavated.
+
+In all the states of alluvial plains, whether they be the fertile
+deposits near the level of the streams which built them, or the poorer
+and ruder surfaced higher terraces, they have a great value to
+mankind. Men early learned that these lands were of singularly uniform
+goodness for agricultural use. They are so light that they were easily
+delved with the ancient pointed sticks or stone hoes, or turned by the
+olden, wooden plough. They not only give a rich return when first
+subjugated, but, owing to the depth of the soil and the frequency with
+which they are visited by fertilizing inundations, they yield rich
+harvests without fertilizing for thousands of years. It is therefore
+not surprising that we find the peoples who depended upon tillage for
+subsistence first developed on the great river plains. There, indeed,
+were laid the foundations of our higher civilization; there alone
+could the state which demands of its citizens fixed abodes and
+continuous labour take rise. In the conditions which these fields of
+abundance afforded, dense populations were possible, and all the arts
+which lead toward culture were greatly favoured. Thus it is that the
+civilization of China, India, Persia, and Egypt, the beginnings of
+man's higher development, began near the mouths of the great river
+valleys. These fields were, moreover, most favourably placed for the
+institution of commerce, in that the arts of navigation, originating
+in the sheltered reaches of the streams, readily found its way through
+the estuaries to the open sea.
+
+Passing down the reaches of a great river as it approaches the sea, we
+find that the alluvial plains usually widen and become lower. At
+length we attain a point where the flood waters cover the surface for
+so large a part of the year that the ground is swampy and untillable
+unless it is artificially and at great expense of labour won to
+agriculture in the manner in which this task has been effected in the
+lower portion of the Rhine Valley. Still farther toward the sea, the
+plain gradually dips downward until it passes below the level of the
+waters. Through this mud-flat section the stream continues to cut
+channels, but with the ever-progressive slowing of its motion the
+burden of fine mud which it carries drops to the bottom, and
+constantly closes the paths through which the water escapes. Every few
+years they tend to break a new way on one side or the other of their
+former path. Some of the greatest engineering work done in modern
+times has been accomplished by the engineers engaged in controlling
+the exits of large rivers to the sea. The outbreak of the Yellow River
+in 1887, in which the stream, hindered by its own accumulations,
+forced a new path across its alluvial plains, destroyed a vast deal of
+life and property, and made the new exit seventy miles from the path
+which it abandoned.
+
+Below the surface of the open water the alluvial deposits spread out
+into a broad fan, which slopes gradually to a point where, in the
+manner of the continental shelf, the bottom descends steeply into deep
+water.
+
+It is the custom of naturalists to divide the lower section of river
+deposits--that part of the accumulation which is near the sea--from
+the other alluvial plains, terming the lower portion the delta. The
+word originally came into use to describe that part of the alluvium
+accumulated by the Nile near its mouth, which forms a fertile
+territory shaped somewhat like the fourth letter of the Greek
+alphabet. Although the definition is good in the Egyptian instance,
+and has a certain use elsewhere, we best regard all the detritus in a
+river valley which is in the state of repose along the stream to its
+utmost branches as forming one great whole. It is, indeed, one of the
+most united of the large features which the earth exhibits. The
+student should consider it as a continuous inclined plane of
+diminishing slope, extending from the base of the torrents to the
+sea, and of course ramifying into the several branches of the river
+system. He should further bear in mind the fact that it is a vast
+laboratory where rock material is brought into the soluble state for
+delivery to the seas.
+
+The diversity in the form of river valleys is exceedingly great.
+Almost all the variety of the landscape is due to this impress of
+water action which has operated on the surface in past ages. When
+first elevated above the sea, the surface of the land is but little
+varied; at this stage in the development the rivers have but shallow
+valleys, which generally cut rather straight away over the plain
+toward the sea. It is when the surface has been uplifted to a
+considerable height, and especially when, as is usually the case, this
+uplifting action has been associated with mountain-building, that
+valleys take on their accented and picturesque form. The reason for
+this is easily perceived: it lies in the fact that the rocks over
+which the stream flows are guided in the cutting which they effect by
+the diversities of hardness in the strata that they encounter. The
+work which it does is performed by the hard substances that are
+impelled by the current, principally by the sand and pebbles. These
+materials, driven along by the stream, become eroding tools of very
+considerable energy. As will be seen when we shortly come to describe
+waterfalls, the potholes formed at those points afford excellent
+evidence as to the capacity of stream-impelled bits of stone to cut
+away the firmest bed rocks. Naturally the ease with which this carving
+work is done is proportionate to the energy of the currents, and also
+to the relative hardness of the moving bits and the rocks over which
+they are driven.
+
+So long as the rocks lie horizontally in their natural construction
+attitude the course of the stream is not much influenced by the
+variations in hardness which the bed exhibits. Where the strata are
+very firm there is likely to be a narrow gorge, the steeps of which
+rise on either side with but slight alluvial plains; where the beds
+are soft the valley widens, perhaps again to contract where in the
+course of its descent it encounters another hard layer. Where,
+however, the beds have been subjected to mountain-building, and have
+been thrown into very varied attitudes by folding and faulting, the
+stream now here and now there encounters beds which either restrain
+its flow or give it freedom. The stream is then forced to cut its way
+according to the positions of the various underlying strata. This
+effect upon its course is not only due to the peculiarities of
+uplifted rocks, but to manifold accidents of other nature: veins and
+dikes, which often interlace the beds with harder or softer partitions
+than the country rock; local hardenings in the materials, due to
+crystallization and other chemical processes, often create
+indescribable variations which are more or less completely expressed
+in the path of the stream.
+
+When a land has been newly elevated above the sea there is often--we
+may say, indeed, generally--a very great difference between the height
+of its head waters and the ocean level. In this condition of a country
+the rivers have what we may call a new aspect; their valleys are
+commonly narrow and rather steep, waterfalls are apt to abound, and
+the alluvial terraces are relatively small in extent. Stage by stage
+the torrents cut deeper; the waste which they make embarrasses the
+course of the lower waters, where no great amount of down-cutting is
+possible for the reason that the bed of the stream is near sea level.
+At the same time the alluvial materials, building out to sea, thus
+diminish the slope of the stream. In the extreme old age of the river
+system the mountains are eaten down so that the torrent section
+disappears, and the stream becomes of something like a uniform slope;
+the higher alluvial plains gradually waste away, until in the end the
+valley has no salient features. At this stage in the process, or even
+before it is attained, the valley is likely to be submerged beneath
+the sea, where it is buried beneath the deposits formed on the floor;
+or a further uplift of the land may occur with the result that the
+stream is rejuvenated; or once more endowed with the power to create
+torrents, build alluvial plains, and do the other interesting work of
+a normal river.
+
+It rarely, if ever, happens that a river valley attains old age before
+it has sunk beneath the sea or been refreshed by further upliftings.
+In the unstable conditions of the continents, one or the other of
+these processes, sometimes in different places both together, is apt
+to be going on. Thus if we take the case of the Mississippi and its
+principal tributaries, the Ohio and Missouri, we find that for many
+geological ages the mountains about their sources have frequently, if
+not constantly, grown upward, so that their torrent sections, though
+they have worn down tens of thousands of feet, are still high above
+the sea level, perhaps on the average as high as they have ever been.
+At the same time the slight up-and-down swayings of the shore lands,
+amounting in general to less than five hundred feet, have greatly
+affected the channels of the main river and its tributaries in their
+lower parts. Not long ago the Mississippi between Cairo and the Gulf
+flowed in a rather steep-sided valley probably some hundreds of feet
+in depth, which had a width of many miles. Then at the close of the
+last Glacial period the region sank down so that the sea flooded the
+valley to a point above the present junction of the Ohio River with
+the main stream. Since then alluvial plains have filled this estuary
+to even beyond the original mouth. In many other of our Southern
+rivers, as along the shore from the Mississippi to the Hudson, the
+streams have not brought in enough detritus to fill their drowned
+valleys, which have now the name of bays, of which the Delaware and
+Chesapeake on the Atlantic coast, and Mobile Bay on the Gulf of
+Mexico, are good examples. The failure of Chesapeake and Delaware Bays
+to fill with _debris_ in the measure exhibited by the more southern
+valleys is due to the fact that the streams which flow into them to a
+great extent drain from a region thickly covered with glacial waste, a
+mass which holds the flood waters, yielding the supply but slowly to
+the torrents, which there have but a slight cutting power.
+
+In our sketch of river valleys no attention has been given to the
+phenomena of waterfalls, those accidents of the flow which, as we have
+noted, are particularly apt to characterize rivers which have not yet
+cut down to near the sea level. Where the normal uniform descent which
+is characteristic of a river's bed is interrupted by a sudden steep,
+the fact always indicates the occurrence of one of a number of
+geological actions. The commonest cause of waterfalls is due to a
+sudden change in the character of horizontal or at least nearly level
+beds over which the stream may flow. Where after coursing for a
+distance over a hard layer the stream comes to its edge and drops on a
+soft or easily eroded stratum, it will cut this latter bed away, and
+create a more or less characteristic waterfall. Tumbling down the face
+of the hard layer, the stream acquires velocity; the _debris_ which it
+conveys is hurled against the bottom, and therefore cuts powerfully,
+while before, being only rubbed over the stone as it moved along, it
+cut but slightly. Masses of ice have the same effect as stones. Bits
+dropping from the ledge are often swept round and round by the eddies,
+so that they excavate an opening which prevents their chance escape.
+In these confined spaces they work like augers, boring a deep,
+well-like cavity. As the bits of stone wear out they are replaced by
+others, which fall in from above. Working in this way, the fragments
+often develop regular well-like depressions, the cavities of which
+work back under the cliffs, and by the undermining process deprive the
+face of the wall of its support, so that it tumbles in ruin to the
+base, there to supply more material for the potholing action.
+
+Waterfalls of the type above described are by far the commonest of
+those which occur out of the torrent districts of a great river
+system. That of Niagara is an excellent specimen of the type, which,
+though rarely manifested in anything like the dignity of the great
+fall, is plentifully shown throughout the Mississippi Valley and the
+basin of the Great Lakes. Within a hundred miles of Niagara there are
+at least a hundred small waterfalls of the same type. Probably three
+quarters of all the larger accidents of this nature are due to the
+conditions of a hard bed overlying softer strata.
+
+Falls are also produced in very many instances by dikes which cross
+the stream. So, too, though rarely, only one striking instance being
+known, an ancient coral reef which has become buried in strata may
+afford rock of such hardness that when the river comes to cross it it
+forms a cascade, as at the Falls of the Ohio, at Louisville, Ky. It is
+a characteristic of all other falls, except those first mentioned,
+that they rarely plunge with a clean downward leap over the face of a
+precipice which recedes at its base, but move downward over an
+irregular sloping surface.
+
+In the torrent district of rivers waterfalls are commonly very
+numerous, and are generally due to the varying hardness in the rocks
+which the streams encounter. Here, where the cutting action is going
+on with great rapidity, slight differences in the resistance which the
+rocks make to the work will lead to great variations in the form of
+the bed over which they flow, while on the more gently sloping bottoms
+of the rivers, where the _debris_ moves slowly, such variations would
+be unimportant in their effect. When the torrents escape into the main
+river valleys, in regions where the great streams have cut deep
+gorges, they often descend from a great vertical height, forming
+wonderful waterfalls, such as those which occur in the famous
+Lauterbrunnen Valley of Switzerland or in that of the Yosemite in
+California. This group of cascades is peculiar in that the steep of
+the fall is made not by the stream itself, but by the action of a
+greater river or of a glacier which may have some time taken its
+place.
+
+Waterfalls have an economic as well as a picturesque interest in that
+they afford sources of power which may be a very great advantage to
+manufacturers. Thus along the Atlantic coast the streams which come
+from the Appalachian highlands, and which have hardly escaped from
+their torrent section before they attain the sea, afford numerous
+cataracts which have been developed so that they afford a vast amount
+of power. Between the James on the south and the Ste. Croix on the
+north more than a hundred of these Appalachian rivers have been turned
+to economic use. The industrial arts of this part of the country
+depend much upon them for the power which drives their machinery. The
+whole of the United States, because of the considerable size of its
+rivers and their relatively rapid fall, is richly endowed with this
+source of energy, which, originating in the sun's heat and conveyed
+through the rain, may be made to serve the needs of man. In view of
+the fact that recent inventions have made it possible to convert this
+energy of falling water into the form of electricity, which may be
+conveyed to great distances, it seems likely that our rivers will in
+the future be a great source of national wealth.
+
+We must turn again to river valleys, there to trace certain actions
+less evident than those already noted, but of great importance in
+determining these features of the land. First, we have to note that in
+the valley or region drained by a river there is another degrading or
+down-wearing action than that which is accomplished by the direct work
+of the visible stream. All over such a valley the underground waters,
+soaking through the soil and penetrating through the underlying rock,
+are constantly removing a portion of the mineral matter which they
+take into solution and bear away to the sea. In this way, deprived of
+a part of their substance, the rocks are continually settling down by
+underwear throughout the whole basin, while they are locally being cut
+down by the action of the stream. Hence in part it comes about that in
+a river basin we find two contrasted features--the general and often
+slight slope of a country toward the main stream and its greater
+tributaries, and the sharp indentation of the gorge in which the
+streams flow, these latter caused by the immediate and recent action
+of the streams.
+
+If now the reader will conceive himself standing at any point in a
+river basin, preferably beyond the realms of the torrents, he may with
+the guidance of the facts previously noted, with a little use of the
+imagination, behold the vast perceptive which the history of the river
+valley may unfold to him. He stands on the surface of the soil, that
+_debris_ of the rocks which is just entering on its way to the ocean.
+In the same region ten thousand years ago he would have stood upon a
+surface from one to ten feet higher than the present soil covering. A
+million years ago his station would have been perhaps five hundred
+feet higher than the surface. Ten million years in the past, a period
+less than the lifetime of certain rivers, such as the French Broad
+River in North Carolina, the soil was probably five thousand feet or
+more above its present plane. There are, indeed, cases where river
+valleys appear to have worked down without interruption from the
+subsidence of the land beneath the sea to the depth of at least two
+miles. Looking upward through the space which the rocks once occupied,
+we can conceive the action of the forces in their harmonious
+co-operation which have brought the surface slowly downward. We can
+imagine the ceaseless corrosion due to the ground water, bringing
+about a constant though slow descent of the whole surface. Again and
+again the streams, swinging to and fro under the guidance of the
+underlying rock, or from the obstacles which the _debris_ they carried
+imposed upon them, have crossed the surface. Now and then perhaps the
+wearing was intensified by glacial action, for an ice sheet often cuts
+with a speed many times as great as that which fluid water can
+accomplish. On the whole, this exercise of the constructive
+imagination in conceiving the history of a river valley is one of the
+most enlarging tasks which the geologist can undertake.
+
+Where in a river valley there are many lateral streams, and especially
+where the process of solution carried on by the underground waters is
+most effective, as compared with erosive work done in the bed of the
+main river, we commonly find the valley sloping gently toward its
+centre, the rivers having but slight steeps near their banks. On the
+other hand, where, as occasionally happens, a considerable stream fed
+by the rain and snow fall in its torrent section courses for a great
+distance over high, arid plains, on which the ground water and the
+tributaries do but little work, the basin may slope with very slight
+declivity to the river margins, and there descend to great depths,
+forming very deep gorges, of which the Colorado Canon is the most
+perfect type. As instances of these contrasted conditions, we may
+take, on the one hand, the upper Mississippi, where the grades toward
+the main stream are gentle and the valley gorge but slightly
+exhibited; on the other, the above-mentioned Colorado, which bears a
+great tide of waters drawn from the high and relatively rainy region
+of the Rocky Mountains across the vast plateau lying in an almost
+rainless country. In this section nearly all the down-wearing has been
+brought about in the direct path of the stream, which has worn the
+elevated plain into a deep gorge during the slow uprising of the
+table-land to its present height. In this way a defile nearly a mile
+in depth has been created in a prevailingly rather flat country. This
+gorge has embranchments where the few great tributaries have done like
+work, but, on the whole, this river flows in an almost unbroken
+channel, the excavation of which has been due to its swift,
+pebble-bearing waters.
+
+The tendency of a newly formed river is to cut a more or less distinct
+canon. As the basin becomes ancient, this element of the gorge tends
+to disappear, the reason for this being that, while the river bed is
+high above the sea, the current is swift and the down-cutting rapid,
+while the slow subsidence of the country on either side--a process
+which goes on at a uniform rate--causes the surface of that region to
+be left behind in the race for the sea level. As the stream bed comes
+nearer the sea level its rate of descent is diminished, and so the
+outlying country gradually overtakes it.
+
+In regions where the winters are very cold the effect of ice on the
+development of the stream beds both in the torrent and river sections
+of the valley is important. This work is accomplished in several
+diverse ways. In the first place, where the stream is clear and the
+current does not flow too swiftly, the stones on the bottom radiate
+their heat through the water, and thus form ice on their surfaces,
+which may attain considerable thickness. As ice is considerably
+lighter than water, the effect is often to lift up the stones of the
+bed if they be not too large; when thus detached from the bottom, they
+are easily floated down stream until the ice melts away. The ice which
+forms on the surface of the water likewise imprisons the pebbles along
+the banks, and during the subsequent thaw may carry them hundreds of
+miles toward the sea. It seems likely, from certain observations made
+by the writer, that considerable stones may thus be carried from the
+Alleghany River to the main Mississippi.
+
+Perhaps the most important effect of ice on river channels is
+accomplished when in a time of flood the ice field which covered the
+stream, perhaps to the depth of some feet, is broken up into vast
+floes, which drift downward with the current. When, as on the Ohio,
+these fields sometimes have the area of several hundred acres, they
+often collide with the shores, especially where the stream makes a
+sharp bend. Urged by their momentum, these ice floes pack into the
+semblance of a dam, which may have a thickness of twenty, thirty, or
+even fifty feet. Beginning on the shore, where the collision takes
+place, the dam may swiftly develop clear across the stream, so that in
+a few minutes the way of the waters is completely blocked. The
+on-coming ice shoots up upon the accumulation, increases its height,
+and extends it up stream, so that in an hour the mass completely bars
+the current. The waters then heap up until they break their way over
+the obstacle, washing its top away, until the whole is light enough
+to be forced down the stream, where, by the friction it encounters on
+the bottom and sides of the channel, it is broken to pieces. It is
+easy to see that such moving dams of ice may sweep the bed of a river
+as with a great broom.
+
+Sometimes where the gorges do not form a stationary dam large cakes of
+ice become turned on edge and pack together so that they roll down the
+stream like great wheels, grinding the bed rock as they go.
+
+In high northern countries, as in Siberia, the rivers, even the
+deepest, often become so far frozen that their channels are entirely
+obstructed. Where, as in the case of these Siberian rivers, the flow
+is from south to north, it often happens that the spring thaw sets in
+before the more northern beds of the main stream are released from
+their bondage of frost. In this case the inundations have to find new
+paths on either side of the obstructed way. The result is a type of
+valleys characterized by very irregular and changeable stream beds,
+the rivers having no chance to organize themselves into the shapely
+curves which they ordinarily follow.
+
+The supply which finds its way to a river is composed, as has been
+already incidentally noted, in part of the water which courses
+underground for a greater or less distance before it emerges to the
+surface, and in part of that which moves directly over the ground.
+These two shares of water have somewhat different histories. On the
+share of these two depends the stability of the flow. Where, as in New
+England and other glaciated countries, the surface of the earth is
+covered with a thick layer of sand and gravel, which, except when
+frozen, readily admits the water; the rainfall is to a very great
+extent absorbed by the earth, and only yielded slowly to the streams.
+In these cases floods are rare and of no great destructive power.
+Again, where also the river basin is covered by a dense mantle of
+forests, the ground beneath which is coated, as is the case in
+primeval woods, with a layer of decomposing vegetation a foot or more
+in depth, this spongy mass retains the water even more effectively
+than the open-textured glacial deposits above referred to. When the
+woods, however, are removed from such an area, the rain may descend to
+the streams almost as speedily as it finds its way to the gutters from
+the house roofs. It thus comes about that all regions, when reduced to
+tillage, and where the rainfall is enough to maintain a good
+agriculture, are, except when they have a coating of glacial waste,
+exceedingly liable to destructive inundations.
+
+Unhappily, the risk of river floods is peculiarly great in all the
+regions of the United States lying much to the east of the Rocky
+Mountains, except in the basin of the Great Lakes and in the district
+of New England, where the prevalence of glacial sands and gravels
+affords the protection which we have noted. Throughout this region the
+rainfall is heavy, and the larger part of it is apt to come after the
+ground has become deeply snow-covered. The result is a succession of
+devastating floods which already are very damaging to the works of
+man, and promise to become more destructive as time goes on. More than
+in any other country, we need the protection which forests can give us
+against these disastrous outgoings of our streams.
+
+
+                            LAKES.
+
+In considering the journey of water from the hilltops to the sea, we
+should take some account of those pauses which it makes on its way
+when for a time it falls into the basin of a lake. These arrests in
+the downward motion of water, which we term lakes, are exceedingly
+numerous; their proper discussion would, indeed, require a
+considerable volume. We shall here note only the more important of
+their features, those which are of interest to the general student.
+
+The first and most noteworthy difference in lakes is that which
+separates the group of dead seas from the living basins of fresh
+water. When a stream attains a place where its waters have to expand
+into the lakelike form, the current moves in a slow manner, and the
+broad surface exposed to the air permits a large amount of
+evaporation. If the basin be large in proportion to the amount of the
+incurrent water, this evaporation may exceed the supply, and produce a
+sea with no outlet, such as we find in the Dead Sea of Judea, in that
+at Salt Lake, Utah, and in a host of other less important basins. If
+the rate of evaporation be yet greater in proportion to the flow, the
+lake may altogether dry away, and the river be evaporated before it
+attains the basin where it might accumulate. In that case the river is
+said to sink, but, in place of sinking into the earth, its waters
+really rise into the air. Many such sinks occur in the central portion
+of the Rocky Mountain district. It is important to note that the
+process of evaporation we are describing takes place in the case of
+all lakes, though only here and there is the air so dry that the
+evaporation prevents the basin from overflowing at the lowest point on
+its rim, forming a river which goes thence to the sea. Even in the
+case of the Great Lakes of North America a considerable part of the
+water which flows into them does not go to the St. Lawrence and thence
+to the sea. As long as the lake finds an outlet to the sea its waters
+contain but little more dissolved mineral matter than that we find in
+the rivers. But because all water which has been in contact with the
+earth has some dissolved mineral substances, while that which goes
+away by evaporation is pure water, a lake without an outlet gradually
+becomes so charged with these materials that it can hold no more in
+solution, but proceeds to lay them down in deposits of that compound
+substance which from its principal ingredient we name salt. The water
+of dead seas, because of the additional weight of the substances which
+it holds, is extraordinarily buoyant. The swimmer notes a difference
+in this regard in the waters of rivers and fresh-water lakes and those
+of the sea, due to this same cause. But in those of dead seas,
+saturated with saline materials, the human body can not sink as it
+does in the ordinary conditions of immersion. It is easy to understand
+how the salt deposits which are mined in many parts of the world have
+generally, if not in all cases, been formed in such dead seas.[5]
+
+[Footnote 5: In some relatively rare cases salt deposits are formed in
+lagoons along the shores of arid lands, where the sea occasionally
+breaks over the beach into the basin, affording waters which are
+evaporated, leaving their salt behind them.]
+
+It is an interesting fact that almost all the known dead seas have in
+recent geological times been living lakes--that is, they poured over
+their brims. In the Cordilleras from the line between Canada and the
+United States to central Mexico there are several of these basins. All
+of those which have been studied show by their old shore lines that
+they were once brimful, and have only shrunk away in modern times.
+These conditions point to the conclusion that the rainfall in
+different regions varies greatly in the course of the geologic ages.
+Further confirmation of this is found in the fact that very great salt
+deposits exist on the coast of Louisiana and in northern
+Europe--regions in which the rainfall is now so great in proportion to
+the evaporation that dead seas are impossible.
+
+Turning now to the question of how lake basins are formed, we note a
+great variety in the conditions which may bring about their
+construction. The greatest agent, or at least that which operates in
+the construction of the largest basins, are the irregular movements of
+the earth, due to the mountain-building forces. Where this work goes
+on on a large scale, basin-shaped depressions are inevitably formed.
+If all those which have existed remained, the large part of the lands
+would be covered by them. In most cases, however, the cutting action
+of the streams has been sufficient to bring the drainage channels down
+to the bottom of the trough, while the influx of sediments has served
+to further the work by filling up the cavities. Thus at the close of
+the Cretaceous period there was a chain of lakes extending along the
+eastern base of the Rocky Mountains, constituting fresh-water seas
+probably as large as the so-called Great Lakes of North America. But
+the rivers, by cutting down and tilling up, have long since
+obliterated these water areas. In other cases the tiltings of the
+continent, which sometimes oppose the flow of the streams, may for a
+time convert the upper part of a river basin which originally sloped
+gently toward the sea into a cavity. Several cases of this description
+occurred in New England in the closing stages of the Glacial period,
+when the ground rose up to the northward.
+
+We have already noted the fact that the basin of a dead sea becomes in
+course of time the seat of extensive salt deposits. These may, indeed,
+attain a thickness of many hundred feet. If now in the later history
+of the country the tract of land with the salt beneath it were
+traversed by a stream, its underground waters may dissolve out the
+salt and in a way restore the basin to its original unfilled
+condition, though in the second state that of a living lake. It seems
+very probable that a portion at least of the areas of Lakes Ontario,
+Erie, and Huron may be due to this removal of ancient salt deposits,
+remains of which lie buried in the earth in the region bordering these
+basins.
+
+By far the commonest cause of lake basins is found in the
+irregularities of the surface which are produced by the occupation of
+the country by glaciers. When these great sheets of ice lie over a
+land, they are in motion down the slopes on which they rest; they wear
+the bed rocks in a vigorous manner, cutting them down in proportion to
+their hardness. As these rocks generally vary in the resistance which
+they oppose to the ice, the result is that when the glacier passes
+away the surface no longer exhibits the continued down slope which the
+rivers develop, but is warped in a very complicated way. These
+depressions afford natural basins in which lakes gather; they may vary
+in extent from a few square feet to many square miles. When a glacier
+occupies a country, the melting ice deposits on the surface of the
+earth a vast quantity of rocky _debris_, which was contained in its
+mass. This detritus is irregularly accumulated; in part it is disposed
+in the form of moraines or rude mounds made at the margin of the
+glacier, in part as an irregular sheet, now thick, now thin, which
+covers the whole of the field over which the ice lay. The result of
+this action is the formation of innumerable pools, which continue to
+exist until the streams have cut channels through which their waters
+may drain away, or the basins have become filled with detritus
+imported from the surrounding country or by peat accumulations which
+the plants form in such places.
+
+Doubtless more than nine tenths of all the lake basins, especially
+those of small size, which exist in the world are due to
+irregularities of the land surface which are brought about by glacial
+action. Although the greater part of these small basins have been
+obliterated since the ice left this country, the number still
+remaining of sufficient size to be marked on a good map is
+inconceivably great. In North America alone there are probably over a
+hundred and fifty thousand of these glacial lakes, although by far the
+greater part of those which existed when the glacial sheet disappeared
+have been obliterated.
+
+Yet another interesting group of fresh-water lakes, or rather we
+should call them lakelets from their small size, owes its origin to
+the curious underground excavations or caverns which are formed in
+limestone countries. The water enters these caverns through what are
+termed "sink holes"--basins in the surface which slope gently toward a
+central opening through which the water flows into the depths below.
+The cups of the sink holes rarely exceed half a mile in diameter, and
+are usually much smaller. Their basins have been excavated by the
+solvent and cutting actions of the rain water which gathers in them to
+be discharged into the cavern below. It often happens that after a
+sink hole is formed some slight accident closes the downward-leading
+shaft, so that the basin holds water; thus in parts of the United
+States there are thousands of these nearly circular pools, which in
+certain districts, as in southern Kentucky, serve to vary the
+landscape in much the same manner as the glacial lakes of more
+northern countries.
+
+Some of the most beautiful lakes in the world, though none more than a
+few miles in diameter, occupy the craters of extinct volcanoes. When
+for a time, or permanently, a volcano ceases to do its appointed work
+of pouring forth steam and molten rock from the depths of the earth,
+the pit in the centre of the cone gathers the rain water, forming a
+deep circular lake, which is walled round by the precipitous faces of
+the crater. If the volcano reawakens, the water which blocks its
+passage may be blown out in a moment, the discharge spreading in some
+cases to a great distance from the cone, to be accumulated again when
+the vent ceases to be open. The most beautiful of these volcanic lakes
+are to be found in the region to the north and south of Rome. The
+original seat of the Latin state was on the shores of one of these
+crater pools, south of the Eternal City. Lago Bolsena, which lies to
+the northward, and is one of the largest known basins of this nature,
+having a diameter of about eight miles, is a crater lake. The volcanic
+cone to which it belongs, though low, is of great size, showing that
+in its time of activity, which did not endure very long, this crater
+was the seat of mighty ejections. The noblest specimen of this group
+of basins is found in Crater Lake, Oregon, now contained in one of the
+national parks of the United States.
+
+Inclosed bodies of water are formed in other ways than those
+described; the list above given includes all the important classes of
+action which produce these interesting features. We should now note
+the fact that, unlike the seas, the lakes are to be regarded as
+temporary features in the physiography of the land. One and all, they
+endure for but brief geologic time, for the reason that the streams
+work to destroy them by filling them with sediment and by carving out
+channels through which their waters drain away. The nature of this
+action can well be conceived by considering what will take place in
+the course of time in the Great Lakes of North America. As Niagara
+Falls cut back at the average rate of several feet a year, it will be
+but a brief geologic period before they begin to lower the waters of
+Lake Erie. It is very probable, indeed, that in twenty thousand years
+the waters of that basin will be to a great extent drained away. When
+this occurs, another fall or rapid will be produced in the channel
+which leads from Lake Huron to Lake Erie. This in turn will go through
+its process of retreat until the former expanse of waters disappears.
+The action will then be continued at the outlets of Lakes Michigan and
+Superior, and in time, but for the interposition of some actions which
+recreate these basins, their floors will be converted into dry land.
+
+It is interesting to note that lakes owe in a manner the preservation
+of their basins to an action which they bring about on the waters that
+flow into them. These rivers or torrents commonly convey great
+quantities of sediment, which serve to rasp their beds and thus to
+lower their channels. In all but the smaller lakelets these turbid
+waters lay down all their sediment before they attain the outlet of
+the basin. Thus they flow away over the rim rock in a perfectly pure
+state--a state in which, as we have noted before, water has no
+capacity for abrading firm rock. Thus where the Niagara River passes
+from Lake Erie its clean water hardly affects the stone over which it
+flows. It only begins to do cutting work where it plunges down the
+precipice of the Falls and sets in motion the fragments which are
+constantly falling from that rocky face. These Falls could not have
+begun as they did on the margin of Lake Ontario except for the fact
+that when the Niagara River began to flow, as in relatively modern
+times, it found an old precipice on the margin of Lake Ontario, formed
+by the waves of the lake, down which the waters fell, and where they
+obtained cutting tools with which to undermine the steep which forms
+the Falls.
+
+Many great lakes, particularly those which we have just been
+considering, have repeatedly changed their outlets, according as the
+surface of the land on which they lie has swayed up and down in
+various directions, or as glacial sheets have barred or unbarred the
+original outlets of the basins. Thus in the Laurentian Lakes above
+Ontario the geologist finds evidence that the drainage lines have
+again and again been changed. For a time during the Glacial period,
+when Lake Ontario and the valley of the St. Lawrence was possessed by
+the ice, the discharge was southward into the upper Mississippi or the
+Ohio. At a later stage channels were formed leading from Georgian Bay
+to the eastern part of Ontario. Yet later, when the last-named lake
+was bared, an ice dam appears to have remained in the St. Lawrence,
+which held back the waters to such a height that they discharged
+through the valley of the Mohawk into the Hudson. Furthermore, at some
+time before the Glacial period, we do not know just when, there
+appears to have been an old Niagara River, now filled with drift,
+which ran from Lake Erie to Ontario, a different channel from that
+occupied by the present stream.
+
+The effects of lakes on the river systems with which they are
+connected is in many ways most important. Where they are of
+considerable extent, or where even small they are very numerous, they
+serve to retain the flood waters, delivering them slowly to the
+excurrent streams. In rising one foot a lake may store away more water
+than the river by its consequent rise at the point of outflow will
+carry away in many months, and this for the simple reason that the
+lake may be many hundred or even thousand times as wide as the stream.
+Moreover, as before noted, the sediment gathered by the stream above
+the level of the lake is deposited in its basin, and does not affect
+the lower reaches of the river. The result is that great rivers, such
+as drain from the Laurentian Lakes, flow clear water, are exempt from
+floods, are essentially without alluvial plains or terraces, and form
+no delta deposits. In all these features the St. Lawrence River
+affords a wonderful contrast to the Mississippi. Moreover, owing to
+the clear waters, though it has flowed for a long time, it has never
+been able to cut away the slight obstructions which form its rapids,
+barriers which probably would have been removed if its waters had been
+charged with sediment.
+
+[Illustration: _Muir Glacier, Alaska, showing crevasses and dust
+layer on surface of ice._]
+
+
+
+
+                         CHAPTER VI.
+
+                          GLACIERS.
+
+
+We have already noted the fact that the water in the clouds is very
+commonly in the frozen state; a large part of that fluid which is
+evaporated from the sea attains the solid form before it returns to
+the earth. Nevertheless, in descending, at least nine tenths of the
+precipitation returns to the fluid state, and does the kind of work
+which we have noted in our account of water. Where, however, the water
+arrives on the earth in the frozen condition, it enters on a role
+totally different from that followed by the fluid material.
+
+Beginning its descent to the earth in a snowflake, the little mass
+falls slowly, so that when it comes against the earth the blow which
+it strikes is so slight that it does no effective work. In the state
+of snow, even in the separate flakes, the frozen water contains a
+relatively large amount of air. It is this air indeed, which, by
+dividing the ice into many flakes that reflect the light, gives it the
+white colour. This important point can be demonstrated by breaking
+transparent ice into small bits, when we perceive that it has the hue
+of snow. Much the same effect is given where glass is powdered, and
+for the same reason.
+
+As the snowflakes accumulate layer on layer they imbed air between
+them, so that when the material falls in a feathery shape--say to the
+depth of a foot--more than nine tenths of the mass is taken up by the
+air-containing spaces. As these cells are very small, the circulation
+in them is slight, and so the layer becomes an admirable
+non-conductor, having this quality for the same reason that feathers
+have it--i.e., because the cells are small enough to prevent the
+circulation of the air, so that the heat which passes has to go by
+conduction, and all gases are very poor conductors. The result is that
+a snow coating is in effect an admirable blanket. When the sun shines
+upon it, much of the heat is reflected, and as the temperature does
+not penetrate it to any depth, only the superficial part is melted.
+This molten water takes up in the process of melting a great deal of
+heat, so that when it trickles down into the mass it readily
+refreezes. On the other hand, the heat going out from the earth, the
+store accumulated in its superficial parts in the last warm season,
+together with the small share which flows out from the earth's
+interior, is held in by this blanket, which it melts but slowly. Thus
+it comes about that in regions of long-enduring snowfall the ground,
+though frozen to the depth of a foot or more at the time when the
+accumulation took place, may be thawed out and so far warmed that the
+vegetation begins to grow before the protecting envelope of snow has
+melted away. Certain of the early flowers of high latitudes, indeed,
+begin to blossom beneath the mantle of finely divided ice.
+
+In those parts of the earth which for the most part receive only a
+temporary coating of snow the effect of this covering is
+inconsiderable. The snow water is yielded to the earth, from which it
+has helped to withdraw the frost, so that in the springtime, the
+growing season of plants, the ground contains an ample store of
+moisture for their development. Where the snowfall accumulates to a
+great thickness, especially where it lodges in forests, the influence
+of the icy covering is somewhat to protract the winter and thus to
+abbreviate the growing season.
+
+Where snow rests upon a steep slope, and gathers to the depth of
+several feet, it begins to creep slowly down the declivity in a manner
+which we may often note on house roofs. This motion is favoured by the
+gradual though incomplete melting of the flakes as the heat
+penetrates the mass. Making a section through a mass of snow which has
+accumulated in many successive falls, we note that the top may still
+have the flaky character, but that as we go down the flakes are
+replaced by adherent shotlike bodies, which have arisen from the
+partial melting and gathering to their centres of the original
+expanded crystalline bits. In this process of change the mass can move
+particle by particle in the direction in which gravity impels it. The
+energy of its motion, however, is slight, yet it can urge loose stones
+and forest waste down hill. Sometimes, as in the cemetery at Augusta,
+Me., where stone monuments or other structures, such as iron railings,
+are entangled in the moving mass, it may break them off and convey
+them a little distance down the slope.
+
+So long as the summer sun melts the winter's snow, even if the ground
+be bare but for a day, the role of action accomplished by the snowfall
+is of little geological consequence. When it happens that a portion of
+the deposit holds through the summer, the region enters on the glacial
+state, and its conditions undergo a great revolution, the consequences
+of which are so momentous that we shall have to trace them in some
+detail. Fortunately, the considerations which are necessary are not
+recondite, and all the facts are of an extremely picturesque nature.
+
+Taking such a region as New England, where all the earth is
+life-bearing in the summer season, and where the glacial period of the
+winter continues but for a short time, we find that here and there on
+the high mountains the snow endures throughout most of the summer, but
+that all parts of the surface have a season when life springs into
+activity. On the top of Mount Washington, in the White Mountains of
+New Hampshire, in a cleft known as Tuckerman's Ravine, where the
+deposit accumulates to a great depth, the snow-ice remains until
+midsummer. It is, indeed, evident that a very slight change in the
+climatal conditions of this locality would establish a permanent
+accumulation of frozen water upon the summit of the mountain. If the
+crest were lifted a thousand feet higher, without any general change
+in the heat or rainfall of the district, this effect would be
+produced. If with the same amount of rainfall as now comes to the
+earth in that region more of it fell as snow, a like condition would
+be established. Furthermore, with an increase of rainfall to something
+like double that which now descends the snow bore the same proportion
+to the precipitation which it does at present, we should almost
+certainly have the peak above the permanent snow line, that level
+below which all the winter's fall melts away. These propositions are
+stated with some care, for the reason that the student should perceive
+how delicate may be--indeed, commonly is--the balance of forces which
+make the difference between a seasonal and a perennial snow covering.
+
+As soon as the snow outlasts the summer, the region which it occupies
+is sterilized to life. From the time the snow begins to hold over the
+warm period until it finally disappears, that field has to be reckoned
+out of the habitable earth, not only to man, but to the lowliest
+organisms.[6]
+
+[Footnote 6: In certain fields of permanent snow, particularly near their
+boundaries, some very lowly forms of vegetable life may develop on a
+frozen surface, drawing their sustenance from the air, and supplied with
+water by the melting which takes place during the summertime. These
+forms include the rare phenomenon termed red snow.]
+
+If the snow in a glaciated region lay where it fell, the result would
+be a constant elevation of the deposit year by year in proportion to
+the annual excess of deposition over the melting or evaporation of the
+material. But no sooner does the deposit attain any considerable
+thickness than it begins to move in the directions of least
+resistance, in accordance with laws which the students of glaciers are
+just beginning to discern. In small part this motion is accomplished
+by avalanches or snow slides, phenomena which are in a way important,
+and therefore merit description. Immediately after a heavy snowfall,
+in regions where the slopes are steep, it often happens that the
+deposit which at first clung to the surface on which it lay becomes so
+heavy that it tends to slide down the slope; a trifling action, the
+slipping, indeed, of a single flake, may begin the movement, which at
+first is gradual and only involves a little of the snow. Gathering
+velocity, and with the materials heaped together from the junction of
+that already in motion with that about to be moved, the avalanche in
+sliding a few hundred feet down the slope may become a deep stream of
+snow-ice, moving with great celerity. At this stage it begins to break
+off masses of ice from the glaciers over which it may flow, or even to
+move large stones. Armed with these, it rends the underlying earth.
+After it has flowed a mile it may have taken up so much earth and
+material that it appears like a river of mud. Owing to the fact that
+the energy which bears it downward is through friction converted into
+heat, a partial melting of the mass may take place, which converts it
+into what we call slush, or a mixture of snow and water. Finally, the
+torrent is precipitated into the bottom of a valley, where in time the
+frozen water melts away, leaving only the stony matter which it bore
+as a monument to show the termination of its flow.
+
+It was the good fortune of the writer to see in the Swiss Oberland one
+very great avalanche, which came from the high country through a
+descent of several thousand feet to the surface of the Upper
+Grindelwald Glacier. The first sign of the action was a vague tremor
+of the air, like that of a great organ pipe when it begins to vibrate,
+but before the pulsations come swiftly enough to make an audible note.
+It was impossible to tell when this tremor came, but the wary guide,
+noting it before his charge could perceive anything unusual, made
+haste for the middle of the glacier. The vibration swelled to a roar,
+but the seat of the sound amid the echoing cliffs was indeterminable.
+Finally, from a valley high up on the southern face of the glacier,
+there leaped forth first a great stone, which sprang with successive
+rebounds to the floor of ice. Then in succession other stones and
+masses of ice which had outrun the flood came thicker and thicker,
+until at the end of about thirty seconds the steep front of the
+avalanche appeared like a swift-moving wall. Attaining the cliffs, it
+shot forth as a great cataract, which during the continuance of the
+flow--which lasted for several minutes--heaped a great mound of
+commingled stones and ice upon the surface of the glacier. The mass
+thus brought down the steep was estimated at about three thousand
+cubic yards, of which probably the fiftieth part was rock material. An
+avalanche of this volume is unusual, and the proportion of stony
+matter borne down exceptionally great; but by these sudden motions of
+the frozen water a large part of the snow deposited above the zone of
+complete melting is taken to the lower valleys, where it may disappear
+in the summer season, and much of the erosion accomplished in the
+mountains is brought about by these falls.
+
+In all Alpine regions avalanches are among the most dreaded accidents.
+Their occurrence, however, being dependent upon the shape of the
+surface, it is generally possible to determine in an accurate way the
+liability of their happening in any particular field. The Swiss take
+precaution to protect themselves from their ravages as other folk do
+to procure immunity from floods. Thus the authorities of many of the
+mountain hamlets maintain extensive forests on the sides of the
+villages whence the downfall may be expected, experience having shown
+that there is no other means so well calculated to break the blow
+which these great snowfalls can deliver, as thick-set trees which,
+though they are broken down for some distance, gradually arrest the
+stream.
+
+As long as the region occupied by permanent snow is limited to sharp
+mountain peaks, relief by the precipitation of large masses to the
+level below the snow line is easily accomplished, but manifestly this
+kind of a discharge can only be effective from a very small field.
+Where the relief is not brought about by these tumbles of snow,
+another mode of gravitative action accomplishes the result, though in
+a more roundabout way, through the mechanism of glaciers.
+
+We have already noted the fact that the winter's snow upon our
+hillsides undergoes a movement in the direction of the slope. What we
+have now to describe in a rather long story concerning glaciers rests
+upon movements of the same nature, though they are in certain features
+peculiarly dependent on the continuity of the action from year to
+year. It is desirable, however, that the student should see that there
+is at the foundation no more mystery in glacial motion than there is
+in the gradual descent of the snow after it has lain a week on a
+hillside. It is only in the scale and continuity of the action that
+the greatest glacial envelope exceeds those of our temporary
+winters--in fact, whenever the snow falls the earth it covers enters
+upon an ice period which differs only in degree from that from which
+our hemisphere is just escaping.
+
+Where the reader is so fortunate as to be able to visit a region of
+glaciers, he had best begin his study of their majestic phenomena by
+ascending to those upper realms where the snow accumulates from year
+to year. He will there find the natural irregularities of the rock
+surface in a measure evened over by a vast sheet of snow, from which
+only the summits of the greater mountains rise. He may soon satisfy
+himself that this sheet is of great depth, for here and there it is
+intersected by profound crevices. If the visit is made in the season
+when snow falls, which is commonly during most of the year, he may
+observe, as before noted in our winter's snow, that the deposit,
+though at first flaky, attains at a short distance below the surface a
+somewhat granular character, though the shotlike grains fall apart
+when disturbed. Yet deeper, ordinarily a few feet below the surface,
+these granules are more or less cemented together; the mass thus loses
+the quality of snow, and begins to appear like a whitish ice. Looking
+down one of the crevices, where the light penetrates to the depth of a
+hundred feet or more, he may see that the bluish hue somewhat
+increases with the depth. A trace of this colour is often visible even
+in the surface snow on the glacier, and sometimes also in our ordinary
+winter fields. In a hole made with a stick a foot or more in depth a
+faint cerulean glimmer may generally be discerned; but the increased
+blueness of the ice as we go down is conspicuous, and readily leads us
+to the conclusion that the air, to which, as we before noted, the
+whiteness of the snow is due, is working out of the mass as the
+process of compaction goes on. In a glacial district this snow mass
+above the melting line is called the _neve_.
+
+Remembering that the excess of snow beyond the melting in a _neve_
+district amounts, it may be, to some feet of material each year, we
+easily come to the conclusion that the mass works down the slope in
+the manner which it does even where the coating is impermanent. This
+supposition is easily confirmed: by observing the field we find that
+the sheet is everywhere drawing away from the cliffs, leaving a deep
+fissure between the _neve_ and the precipices. This crevice is called
+by the German-Swiss guides the _Bergschrund_. Passage over it is
+often one of the most difficult feats to accomplish which the Alpine
+explorer has to undertake. In fact, the very appearance of the
+surface, which is that of a river with continuous down slopes, is
+sufficient evidence that the mass is slowly flowing toward the
+valleys. Following it down, we almost always come to a place where it
+passes from the upper valleys to the deeper gorges which pierce the
+skirts of the mountain. In going over this projection the mass of
+snow-ice breaks to pieces, forming a crowd of blocks which march down
+the slope with much more speed than they journeyed when united in the
+higher-lying fields. In this condition and in this part of the
+movement the snow-ice forms what are called the _seracs_, or curds, as
+the word means in the French-Swiss dialect. Slipping and tumbling
+down the steep slope on which the _seracs_ develop, the ice becomes
+broken into bits, often of small size. These fragments are quickly
+reknit into the body of ice, which we shall hereafter term the
+glacier, and in this process the expulsion of the air goes on more
+rapidly than before, and the mass assumes a more transparent icelike
+quality.
+
+The action of the ice in the pressures and strains to which it is
+subjected in joining the main glacier and in the further part of its
+course demand for their understanding a revision of those notions as
+to rigidity and plasticity which we derive from our common experience
+with objects. It is hard to believe that ice can be moulded by
+pressure into any shape without fracturing, provided the motion is
+slowly effected, while at the same time it is as brittle as ice to a
+sudden blow. We see, however, a similar instance of contrasted
+properties in the confection known as molasses candy, a stick of which
+may be indefinitely bent if the flexure is slowly made, but will fly
+to pieces like glass if sharply struck. Ice differs from the sugary
+substance in many ways; especially we should note that while it may be
+squeezed into any form, it can not be drawn out, but fractures on the
+application of a very slight tension. The conditions of its movement
+we will inquire into further on, when we have seen more of its action.
+
+Entering on the lower part of its course, that where it flows into the
+region below the snow line, the ice stream is now confined between the
+walls of the valley, a channel which in most cases has been shaped
+before the ice time, by a mountain torrent, or perhaps by a slower
+flowing river. In this part of its course the likeness of a glacial
+stream to one of fluid water is manifest. We see that it twists with
+the turn of the gorge, widens where the confining walls are far apart,
+and narrows where the space is constricted. Although the surface is
+here and there broken by fractures, it is evident that the movement of
+the frozen current, though slow, is tolerably free. By placing stakes
+in a row across the axis of a glacier, and observing their movement
+from day to day, or even from hour to hour if a good theodolite is
+used for the purpose, we note that the movement of the stream is
+fastest in the middle parts, as in the case of a river, and that it
+slows toward either shore, though it often happens, as in a stream of
+molten water, that the speediest part of the current is near one side.
+Further observations have indicated that the movement is most rapid on
+the surface and least at the bottom, in which the stream is also
+riverlike. It is evident, in a word, that though the ice is not fluid
+in strict sense, the bits of which it is made up move in substantially
+the manner of fluids--that is, they freely slip over each other. We
+will now turn our attention to some important features of a detailed
+sort which glaciers exhibit.
+
+If we visit a glacier during the part of the year when the winter
+snows are upon it, it may appear to have a very uninterrupted surface.
+But as the summer heat advances, the mask of the winter coating goes
+away, and we may then see the structure of the ice. First of all we
+note in all valley glaciers such as we are observing that the stream
+is overlaid by a quantity of rocky waste, the greater part of which
+has come down with the avalanches in the manner before described,
+though a small part may have been worn from the bed over which the ice
+flows. In many glaciers, particularly as we approach their
+termination, this sheet of earth and rock materials often covers the
+ice so completely that the novice in such regions finds it difficult
+to believe that the ice is under his feet. If the explorer is minded
+to take the rough scramble, he can often walk for miles on these
+masses of stone without seeing, much less setting foot on any frozen
+water. In some of the Alaskan glaciers this coating may bear a forest
+growth. In general, this material, which is called moraine, is
+distributed in bands parallel to the sides of the glaciers, and the
+strips may amount to a half dozen or more. Those on the sides of the
+ice have evidently been derived from the precipices which they have
+passed. Those in the middle have arisen from the union of the moraines
+formed in two or more tributary valleys.
+
+[Illustration: Fig. 12.--Map of glaciers and moraines near Mont Blanc.]
+
+Where the avalanches fall most plentifully, the stones lie buried with
+the snow, and only melt out when the stream attains the region where
+the annual waste of its surface exceeds the snowfall. In this section
+we can see how the progressive melting gradually brings the rocky
+_debris_ into plain view. Here and there we will find a boulder
+perched on a pedestal of ice, which indicates a recent down-wearing of
+the field. A frequent sound in these regions arises from the tumble of
+the stones from their pedestals or the slipping of the masses from the
+sharp ridge which is formed by the protection given to the ice through
+the thick coating of detritus on its surface. These movements of the
+moraines often distribute their waste over the glacier, so that in its
+lower part we can no longer trace the contributions from the several
+valleys, the whole area being covered by the _debris_. At the end of
+the ice stream, where its forward motion is finally overcome by the
+warmth which it encounters, it leaves in a rude heap, extending often
+like a wall across the valley, all the coarse fragments which it
+conveys. This accumulation, composed of all the lateral moraines which
+have gathered on the ice by the fall of avalanches, is called the
+terminal moraine. As the ice stream itself shrinks, a portion of the
+detritus next the boundary wall is apt to be left clinging against
+those slopes. It is from the presence of these heaps in valleys now
+abandoned by glaciers that we obtain some information as to the former
+greater extent of glacial action.
+
+The next most noticeable feature is the crevasse. These fractures
+often exist in very great numbers, and constitute a formidable barrier
+in the explorer's way. The greater part of these ruptures below the
+_serac_ zone run from the sides of the stream toward the centre
+without attaining that region. These are commonly pointed up stream;
+their formation is due to the fact that, owing to the swifter motion
+in the central parts of the stream, the ice in that section draws away
+from the material which is moving more slowly next the shore. As
+before noted, these ice fractures when drawn out naturally form
+fissures at right angles to the direction of the strain. In the middle
+portions of the ice other fissures form, though more rarely, which
+appear to depend on local strains brought about through the
+irregularity of the surface over which the ice is flowing.
+
+If the observer is fortunate, he may in his journey over the glacier
+have a chance to see and hear what goes on when crevasses are formed.
+First he will hear a deep, booming sound beneath his feet, which
+merges into a more splintering note as the crevice, which begins at
+the bottom or in the distance, comes upward or toward him. When the
+sound is over, he may not be able to see a trace of the fracture,
+which at first is very narrow. But if the break intersect any of the
+numerous shallow pools which in a warm summer's day are apt to cover a
+large part of the surface, he may note a line of bubbles rushing up
+through the water, marking the escape of the air from the glacier,
+some remnant of that which is imprisoned in the original snow. Even
+where this indication is wanting, he can sometimes trace the crevice
+by the hissing sound of the air streams where they issue from the ice.
+If he will take time to note what goes on, he can usually in an hour
+or two behold the first invisible crack widen until it may be half an
+inch across. He may see how the surface water hastens down the
+opening, a little river system being developed on the surface of the
+ice as the streams make their way to one or more points of descent. In
+doing this work they excavate a shaft which often becomes many feet in
+diameter, down which their waters thunder to the base of the glacier.
+This well-like opening is called a _moulin_, or mill, a name which, as
+we shall see, is well deserved from the work which falling waters
+accomplish. Although the institution of the _moulin_ shaft depends
+upon the formation of a crevice, it often happens that as the ice
+moves farther on its journey its walls are again thrust together,
+soldered in the manner peculiar to ice, so that no trace of the
+rupture remains except the shaft which it permitted to form. Like
+everything else in the glacier, the _moulin_ slowly moves down the
+slope, and remains open as long as it is the seat of descending waters
+produced by the summer melting. When it ceases to be kept open from
+the summer, its walls are squeezed together in the fashion that the
+crevices are closed.
+
+Forming here and there, and generally in considerable numbers, the
+crevices of a glacier entrap a good deal of the morainal _debris_,
+which falls through them to the bottom of the glacier. Smaller bits
+are washed into the _moulin_, by the streams arising from the melting
+ice, which is brought about by the warm sun of the summer, and
+particularly by the warm rains of that season. On those glaciers
+where, owing to the irregularity of the bottom over which the ice
+flows, these fractures are very numerous, it may happen that all the
+detritus brought upon the surface of the glacier by avalanches finds
+its way to the floor of the ice.
+
+Although it is difficult to learn what is going on at the under
+surface of the glacier, it is possible directly and indirectly to
+ascertain much concerning the peculiar and important work which is
+there done. The intrepid explorer may work his way in through the
+lateral fissures, and even with care safely descend some of the
+fissures which penetrate the central parts of a shallow ice stream.
+There, it may be at the depth of a hundred feet or more, he will find
+a quantity of stones, some of which may be in size like to a small
+house held in the body of the ice, but with one side resting upon the
+bed rock. He may be so fortunate as to see the stone actually in
+process of cutting a groove in the bed rock as it is urged forward by
+the motion of the glacier. The cutting is not altogether in the fixed
+material, for the boulder itself is also worn and scored in the work.
+Smaller pebbles are caught in the space between the erratic and the
+motionless rock and ground to bits. If in his explorations the student
+finds his way to the part of the floor on which the waters of a
+_moulin_ fall, he may have a chance to observe how the stones set in
+motion serve to cut the bed rock, forming elongated potholes much as
+in the case of ordinary waterfalls, or at the base of those shafts
+which afford the beginnings of limestone caverns.
+
+The best way to penetrate beneath the glacier is through the arch of
+the stream which always flows from the terminal face of the ice river.
+Even in winter time every large glacier discharges at its end a
+considerable brook, the waters of which have been melted from the ice
+in small part by the outflow of the earth's heat; mainly, however, by
+the warmth produced in the friction of the ice on itself and on its
+bottom--in other words, by the conversion of that energy of position,
+of which we have often to speak, into heat. In the summer time this
+subglacial stream is swollen by the surface waters descending through
+the crevices and the _moulins_ which come from them, so that the
+outflow often forms a considerable river, and thus excavates in the
+ice a large or at least a long cavern, the base of which is the bed
+rock. In the autumn, when the superficial melting ceases, this gallery
+can often be penetrated for a considerable distance, and affords an
+excellent way to the secrets of the under ice. The observer may here
+see quantities of the rock material held in the grip of the ice, and
+forced to a rude journey over the bare foundation stones. Now and then
+he may find the glacial mass in large measure made up of stones, the
+admixture extending many feet above the bottom of the cavern, perhaps
+to the very top of the arch. He may perchance find that these stones
+are crushing each other where they are in contact. The result will be
+brought about by the difference in the rate of advance of the ice,
+which moves the faster the higher it is above the surface over which
+it drags, and thus forces the stones on one level over those below.
+Where the waters of the subglacial stream have swept the bed rock
+clean of _debris_ its surface is scored, grooved, and here and there
+polished in a manner which is accomplished only by ice action, though
+some likeness to it is afforded where stones have been swept over for
+ages by blowing sand. Here and there, often in a way which interrupts
+the cavern journey, the shrunken stream, unable to carry forward the
+_debris_, deposits the material in the chamber, sometimes filling the
+arch so completely that the waters are forced to make a detour. This
+action is particularly interesting, for the reason that in regions
+whence glaciers have disappeared the deposits formed in the old ice
+arches often afford singularly perfect moulds of those caverns which
+were produced by the ancient subglacial streams. These moulds are
+termed _eskers_.
+
+If the observer be attentive, he will note the fact that the waters
+emerging from beneath the considerable glacier are very much charged
+with mud. If he will take a glass of the water at the point of escape,
+he will often find, on permitting it to settle, that the sediment
+amounts to as much as one twentieth of the volume. While the greater
+part of this detritus will descend to the bottom of the vessel in the
+course of a day, a portion of it does not thus fall. He may also note
+that this mud is not of the yellowish hue which he is accustomed to
+behold in the materials laid down by ordinary rivers, but has a
+whitish colour. Further study will reveal the fact that the difference
+is due to the lack of oxidation in the case of the glacial detritus.
+River muds forming slowly and during long-continued exposure to the
+action of the air have their contained iron much oxidized, which gives
+them a part of their darkened appearance. Moreover, they are somewhat
+coloured with decayed vegetable matter. The waste from beneath the
+glacier has been quickly separated from the bed rock, all the faces of
+the grains are freshly fractured, and there is no admixture of organic
+matter. The faces of the particles thus reflect light in substantially
+the same way as powdered glass or pulverized ice, and consequently
+appear white.
+
+A little observation will show the student that this very muddy
+character of waters emerging from beneath the glacier is essentially
+peculiar to such streams as we have described. Ascending any of the
+principal valleys of Switzerland, he may note that some of the streams
+flow waters which carry little sediment even in times when they are
+much swollen, while others at all seasons have the whitish colour. A
+little further exploration, or the use of a good map, will show him
+that the pellucid streams receive no contributions of glacial water,
+while those which look as if they were charged with milk come, in part
+at least, from the ice arches. From some studies which the writer has
+made in Swiss valleys, it appears that the amount of erosion
+accomplished on equal areas of similar rock by the descent of the
+waters in the form of a glacier or in that of ordinary torrents
+differs greatly. Moving in the form of ice, or in the state of
+ice-confined streams, the mass of water applies very many times as
+much of its energy of position to grinding and bearing away the rocks
+as is accomplished where the water descends in its fluid state.
+
+The effect of the intense ice action above noted is rapidly to wear
+away the rocks of the valley in which the glacier is situated. This
+work is done not only in a larger measure but in a different way from
+that accomplished by torrents. In the case of the latter, the stream
+bed is embarrassed by the rubbish which comes into it; only here and
+there can it attack the bed rock by forcing the stones over its
+surface. Only in a few days of heavy rain each year is its work at all
+effective; the greater part of the energy of position of its waters is
+expended in the endless twistings and turnings of its stream, which
+result only in the development of heat which flies away into the
+atmosphere. In the ice stream, owing to its slow movement and to the
+detritus which it forces along the bottom, a vastly greater part of
+the energy which impels it down the slope is applied to rock cutting.
+None of the boulders, even if they are yards in diameter, obstruct its
+motion; small and great alike are to it good instruments wherewith to
+attack the bed rocks. The fragments are never left to waste by
+atmospheric decay, but are to a very great extent used up in
+mechanical work, while the most of the detritus which comes to a
+torrent is left in a coarse state when it is delivered to the stream;
+the larger part of that which the glacier transports is worn out in
+its journey. To a great extent it is used up in attacking the bed
+rock. In most cases the _debris_ in the terminal moraine is evidently
+but a small part of what entered the ice during its journey from the
+uplands; the greater part has been worn out in the rude experiences to
+which it has been subjected.
+
+It is evident that even in the regions now most extensively occupied
+by glaciers the drainage systems have been shaped by the movement of
+ordinary streams--in other words, ice action is almost everywhere,
+even in the regions about the poles, an incidental feature in the work
+of water, coming in only to modify the topography, which is mainly
+moulded by the action of fluid water. When, owing to climatal changes,
+a valley such as those of the Alps is occupied by a glacial stream,
+the new current proceeds at once, according to its evident needs, to
+modify the shape of its channel. An ordinary torrent, because of the
+swiftness of its motion, which may, in general, be estimated at from
+three to five miles an hour, can convey away the precipitation over a
+very narrow bed. Therefore its channel is usually not a hundredth part
+as wide as the gorge or valley in which it lies. But when the
+discharge takes place by a glacier, the speed of which rarely exceeds
+four or five feet a day, the ice stream because of its slow motion has
+to fill the trough from side to side, it has to be some thousand times
+as deep and wide as the torrent. The result is that as soon as the
+glacial condition arises in a country the ice streams proceed to
+change the old V-shaped torrent beds into those which have a broad
+U-like form. The practised eye can in a way judge how long a valley
+has been subjected to glacial action by the extent to which it has
+been widened by this process.
+
+In the valleys of Switzerland and other mountain districts which have
+been attentively studied it is evident that glacial action has played
+a considerable part in determining their forms. But the work has been
+limited to that part of the basin in which the ice is abundantly
+provided with cutting tools in the stone which have found their way to
+the base of the stream. In the region of the _neve_, where the
+contributions of rocky matter to the surface of the deposit made from
+the few bare cliffs which rise above the sheet of snow is small, the
+snow-ice does no cutting of any consequence. Where it passes over the
+steep at the head of the deep valley into which it drains, and is
+riven into the _seracs_, such stony matter as it may have gathered is
+allowed to fall to the bottom, and so comes into a position where it
+may do effective work. From this _serac_ section downward the now
+distinct ice river, being in general below the snow line, has
+everywhere cliffs, on either side from which the contributions of rock
+material are abundant. Hence this part of the glacier, though it is
+the wasting portion of its length, does all the cutting work of any
+consequence which is performed. It is there that the underrunning
+streams become charged with sediment, which, as we have noted, they
+bear in surprising quantities, and it is therefore in this section of
+the valley that the impress of the ice work is the strongest. Its
+effect is not only to widen the valley and deepen it, but also to
+advance the deep section farther up the stream and its tributaries.
+The step in the stream beds which we find at the _seracs_ appears to
+mark the point in the course of the glacier where, owing to the
+falling of stones to its base, as well as to its swifter movements and
+the firmer state of the ice, it does effective wearing.
+
+There are many other features connected with glaciers which richly
+repay the study of those who have a mind to explore in the manner of
+the physicist interested in ice actions the difficult problems which
+they afford; but as these matters are not important from the point of
+view of this work, no mention of them will here be made. We will now
+turn our attention to that other group of glaciers commonly termed
+continental, which now exist about either pole, and which at various
+times in the earth's history have extended far toward the equator,
+mantling over vast extents of land and shallow sea. The difference
+between the ice streams of the mountains and those which we term
+continental depends solely on the areas of the fields and the depth of
+the accumulation. In an ordinary Alpine region the _neve_ districts,
+where the snow gathers, are relatively small. Owing to the rather
+steep slopes, the frozen water is rapidly discharged into the lower
+valleys, where it melts away. Both in the _neve_ and in the distinct
+glacier of the lower grounds there are, particularly in the latter,
+projecting peaks, from which quantities of stone are brought down by
+avalanches or in ordinary rock falls, so that the ice is abundantly
+supplied with cutting tools, which work from its surface down to its
+depths.
+
+As the glacial accumulation grows in depth there are fewer peaks
+emerging from it, and the streams which it feeds rise the higher until
+they mantle over the divides between the valleys. Thus by
+imperceptible stages valley glaciers pass to the larger form, usually
+but incorrectly termed continental. We can, indeed, in going from the
+mountains in the tropics to the poles, note every step in this
+transition, until in Greenland we attain the greatest ice mass in the
+world, unless that about the southern pole be more extensive. In the
+Greenland glacier the ice sheet covers a vast extent of what is
+probably a mountain country, which is certainly of this nature in the
+southern part of the island, where alone we find portions of the earth
+not completely covered by the deep envelope. Thanks to the labours of
+certain hardy explorers, among whom Nansen deserves the foremost
+place, we now know something as to the conditions of this vast ice
+field, for it has been crossed from shore to shore. The results of
+these studies are most interesting, for they afford us a clew as to
+the conditions which prevail over a large part of the earth during the
+Glacial period from which the planet is just escaping, and in the
+earlier ages when glaciation was likewise extensive. We shall
+therefore consider in a somewhat detailed way the features which the
+Greenland glacier presents.
+
+Starting from the eastern shore of that land, if we may thus term a
+region which presents itself mainly in the form of ice, we find next
+the shore a coast line not completely covered with ice and snow, but
+here and there exhibiting peaks which indicate that if the frozen
+mantle were removed the country would appear deeply intersected with
+fiords in the manner exhibited in the regions to the south of
+Greenland or the Scandinavian peninsula. The ice comes down to the
+sea through the valleys, often facing the ocean for great distances
+with its frozen cliffs. Entering on this seaward portion of the
+glacier, the observer finds that for some distance from the coast line
+the ice is more or less rifted with crevices, the formation of which
+is doubtless due to irregularities of the rock bottom over which it
+moves. These ruptures are so frequent that for some miles back it is
+very difficult to find a safe way. Finally, however, a point is
+attained where these breaks rather suddenly disappear, and thence
+inward the ice rises at the rate of upward slope of a few feet to the
+mile in a broad, nearly smooth incline. In the central portion of the
+region for a considerable part of the territory the ice has very
+little slope. Thence it declines toward the other shore, exhibiting
+the same features as were found on the eastern versant until near the
+coast, when again the surface is beset with crevices which continue to
+the margin of the sea.
+
+Although the explorations of the central field of Greenland are as yet
+incomplete, several of these excursions into or across the interior
+have been made, and the identity of the observations is such that we
+can safely assume the whole region to be of one type. We can
+furthermore run no risk in assuming that what we find in Greenland, at
+least so far as the unbroken nature of the central ice field is
+concerned, is what must exist in every land where the glacial envelope
+becomes very deep. In Greenland it seems likely that the depth of the
+ice is on the average more than half a mile, and in the central part
+of the realm the sheet may well have a much greater profundity; it may
+be nearly a mile deep. The most striking feature--that of a vast
+unbroken expanse, bordered by a region where the ice is ruptured--is
+traceable wherever very extensive and presumably deep deposits of ice
+have been examined. As we shall see hereafter, these features teach us
+much as to the conditions of glacial action--a matter which we shall
+have to examine after we have completed our general survey as to the
+changes which occur during glacial periods.
+
+In the present state of that wonderful complex of actions which we
+term climate, glaciers are everywhere, so far as our observations
+enable us to judge, generally in process of decrease. In Switzerland,
+although the ancients even in Roman days were in contact with the ice,
+they were so unobservant that they did not even remark that the ice
+was in motion. Only during the last two centuries have we any
+observations of a historic sort which are of value to the geologist.
+Fortunately, however, the signs written on the rock tell the story,
+except for its measurement in terms of years, as clearly as any
+records could give it. From this testimony of the rocks we perceive
+that in the geological yesterday, though it may have been some tens of
+thousands of years ago, the Swiss glaciers, vastly thickened, and with
+their horizontal area immensely expanded, stretched over the Alpine
+country, so that only here and there did any of the sharper peaks rise
+above the surface. These vast glaciers, almost continually united on
+their margins, extended so far that every portion of what is now the
+Swiss Republic was covered by them. Their front lay on the southern
+lowlands of Germany, on the Jura district of France; on the south, it
+stretched across the valley of the Po as far as near Milan. We know
+this old ice front by the accumulations of rock _debris_ which were
+brought to it from the interior of the mountain realm. We can
+recognise the peculiar kinds of stone, and with perfect certainty
+trace them to the bed rock whence they were riven. Moreover, we can
+follow back through the same evidence the stages of retreat of the
+glaciers, until they lost their broad continental character and
+assumed something like their present valley form. Up the valley of any
+of the great rivers, as, for instance, that of the Rhone above the
+lake of Geneva, we note successive terminal moraines which clearly
+indicate stages in the retreat of the ice when for a time it ceased to
+go backward, or even made a slight temporary readvance. It is easily
+seen that on such occasions the stones carried to the ice front would
+be accumulated in a heap, while during the time when day by day the
+glacier was retreating the rock waste would be left broadcast over the
+valley.
+
+As we go up from the course of the glacial streams we note that the
+successive moraines have their materials in a progressively less
+decayed state. Far away from the heap now forming, and in proportion
+to the distance, the stones have in a measure rotted, and the heaps
+which they compose are often covered with soil and occupied by
+forests. Within a few miles of the ice front the stones still have a
+fresh aspect. When we arrive within, say, half a mile of the moraine
+now building, we come to the part of the glacial retreat of which we
+have some written or traditional account. This is in general to the
+effect that the wasting of the glaciers is going on in this century as
+it went on in the past. Occasionally periods of heavy snow would
+refresh the ice streams, so that for a little time they pushed their
+fronts farther down the valley. The writer has seen during one of
+these temporary advances the interesting spectacle of ice destroying
+and overturning the soil of a small field which had been planted in
+grain.
+
+It should be noted that these temporary advances of the ice are not
+due to the snowfall of the winter or winters immediately preceding the
+forward movement. So slow is the journey of the ice from the _neve_
+field to the end of a long glacier that it may require centuries for
+the store accumulated in the uplands to affect the terminal portion of
+the stream. We know that the bodies of the unhappy men who have been
+lost in the crevices of the glacier are borne forward at a uniform and
+tolerably computable rate until they emerge at the front, where the
+ice melts away. In at least one case the remains have appeared after
+many years in the _debris_ which is contributed to the moraine. On
+account of this slow feeding of the glacial stream, we naturally may
+expect to find, as we do, in fact, that a great snowfall of many
+years ago, and likewise a period when the winter's contribution has
+been slight, would influence the position of the terminal point of the
+ice stream at different times, according to its length. If the length
+of the flow be five miles, it may require twenty or thirty years for
+the effect to be evident; while if the stream be ten miles long, the
+influence may not be noted in less than threescore years. Thus it
+comes about that at the present time in the same glacial district some
+streams may be advancing while others are receding, though, on the
+whole, the ice is generally in process of shrinkage. If the present
+rate of retreat should be maintained, it seems certain that at the end
+of three centuries the Swiss glaciers as a whole will not have
+anything like their present area, and many of the smaller streams will
+entirely disappear.
+
+Following the method of the illustrious Louis Agassiz, who first
+attentively traced the evidence which shows the geologically recent
+great extension of glaciers by studying the evidence of the action in
+fields they no longer occupy, geologists have now inspected a large
+part of the land areas with a view to finding the proofs of such ice
+work. So far as these indications are concerned, the indications which
+they have had to trace are generally of a very unmistakable character.
+Rarely, indeed, does a skilled student of such phenomena have to
+search in any region for more than a day before he obtains indubitable
+evidence which will enable him to determine whether or not the field
+has recently been occupied by an enduring ice sheet--one which
+survives the summer season and therefore deserves the name of glacier.
+The indications which he has to consider consist in the direction and
+manner in which the surface materials have been carried, the physical
+conditions of these materials, the shape of the surface of the
+underlying rock as regards its general contour, and the presence or
+absence of scratches and groovings on its surface. As these records of
+ice action are of first importance in dealing with this problem, and
+as they afford excellent subjects for the study of those who dwell in
+glaciated regions, we shall note them in some detail.
+
+The geologist recognises several ways in which materials may be
+transported on the surface of the earth. They may be cast forth by
+volcanoes, making their journey by being shot through the air, or by
+flowing in lava streams; it is always easy at a glance, save in very
+rare instances, to determine whether fragments have thus been
+conveyed. Again, the detritus may be moved by the wind; this action is
+limited; it only affects dust, sand, and very small pebbles, and is
+easily discriminated. The carriage may be effected by river or marine
+currents; here, again, the size of the fragments moved is small, and
+the order of their arrangement distinctly traceable. The fragments may
+be conveyed by ice rafts; here, too, the observer can usually limit
+the probabilities he has to consider by ascertaining, as he can
+generally do, whether the region which he is observing has been below
+a sea or lake. In a word, the before-mentioned agents of
+transportation are of somewhat exceptional influence, and in most
+cases can, as explanations of rock transportation, be readily
+excluded. When, therefore, the geologist finds a country abundantly
+covered with sand, pebbles, and boulders arranged in an irregular way,
+he has generally only to inquire whether the material has been carried
+by rivers or by glaciers. This discrimination can be quickly and
+critically effected. In the first place, he notes that rivers only in
+their torrent sections can carry large fragments of rock, and that in
+all cases the fragments move down hill. Further, that where deposits
+are formed, they have more or less the form of alluvial deposits. If
+now the observations show that the rock waste occupying the surface of
+any region has been carried up hill and down, across the valleys,
+particularly if there are here and there traces of frontal moraines,
+the geologist is entitled to suppose--he may, indeed, be sure--that
+the carriage has been effected by a glacial sheet.
+
+Important corroborative evidence of ice action is generally to be
+found by inspecting the bed rock below the detritus, which indicates
+glacial action. Even if it be somewhat decayed, as is apt to be the
+case where the ice sheet long since passed away, the bed rock is
+likely to have a warped surface; it is cast into ridges and furrows of
+a broad, flowing aspect, such as liquid water never produces, which,
+indeed, can only be created by an ice sheet moving over the surface,
+cutting its bed in proportion to the hardness of the material.
+Furthermore, if the bed rock have a firm texture, and be not too much
+decayed, we almost always find upon it grooves or scratches, channels
+carved by the stones embedded in the body of the ice, and drawn by its
+motion over the fixed material. Thus the proof of glacial extension in
+the last ice epoch is made so clear that accurate maps can be prepared
+showing the realm of its action. This task is as yet incomplete,
+although it is already far advanced.
+
+While the study of glaciers began in Europe, inquiries concerning
+their ancient extension have been carried further and with more
+accuracy in North America than in any other part of the world. We may
+therefore well begin our description of the limits of the ice sheets
+with this continent. Imagining a seafarer to have approached America
+by the North Atlantic, as did the Scandinavians, and that his voyage
+came perhaps a hundred thousand years or more before that of Leif
+Ericsson, he would have found an ice front long before he attained the
+present shores of the land. This front may have extended from south of
+Greenland, off the shores of the present Grand Banks of Newfoundland,
+thence and westward to central or southern New Jersey. This cliff of
+ice was formed by a sheet which lay on the bottom of the sea. On the
+New Jersey coast the ice wall left the sea and entered on the body of
+the continent. We will now suppose that the explorer, animated with
+the valiant scientific spirit which leads the men of our day to seek
+the poles, undertook a land journey along the ice front across the
+continent. From the New Jersey coast the traveller would have passed
+through central Pennsylvania, where, although there probably detached
+outlying glaciers lying to the southward as far as central Virginia,
+the main front extended westward into the Ohio Valley. In southern
+Ohio a tongue of the ice projected southwardly until it crossed the
+Ohio River, where Cincinnati now lies, extending a few miles to the
+southward of the stream. Thence it deflected northwardly, crossing the
+Mississippi, and again the Missouri, with a tongue or lobe which went
+far southward in that State. Then again turning to the northwest, it
+followed in general the northern part of the Missouri basin until it
+came to within sight of the Rocky Mountains. There the ice front of
+the main glacier followed the trend of the mountains at some distance
+from their face for an unknown extent to the northward. In the
+Cordilleras, as far south as southern Colorado, and probably in the
+Sierra Nevada to south of San Francisco, the mountain centres
+developed local glaciers, which in some places were of very great
+size, perhaps exceeding any of those which now exist in Switzerland.
+It will thus be seen that nearly one half of the present land area of
+North America was beneath a glacial covering, though, as before noted,
+the region about the Gulf of Mexico may have swayed upward when the
+northern portion of the land was borne down by the vast load of ice
+which rested upon it. Notwithstanding this possible addition to the
+land, our imaginary explorer would have found the portion of the
+continent fit for the occupancy of life not more than half as great as
+it is at present.
+
+In the Eurasian continent there was no such continuous ice sheet as in
+North America, but the glaciers developed from a number of different
+centres, each moving out upon the lowlands, or, if its position was
+southern, being limited to a particular mountain field. One of these
+centres included Scandinavia, northern Germany, Great Britain about as
+far south as London, and a large part of Ireland, the ice covering the
+intermediate seas and extending to the westward, so that the passage
+of the North Atlantic was greatly restricted between this ice front
+and that of North America. Another centre, before noted, was formed in
+the Alps; yet another, of considerable area, in the Pyrenees; other
+less studied fields existed in the Apennines, in the Caucasus, the
+Ural, and the other mountains of northern Asia. Curiously enough,
+however, the great region of plains in Siberia does not appear to have
+been occupied by a continuous ice sheet, though the similar region in
+North America was deeply embedded in a glacier. Coincident with this
+development of ice in the eastern part of the continent, the ice
+streams of the Himalayan Mountains, some of which are among the
+greatest of our upland glaciers, appear to have undergone but a
+moderate extension. Many other of the Eurasian highlands were probably
+ice-bound during the last Glacial period, but our knowledge concerning
+these local fields is as yet imperfect.
+
+In the southern hemisphere the lands are of less extent and, on the
+whole, less studied than in the northern realm. Here and there where
+glaciers exist, as in New Zealand and in the southern part of South
+America, observant travellers have noticed that these ice fields have
+recently shrunk away. Whether the time of greatest extension and of
+retreat coincided with that of the ice sheets in the north is not yet
+determined; the problem, indeed, is one of some difficulty, and may
+long remain undecided. It seems, however, probable that the glaciers
+of the southern hemisphere, like those in the north, are in process of
+retreat. If this be true, then their time of greatest extension was
+probably the same as that of the ice sheets about the southern pole.
+From certain imperfect reports which we have concerning evidences of
+glaciation in Central America and in the Andean district in the
+northern part of South America, it seems possible that at one time the
+upland ice along the Cordilleran chain existed from point to point
+along that system of elevations, so that the widest interval between
+the fields of permanent snow with their attendant glaciers did not
+much exceed a thousand miles.
+
+Observing the present gradual retreat of those ice remnants which
+remain mere shreds and patches of the ancient fields, it seems at
+first sight likely that the extension and recession of the great
+glaciers took place with exceeding slowness. Measured in terms of
+human life, in the manner in which we gauge matters of man's history,
+this process was doubtless slow. There are reasons, however, to
+believe that the coming and going were, in a geological sense, swift;
+they may have, indeed, been for a part of the time of startling
+rapidity. Going back to the time of geological yesterday, before the
+ice began its development in the northern hemisphere, all the evidence
+we can find appears to indicate a temperate climate extending far
+toward the north pole. The Miocene deposits found within twelve
+degrees, or a little more than seven hundred miles, of the north pole,
+and fairly within the realm of lowest temperature which now exists on
+the earth, show by the plant remains which they contain that the
+conditions permitted the growth of forests, the plants having a
+tolerably close resemblance to those which now freely develop in the
+southern portion of the Mississippi Valley. Among them there are
+species which had the habit of retaining their broad, rather soft
+leaves throughout the winter season. The climate appears, in a word,
+to have been one where the mean annual temperature must have been
+thirty degrees or more higher than the present average of that realm.
+Although such conditions near the sea level are not inconsistent with
+the supposition that glaciers existed in the higher mountains of the
+north, they clearly deny the possibility of the realm being occupied
+by continental glaciers.
+
+Although the Pliocene deposits formed in high latitudes have to a
+great extent been swept away by the subsequent glacial wearing, they
+indicate by their fossils a climatal change in the direction of
+greater cold. We trace this change, though obscurely, in a
+progressive manner to a point where the records are interrupted, and
+the next interpretable indication we have is that the ice sheet had
+extended to somewhere near the limits which we have noted. We are then
+driven to seek what we can concerning the sojourn of the ice on the
+land by the amount of wearing which it has inflicted upon the areas
+which it occupied. This evidence has a certain, though, as we shall
+see, a limited value.
+
+When the students of glacial action first began the great task of
+interpreting these records, they were led to suppose that the amount
+of rock cutting which was done by the ice was very great. Observing
+what goes on, in the manner we have noted, beneath a valley glacier
+such as those of Switzerland, they saw that the ice work went on
+rapidly, and concluded that if the ice remained long at work in a
+region it must do a vast deal of erosion. They were right in a part of
+their premises, but, as we shall see, probably in another part wrong.
+Looking carefully over the field where the ice has operated, we note
+that, though at first sight the area appears to have lost all trace of
+its preglacial river topography, this aspect is due mainly to the
+irregular way in which the glacial waste is laid down. Close study
+shows us that we may generally trace the old stream valleys down to
+those which were no larger than brooks. It is true that these channels
+are generally and in many places almost altogether filled in with
+rubbish, but a close study of the question has convinced the writer,
+and this against a previous view, that the amount of erosion in New
+England and Canada, where the work was probably as great as anywhere,
+has not on the average exceeded a hundred feet, and probably was much
+less than that amount.
+
+Even in the region north of Lake Ontario, over which the ice was deep
+and remained for a long time, the amount of erosion is singularly
+small. Thus north of Kingston the little valleys in the limestone
+rocks which were cut by the preglacial streams, though somewhat
+encumbered with drift, remain almost as distinct as they are on
+similar strata in central Kentucky, well south of the field which the
+ice occupied. In fact, the ice sheet appears to have done the greatest
+part of its work and to have affected the surface most in the belt of
+country a few hundred miles in width around the edges of the sheet. It
+was to be expected that in a continental glacier, as in those of
+mountain valleys, the most of the _debris_ should be accumulated about
+the margin where the materials dropped from the ice. But why the
+cutting action should be greatest in that marginal field is not at
+first sight clear. To explain this and other features as best we may,
+we shall now consider the probable history of the great ice march in
+advance and retreat, and then take up the conditions which brought
+about its development and its disappearance.
+
+Ice is in many ways the most remarkable substance with which the
+physicist has to deal, and among its eminent peculiarities is that it
+expands in freezing, while the rule is that substances contract in
+passing from the fluid to the solid state. On this account frozen
+water acts in a unique manner when subjected to pressure. For each
+additional atmosphere of pressure--a weight amounting to about fifteen
+pounds to the square inch--the temperature at which the ice will melt
+is lowered to the amount of sixteen thousandths of a degree
+centigrade. If we take a piece of ice at the temperature of freezing
+and put upon it a sufficient weight, we inevitably bring about a small
+amount of melting. Where we can examine the mass under favourable
+conditions, we can see the fluid gather along the lines of the
+crystals or other bits of which the ice is composed. We readily note
+this action by bringing two pieces of ice together with a slight
+pressure; when the pressure is removed, they will adhere. The adhesion
+is brought about not by any stickiness of the materials, for the
+substance has no such property. It is accomplished by melting along
+the line of contact, which forms a film of water, that at once
+refreezes when the pressure is withdrawn. When a firm snowball is
+made by even pressing snow, innumerable similar adhesions grow up in
+the manner described. The fact is that, given ice at the temperature
+at which it ordinarily forms, pressure upon it will necessarily
+develop melting.
+
+The consequences of pressure melting as above described are in
+glaciers extremely complicated. Because the ice is built into the
+glacier at a temperature considerably below the freezing point, it
+requires a great thickness of the mass before the superincumbent
+weight is sufficient to bring about melting in its lower parts. If we
+knew the height at which a thermometer would have stood in the surface
+ice of the ancient glacier which covered the northern part of North
+America, we could with some accuracy compute how thick it must have
+been before the effect of pressure alone would have brought about
+melting; but even then we should have to reckon the temperature
+derived from the grinding of the ice over the floor and the crushing
+of rocks there effected, as well as the heat which is constantly
+though slowly coming forth from the earth's interior. The result is
+that we can only say that at some depth, probably less than a mile,
+the slowly accumulating ice would acquire such a temperature that,
+subjected to the weight above it, the material next the bottom would
+become molten, or at least converted into a sludgelike state, in which
+it could not rub against the bottom, or move stones in the manner of
+ordinary glaciers.
+
+As fast as the ice assumed this liquid or softened state, it would be
+squeezed out toward the region where, because of the thinning of the
+glacier, it would enter a field where pressure melting did not occur.
+It would then resume the solid state, and thence journey to the margin
+of the ice in the ordinary manner. We thus can imagine how such a
+glacier as occupied the northern part of this continent could have
+moved from the central parts toward its periphery, as we can not do if
+we assume that the glacier everywhere lay upon the bed rock. There is
+no slope from Lake Erie to the Ohio River at Cincinnati. Knowing that
+the ice moved down this line, there are but two methods of accounting
+for its motion: either the slope of the upper surface to the northward
+was so steep that the mass would have been thus urged down, the upper
+parts dragging the bottom along with them, or the ice sheet for the
+greater part of its extent rested upon pressure-molten water, or
+sludge ice, which was easily squeezed out toward the front. The first
+supposition appears inadmissible, for the reason that the ice would
+have to be many miles deep at Hudson Bay in order that its upper
+surface should have slope enough to overcome the rigidity of the
+material and bring about the movement. We know that any such depth is
+not supposable.
+
+The recent studies in Greenland supply us with strong corroborative
+evidence for the support of the view which is here urged. The wide
+central field of that area, where the ice has an exceeding slight
+declivity, and is unruptured by crevices, can not be explained except
+on the supposition that it rests on pressure-molten water. The thinner
+section next the shore, where the glacier is broken up by those
+irregular movements which its wrestle with the bottom inevitably
+induces, shows that there it is in contact with the bed rock, for it
+behaves exactly as do the valley glaciers of like thickness.
+
+The view above suggested as to the condition of continental glaciers
+enables us to explain not only their movements, but the relatively
+slight amount of wearing which they brought about on the lands they
+occupied. Beginning to develop in mountain regions, or near the poles
+on the lowlands, these sheets, as soon as they attained the thickness
+where the ice at their bottom became molten, would rapidly advance for
+great distances until they attained districts where the melting
+exceeded the supply of frozen material. In this excursion only the
+marginal portion of the glacier would do erosive work. This would
+evidently be continued for the greatest amount of time near the front
+or outer rim of the ice field, for there, we may presume, that for
+the longest time the cutting rim would rest upon the bed rock of the
+country. As the ice receded, this rim would fall back; thus in the
+retreat as in the advance the whole of the field would be subjected to
+a certain amount of erosion. On this supposition we should expect to
+find that the front of a continental glacier, fed with pressure-molten
+water from all its interior district, which became converted into ice,
+would attain much warmer regions than the valley streams, where all
+the flow took place in the state of ice, and, furthermore, that the
+speed of the going on the margin would be much more rapid than in the
+Alpine streams. These suppositions are well borne out by the study of
+existing continental ice sheets, which move with singular rapidity at
+their fronts, and by the ancient glaciers, which evidently extended
+into rather warm fields. Thus, when the ice front lay at the site of
+Cincinnati, at six hundred feet above the sea, there were no glaciers
+in the mountains of North Carolina, though those rise more than five
+thousand feet higher in the air, and are less than two hundred miles
+farther south. It is therefore evident that the continental glacier at
+this time pushed southward into a comparatively warm country in a way
+that no stream moving in the manner of a valley glacier could possibly
+have done.
+
+The continental glaciers manage in many cases to convey detritus from
+a great distance. Thus, when the ice sheet advanced southwardly from
+the regions north of the Great Lakes, they conveyed quantities of the
+_debris_ from that section as far south as the Ohio River. In part
+this rubbish was dragged forward by the ice as the sheet advanced; in
+part it was urged onward by the streams of liquid water formed by the
+ordinary process of ice melting. Such subglacial rivers appear to have
+been formed along the margins of all the great glaciers. We can
+sometimes trace their course by the excavation which they have made,
+but more commonly by the long ridges of stratified sand and gravel
+which were packed into the caverns excavated by these subglacial
+rivers, which are known to glacialists as _eskers_, or as serpent
+kames. In many cases we can trace where these streams flowed up stream
+in the old river valleys until they discharged over their head waters.
+Thus in the valley of the Genesee, which now flows from Pennsylvania,
+where it heads against the tributaries of the Ohio and Susquehanna, to
+Lake Ontario, there was during the Glacial epoch a considerable river
+which discharged its waters into those of the Ohio and the Susquehanna
+over the falls at the head of its course.
+
+[Illustration: _Front of Muir Glacier, showing ice entering the sea;
+also small icebergs._]
+
+The effect of widespread glacial action on a country such as North
+America appears to have been, in the first place, to disturb the
+attitude of the land by bearing down portions of its surface, a
+process which led to the uprising of other parts which lay beyond the
+realm of the ice. Within the field of glaciation, so far as the ice
+rested bodily on the surface, the rocks were rapidly worn away. A
+great deal of the _debris_ was ground to fine powder, and went far
+with the waters of the under-running streams. A large part was
+entangled in the ice, and moved forward toward the front of the
+glacier, where it was either dropped at the margin or, during the
+recession of the glacier, was laid upon the surface as the ice melted
+away. The result of this erosion and transportation has been to change
+the conditions of the surface both as regards soil and drainage. As
+the reader has doubtless perceived, ordinary soil is, outside of the
+river valleys, derived from the rock beneath where it lies. In
+glaciated districts the material is commonly brought from a
+considerable distance, often from miles away. These ice-made soils are
+rarely very fertile, but they commonly have a great endurance for
+tillage, and this for the reason that the earth is refreshed by the
+decay of the pebbles which they contain. Moreover, while the tillable
+earth of other regions usually has a limited depth, verging downward
+into the semisoil or subsoil which represent the little changed bed
+rocks, glacial deposits can generally be ploughed as deeply as may
+prove desirable.
+
+The drainage of a country recently affected by glaciers is always
+imperfect. Owing to the irregular erosion of the bed rocks, and to the
+yet more irregular deposition of the detritus, there are very numerous
+lakes which are only slowly filled up or by erosion provided with
+drainage channels. Though several thousand years have passed by since
+the ice disappeared from North America, the greater part of the area
+of these fresh-water basins remains, the greater number of them,
+mostly those of small size, have become closed.
+
+Where an ice stream descends into the sea or into a large lake, the
+depth of which is about as great as the ice is thick, the relative
+lightness of the ice tends to make it float, and it shortly breaks off
+from the parent mass, forming an iceberg. Where, as is generally the
+case in those glaciers which enter the ocean, a current sweeps by the
+place where the berg is formed, it may enter upon a journey which may
+carry the mass thousands of miles from its origin. The bergs separated
+from the Greenland glaciers, and from those about the south pole, are
+often of very great size; sometimes, indeed, they are some thousand
+feet in thickness, and have a length of several miles. It often
+happens that these bergs are formed of ice, which contains in its
+lower part a large amount of rock _debris_. As the submerged portion
+of the glacier melts in the sea water, these stones are gradually
+dropped to the bottom, so that the cargo of one berg may be strewed
+along a line many hundred miles in length. It occasionally happens
+that the ice mass melts more slowly in those parts which are in the
+air than in its under-water portions. It thus becomes top-heavy and
+overturns, in which case such stony matter as remains attains a
+position where it may be conveyed for a greater distance than if the
+glacier were not capsized. It is likely, indeed, that now and then
+fragments of rock from Greenland are dropped on the ocean floor in the
+part of the Atlantic which is traversed by steamers between our
+Atlantic ports and Great Britain.
+
+Except for the risks which they bring to navigators, icebergs have no
+considerable importance. It is true they somewhat affect the
+temperature of sea and air, and they also serve to convey fragments of
+stone far out to sea in a way that no other agent can effect; but, on
+the whole, their influence on the conditions of the earth is
+inconsiderable.
+
+Icebergs in certain cases afford interesting indices as to the motion
+of oceanic currents, which, though moving swiftly at a depth below the
+surface, do not manifest themselves on the plain of the sea. Thus in
+the region about Greenland, particularly in Davis Strait, bergs have
+been seen forcing their way southward at considerable speed through
+ordinary surface ice, which was either at rest or moving in the
+opposite direction. The train of these bergs, which moves upward from
+the south polar continent, west of Patagonia, indicates also in a very
+emphatic way the existence of a very strong northward-setting current
+in that part of the ocean.
+
+                  *       *       *       *       *
+
+We have now to consider the causes which could bring about such great
+extensions of the ice sheet as occurred in the last Glacial period.
+Here again we are upon the confines of geological knowledge, and in a
+field where there are no well-cleared ways for the understanding. In
+facing this problem, we should first note that those who are of the
+opinion that a Glacial period means a very cold climate in the regions
+where the ice attained its extension are probably in error. Natural as
+it may seem to look for exceeding cold as the cause of glaciation, the
+facts show us that we can not hold this view. In Siberia and in the
+parts of North America bordering on the Arctic Sea the average cold is
+so intense that the ground is permanently frozen--as it is, for
+instance, in the Klondike district--to the depth of hundreds of feet,
+only the surface thawing out during the warm summers. All this region
+is cold enough for glaciers, but there is not sufficient snowfall to
+maintain them. On the other hand, in Greenland, and in a less though
+conspicuous degree in Scandinavia, where the waters of the North
+Atlantic somewhat diminish the rigour of the cold, and at the same
+time bring about a more abundant snowfall, the two actions being
+intimately related, we have very extensive glaciers. Such facts, which
+could be very much extended, make it clear that the climate of glacial
+periods must have been characterized by a great snowfall, and not by
+the most intense cold.
+
+It is evident that what would be necessary again to envelop the boreal
+parts of North America with a glacial sheet would not be a
+considerable decrease of heat, but an increase in the winter's
+contribution of frozen water. Even if the heat released by this
+snowfall elevated the average temperature of the winter, as it
+doubtless would in a considerable measure, it would not melt off the
+snow. That snowfall tends to warm the air by setting free the heat
+which was engaged in keeping the water in a state of vapour is
+familiarly shown by the warming which attends an ordinary snowstorm.
+Even if the fall begin with a temperature of about 0 deg. Fahr., the air
+is pretty sure to rise to near the freezing point.
+
+It is evident that no great change of temperature is required in order
+to bring about a very considerable increase in the amount of snowfall.
+In the ordinary succession of seasons we often note the occurrence of
+winters during which the precipitation of snow is much above the
+average, though it can not be explained by a considerable climatal
+change. We have to account for these departures from the normal
+weather by supposing that the atmospheric currents bring in more than
+the usual amount of moisture from the sea during the period when great
+falls of snow occur. In fact, in explaining variations in the humidity
+of the land, whether those of a constant nature or those that are to
+be termed accidental, we have always to look to those features which
+determine the importation of vapour from the great field of the ocean
+where it enters the air. We should furthermore note that these
+peculiarities of climate are dependent upon rather slight geographic
+accidents. Thus the snowfall of northern Europe, which serves to
+maintain the glaciation of that region, and, curiously enough, in some
+measure its general warmth, depends upon the movement of the Gulf
+Stream from the tropics to high latitudes. If by any geographical
+change, such as would occur if Central America were lowered so as to
+make a free passage for its waters to the westward, the glaciers of
+Greenland and of Scandinavia would disappear, and at the same time the
+temperature of those would be greatly lowered. Thus the most evident
+cause of glaciation must be sought in those alterations of the land
+which affect the movement of the oceanic currents.
+
+Applying this principle to the northern hemisphere, we can in a way
+imagine a change which would probably bring about a return of such an
+ice period as that from which the boreal realm is now escaping. Let us
+suppose that the region of not very high land about Bering Strait
+should sink down so as to afford the Kuro Siwo, or North Pacific
+equivalent of our Gulf Stream, an opportunity to enter the Arctic Sea
+with something like the freedom with which the North Atlantic current
+is allowed to penetrate to high latitudes. It seems likely that this
+Pacific current, which in volume and warmth is comparable to that of
+the Atlantic, would so far elevate the temperature of the arctic
+waters that their wide field would be the seat of a great evaporation.
+Noting once again the fact that the Greenland glaciers, as well as
+those of Norway, are supplied from seas warmed by the Gulf Stream, we
+should expect the result of this change would be to develop similar
+ice fields on all the lands near that ocean.
+
+Applying the data gathered by Dr. Croll for the Gulf Stream, it seems
+likely that the average annual temperature induced in the Arctic Sea
+by the free entrance of the Japan current would be between 20 deg. and 30 deg.
+Fahr. This would convert this wide realm of waters into a field of
+great evaporation, vastly increasing the annual precipitation. It
+seems also certain that the greater part of this precipitation would
+be in the form of snow. It appears to the writer that this cause alone
+may be sufficient to account for the last Glacial period in the
+northern hemisphere. As to the probability that the region about
+Bering Strait may have been lowered in the manner required by this
+view, it may be said that recent studies on the region about Mount St.
+Elias show that during or just after the ice epoch the shores in that
+portion of Alaska were at least four thousand feet lower than at
+present. As this is but a little way from the land which we should
+have to suppose to be lowered in order to admit the Japan current, we
+could fairly conclude that the required change occurred. As for the
+cause of the land movement, geologists are still in doubt. They know,
+however, that the attitudes of the land are exceedingly unstable, and
+that the shores rarely for any considerable time maintain their
+position. It is probable that these swayings of the earth's surface
+are due to ever-changing combinations of the weight in different parts
+of the crust and the strains arising from the contraction of its inner
+parts.
+
+In the larger operations of Nature the effects which we behold,
+however simple, are rarely the products of a single cause. In fact,
+there are few actions so limited that they can fairly be referred to
+one influence. It is therefore proper to state that there are many
+other actions besides those above noted which probably enter into
+those complicated equations which determine the climatal conditions of
+the earth. To have these would carry us into difficult and speculative
+inquiries.
+
+As before remarked, all the regions which have been subjected to
+glaciation are still each year brought temporarily into the glacial
+state. This fact serves to show us that the changes necessary to
+produce great ice sheets are not necessarily of a startling nature,
+however great the consequences may be. Assuming, then, that relatively
+slight alterations of climate may cause the ice sheet to come and go,
+we may say that all the influences which have been suggested by the
+students of glaciation, and various other slighter causes which can
+not be here noted, may have co-operated to produce the peculiar
+result. In this equation geographic change has affected the course of
+the ocean currents, and has probably been the most influential, or at
+least the commonest, cause to which we must attribute the extension of
+ice sheets. Next, alterations of the solar heat may be looked to as a
+change-bringing action; unfortunately, however, we have no direct
+evidence that this is an efficient cause. Thirdly, the variations in
+the eccentricity of the earth's orbit, combined with the precession of
+the equinoxes and the rotation of the apsides, may be regarded as
+operative. The last of all, changes in the constitution of the
+atmosphere, have to be taken into account. To these must be added, as
+before remarked, many less important actions which influence this
+marvellously delicate machine, the work of which is expressed in the
+phenomena assembled under the name of climate.
+
+Evidence is slowly accumulating which serves to show that glacial
+periods of greater or less importance have been of frequent occurrence
+at all stages in the history of the earth of which we have a distinct
+record. As these accidents write their history upon the ground alone,
+and in a way impermanently, it is difficult to trace the ice times of
+ancient geological periods. The scratches on the bed rocks, and the
+accumulations of detritus formed as the ice disappeared, have alike
+been worn away by the agents of decay. Nevertheless, we can trace here
+and there in the older strata accumulations of pebbly matter often
+containing large boulders, which clearly were shaped and brought
+together by glacial action. These are found in some instances far
+south of the region occupied by the glaciers during the last ice
+epoch. They occur in rocks of the Cambrian or Silurian age in eastern
+Tennessee and western North Carolina; they are also found in India
+beyond the limits to which glaciers have attained in modern times.
+
+In closing this inadequate account of glacial action, a story which
+for its complete telling would require many volumes, it is well for
+the reader to consider once again how slight are the changes of
+climate which may alternately withdraw large parts of the land from
+the uses of life, and again quickly restore the fields to the service
+of plants and animals. He may well imagine that these changes, by
+driving living creatures to and fro, profoundly affect the history of
+their development. This matter will be dealt with in the volume
+concerning the history of organic beings.
+
+When the ice went off from the northern part of this continent, the
+surface of the country, which had been borne down by the weight of the
+glacier, still remained depressed to a considerable depth below the
+level of the sea, the depression varying from somewhere about one
+hundred feet in southern New England to a thousand feet or more in
+high latitudes. Over this region, which lay beneath the level of the
+sea, the glacier, when it became thin enough to float, was doubtless
+broken up into icebergs, in the manner which we now behold along the
+coast of Greenland. Where the shore was swept by a strong current,
+these bergs doubtless drifted away; but along the most of the coast
+line they appear to have lain thickly grouped next the shores,
+gradually delivering their loads of stones and finer _debris_ to the
+bottom. These masses of floating ice in many cases seem to have
+prevented the sea waves from attaining the shore, and thus hindered
+the formation of those beaches which in their present elevated
+condition enable us to interpret the old position of the sea along
+coast lines which have been recently elevated. Here and there,
+however, from New Jersey to Greenland, we find bits of these ancient
+shores which clearly tell the story of that down-sinking of the land
+beneath the burden of the ice which is such an instructive feature in
+the history of that period.
+
+
+
+
+                          CHAPTER VII.
+
+                  THE WORK OF UNDERGROUND WATER.
+
+
+We have already noted two means by which water finds its way
+underground. The simplest and largest method by which this action is
+effected is by building in the fluid as the grains of the rock are
+laid down on the floors of seas or lakes. The water thus imprisoned is
+firmly inclosed in the interstices of the stone, it in time takes up
+into its mass a certain amount of the mineral materials which are
+contained in the deep-buried rocks. The other portion of the ground
+water--that with which we are now to be specially concerned--arises
+from the rain which descends into the crevices of the earth; it is
+therefore peculiar to the lands. For convenience we shall term the
+original embedded fluid _rock water_, and that which originates from
+the rain _crevice water_, the two forming the mass of the earth water.
+
+The crevice water of the earth, although forming at no time more than
+a very small fraction of the hidden fluid, is an exceedingly potent
+geological agent, doing work which, though unseen, yet affords the
+very foundations on which rest the life alike of land and sea. When
+this water enters the earth, though it is purified of all mineral
+materials, it has already begun to acquire a share of a gaseous
+substance, carbonic acid, or, as chemists now term it, carbon dioxide,
+which enables the fluid to begin its role of marvellous activities. In
+its descent as rain, probably even before it was gathered in drops in
+the cloud realm, the water absorbs a certain portion of this gas from
+the atmosphere. Entering the realm of the soil, where the decaying
+organic matter plentifully gives forth carbon dioxide, a further store
+of the gas is acquired. At the ordinary pressure of the air, water may
+take in many times its bulk of the gas.
+
+The immediate effect of carbonic acid when it is absorbed by water is
+greatly to increase the capacity which that fluid has for taking
+mineral matters into solution. When charged with this gas, in the
+measure in which it may be in the soil, water is able to dissolve
+about fifty times as much limestone as it can in its perfectly pure
+form take up. A familiar instance of this peculiar capacity which the
+gas gives may often be seen where the water from a soda-water fountain
+drips upon the marble slab beneath. In a few years this slab will be
+considerably corroded, though pure water would in the same time have
+had no effect upon it.
+
+The first and by far the most important effect of crevice water is
+exercised upon the soil, which is at once the product of this action,
+and the laboratory where the larger part of the work is done.
+Penetrating between the grains of the detrital covering, held in large
+quantities in the coating, and continually in slow motion, the
+gas-charged water takes a host of substances into solution, and brings
+them into a condition where they may react upon each other in the
+chemical manner. These materials are constantly being offered to the
+roots of plants and brought in contact with the underlying rock which
+has not passed into the state of soil. The changes induced in this
+stony matter lead to its breaking up, or at least to its softening to
+the point where the roots can penetrate it and complete its
+destruction. Thus it comes about that the water which to a great
+extent divides the rocks into the state of soil, which is continually
+wearing away the material on the surface, or leaching it out through
+the springs, is also at work in restoring the layer from beneath.
+
+The greater part of the water which enters the soil does not
+penetrate to any great depth in the underlying rocks, but finds its
+way to the surface after no long journey in the form of small springs.
+Generally those superficial springs do not emerge through distinct
+channels, but move, though slowly, in a massive way down the slopes
+until they enter a water course. Along the banks of any river, however
+small, or along the shores of the sea, a pit a few inches deep just
+above the level of the water will be quickly filled by a flow from
+this sheet which underlies the earth. At a distance from the stream
+this sheet spring is in contact with the bed rocks, and may be many
+feet below the surface, but it comes to the level of the river or the
+sea near their margins. Here and there the shape of the bed rocks,
+being like converging house roofs, causes the superficial springs to
+form small pipelike channels for the escape of their gathered waters,
+and the flow emerges at a definite point. Almost all these sources of
+considerable flow are due to the action of the water on the underlying
+rock, where we shall now follow that portion of the crevice water
+which penetrates deeply into the earth.
+
+Almost all rocks, however firm they may appear to be, are divided by
+crevices which extend from the soil level it may be to the depths of
+thousands of feet. These rents are in part due to the strains of
+mountain-building, which tend to disrupt the firmest stone, leaving
+open fractures. They are also formed in other ways, as by the
+imperfectly understood agencies which produce joint planes. It often
+happens that where rocks are highly tilted water finds its way
+downward between the layers, which are imperfectly soldered together,
+or a bed of coarse material, such as sandstone or conglomerate, may
+afford an easy way by which the water may descend for miles beneath
+the surface. Passing through rocks which are not readily soluble, the
+water, already to a great extent supplied with mineral matter by its
+journey through the soil, may not do much excavating work, and even
+after a long time may only slightly enlarge the spaces in which it
+may be stored or the channels by which it discharges to the surface.
+Hence it comes about that in many countries, even where the waters
+penetrate deeply, they do not afford large springs. It is otherwise
+where the crevice waters enter limestones composed of materials which
+are readily dissolved. In such places we find the rain so readily
+entering the underlying rock that no part of the fall goes at once to
+the brooks, but all has a long underground journey.
+
+In any limestone district where the beds of the material are thick and
+tolerably pure--as, for instance, in the cavern district of southern
+Kentucky--the traveller who enters the region notes at once that the
+usual small streams which in every region of considerable rainfall he
+is accustomed to see intersecting the surface of the country are
+entirely absent. In their place he notes everywhere pitlike
+depressions of bowl-shaped form, the sink holes to which we have
+already adverted. Through the openings in the bottom of these the rain
+waters descend into the depths of the earth. Although the most of
+these depressions have but small openings in their bottom, now and
+then one occurs with a vertical shaft sufficiently large to permit the
+explorer to descend into it, though he needs to be lowered down in the
+manner of a miner who is entering a shaft. In fact, the journey is
+nearly always one of some hazard; it should not be undertaken save
+with many precautions to insure safety.
+
+When one is lowered away through an open sink hole, though the descent
+may at first be somewhat tortuous, the explorer soon finds himself
+swinging freely in the air, it may be at a point some hundred feet
+above the base of the bottle-shaped shaft or dome into which he has
+entered. Commonly the neck of the bottle is formed where the water has
+worked its way through a rather sandy limestone, a rock which was not
+readily dissolved by the water. In the pure and therefore easily cut
+limestone layers the cavity rapidly expands until the light of the
+lantern may not disclose its walls. Farther down there is apt to be a
+shelf composed of another impure limestone, which extends off near the
+middle of the shaft. If the explorer can land upon this shelf, he is
+sure to find that from this imperfect floor the cavern extends off in
+one or more horizontal galleries, which he may follow for a great
+distance until he comes to the point where there is again a well-like
+opening through the hard layer, with another dome-shaped base beneath.
+Returning to the main shaft, the explorer may continue his descent
+until he attains the base of this vertical section of the cave, where
+he is likely to find himself delivered in a pool of water of no great
+depth, the bottom of which is occupied by a quantity of small, hard
+stones of a flinty nature, which have evidently come from the upper
+parts of the cavern. The close observer will have noted that here and
+there in the limestone there are flinty bits, such as those which he
+finds in the pool. From the bottom of the dome a determined inquirer
+can often make his way along the galleries which lead from that level,
+though it may be after a journey of miles to the point where he
+emerges from the cavern on the banks of an open-air river.
+
+Although a journey by way of the sink holes through a cavern system is
+to be commended for the reason that it is the course of the caverning
+waters, it is, on the whole, best to approach the cave through their
+exits along the banks of a stream or through the chance openings which
+are here and there made by the falling in of their roofs. One
+advantage of this cavity of entrance is that we can thus approach the
+cavern in times of heavy rain when the processes which lead to their
+construction are in full activity. Coming in this way to one of the
+domes formed beneath a sink hole, we may observe in rainy weather that
+the water falling down the deep shaft strikes the bottom with great
+force; in many of the Kentucky caves it falls from a greater height
+than Niagara. At such times the stones in the basin at the bottom of
+the shaft are vigorously whirled about, and in their motion they cut
+the rocks in the bottom of the basin--in fact, this cavity is a great
+pot hole, like those at the base of open-air cascades. It is now easy
+to interpret the general principles which determine the architecture
+of the cavern realm.
+
+When it first enters the earth all the work which the water does in
+the initial steps of cavern formation is effected by solution. As the
+crevice enlarges and deepens, the stream acquires velocity, and begins
+to use the bits of hard rock in boring. It works downward in this way
+by the mixed mechanical and chemical action until it encounters a hard
+layer. Then the water creeps horizontally through the soft stratum,
+doing most of its work by solution, until it finds a crevice in the
+floor through which it can excavate farther in the downward direction;
+so it goes on in the manner of steps until it burrows channels to the
+open stream. In time the vertical fall under the sink hole will cut
+through the hard layer, when the water, abandoning the first line of
+exit, will develop another at a lower level, and so in time it comes
+about that there may be several stories of the cave, the lowest being
+the last to be excavated. Of the total work thus done, only a small
+part is accomplished by the falling of the water, acting through the
+boring action of its tools, the bits of stone before mentioned; the
+principal part of the task is done by the solvent action of the
+carbonated waters on the limestone. In the system of caverns known as
+the Mammoth Cave, in Kentucky, the writer has estimated that at least
+nine tenths of the stone was removed in the state of solution.
+
+When first excavated, the chambers of a limestone cavern have little
+beauty to attract the eye. The curves of the walls are sometimes
+graceful, but the aspect of the chambers, though in a measure grand,
+is never charming. When, however, the waters have ceased to carve the
+openings, when they have been drained away by the formation of
+channels on a lower level, there commonly sets in a process known as
+stalactitization, which transforms the scene into one of singular
+beauty. We have already noted the fact that everywhere in ordinary
+rocks there are crevices through which water, moving under the
+pressure of the fluid which is above, may find its way slowly
+downward. In the limestone roofs of caverns, particularly in those of
+the upper story, this ooze of water passes through myriads of unseen
+fissures at a rate so slow that it often evaporates in the dry air
+without dropping to the floor. When it comes out of the rocks the
+water is charged with various salts of lime; when it evaporates it
+leaves the material behind on the roof. Where the outflow is so slight
+that the fluid does not gather into drops, it forms an incrustation of
+limy matter, which often gathers in beautiful flowerlike forms, or
+perhaps in the shape of a sheet of alabaster. Where drops are formed,
+a small, pendent cone grows downward from the ceiling, over which the
+water flows, and on which it evaporates. This cone grows slowly
+downward until it may attain the floor of the chamber, which has a
+height of thirty feet or more. If all the water does not evaporate,
+that which trickles off the apex of the cone, striking on the floor,
+is splashed out into a thin sheet, so that it evaporates in a speedy
+manner, lays down its limestone, and thus builds another and ruder
+cone, which grows upward toward that which is pendent above it.
+Finally, they grow together, enlarged by the process which constructed
+them, until a mighty column may be formed, sculptured as if by the
+hands of a fantastic architect.
+
+[Illustration: Fig. 13.--Stalactites and stalagmites on roof and floor
+of a cavern. The arrows show the direction of the moving water.]
+
+All the while that subterranean streams are cutting the caverns
+downward the open-air rivers into which they discharge are deepening
+their beds, and thereby preparing for the construction of yet lower
+stories of caves. These open-air streams commonly flow in steep-sided,
+narrow valleys, which themselves were caves until the galleries became
+so wide that they could no longer support the roof. Thus we often find
+that for a certain distance the roof over a large stream has fallen
+in, so that the water flows in the open air. Then it will plunge
+under an arch and course, it may be, for some miles, before it again
+arrives at a place where the roof has disappeared, or perhaps attains
+a field occupied by rocks of another character, in which caverns were
+not formed. At places these old river caverns are abandoned by the
+streams, which find other courses. They form natural tunnels, which
+are not infrequently of considerable length. One such in southwestern
+Virginia has been made useful for a railway passing from one valley to
+another, thus sparing the expense of a costly excavation. Where the
+remnant of the arch is small, it is commonly known as a natural
+bridge, of which that in Rockbridge County, in Virginia, is a very
+noble example. Arches of this sort are not uncommon in many cavern
+countries; five such exist in Carter County, Kentucky, a district in
+the eastern part of that State which abounds in caverns, though none
+of them are of conspicuous height or beauty.[7]
+
+[Footnote 7: It is reported that one of these natural bridges of Carter
+County has recently fallen down. This is the natural end of these
+features. As before remarked, they are but the remnants of much more
+extensive roofs which the processes of decay have brought to ruin.]
+
+At this stage of his studies on cavern work the student will readily
+conceive that, as the surface of the country overlying the cave is
+incessantly wearing down, the upper stories of the system are
+continually disappearing, while new ones are forming at the present
+drainage level of the country. In fact, the attentive eye can in such
+a district find here and there evidences of this progressive
+destruction. Not only do the caves wear out from above, but their
+roofs are constantly falling to their floors, a process which is
+greatly aided by the growth of stalactites. Forming in the crevices or
+joints between the stones, these rock growths sometimes prize off
+great blocks. In other cases the weight of the pendent stalactite
+drags the ill-supported masses of the roof to the floor. In this way a
+gallery originally a hundred feet below the surface may work its way
+upward to the light of day. The entrance by which the Mammoth Cave is
+approached appears to have been formed in this manner, and at several
+points in that system of caverns the effect of this action may be
+distinctly observed.
+
+We must now go a step further on the way of subterranean water, and
+trace its action in the depths below the plane of ordinary caves,
+which, as we have noted, do not extend below the level of the main
+streams of the cavern district. The first group of facts to be
+attended to is that exhibited by artesian wells. These occur where
+rocks have been folded down into a basinlike form. It often happens
+that in such a basin the rocks of which it is composed are some of
+them porous, and others impervious to water, and that the porous
+layers outcrop on the high margins of the depression and have
+water-tight layers over them. These conditions can be well represented
+by supposing that we have two saucers, one within the other, with an
+intervening layer of sand which is full of water. If now we bore an
+opening in the bottom of the uppermost saucer, we readily conceive
+that the water will flow up through it. In Nature we often find these
+basins with the equivalent of the sandy layer in the model just
+described rising hundreds of feet above the valley, so that the
+artesian well, so named from the village of Artois, near Paris, where
+the first opening of this nature was made, may yield a stream which
+will mount upward, especially where piped, to a great height. At many
+places in the world it is possible by such wells to obtain a large
+supply of tolerably pure water, but in general it is found to contain
+too large a supply of dissolved mineral matter or sulphuretted gases
+to be satisfactory for domestic purposes. It may be well to note the
+fact that the greater part of the so-called artesian wells, or borings
+which deliver water to a height above the surface, are not true
+artesian sources, in that they do not send up the water by the action
+of gravitation, but under the influence of gaseous pressure.
+
+Where, as in the case of upturned porous beds, the crevice water
+penetrates far below the earth's surface or the open-air streams which
+drain the water away, the fluid acquires a considerable increase of
+temperature, on the average about one degree Fahrenheit for each
+eighty feet of descent. It may, indeed, become so heated that if it
+were at the earth's surface it would not only burst into steam with a
+vast explosive energy, but would actually shine in the manner of
+heated solids. As the temperature of water rises, and as the pressure
+on it increases, it acquires a solvent power, and takes in rocky
+matter in a measure unapproached at the earth's surface. At the depth
+of ten miles water beginning as inert rain would acquire the
+properties which we are accustomed to associate with strong acids.
+Passing downward through fissures or porous strata in the manner
+indicated in the diagram, the water would take up, by virtue of its
+heat and the gases it contained, a share of many mineral substances
+which we commonly regard as insoluble. Gold and even platinum--the
+latter a material which resists all acids at ordinary
+temperatures--enters into the solution. If now the water thus charged
+with mineral stores finds in the depths a shorter way to the surface
+than that which it descended, which may well happen by way of a deep
+rift in the rocks, it will in its ascent reverse the process which it
+followed on going down. It will deposit the several minerals in the
+order of their solubilities--that is, the last to be taken in will be
+the first to be crystallized on the walls of the fissure through which
+the upflow is taking place. The result will be the formation of a vein
+belonging to the variety known as fissure veins.
+
+[Illustration: Fig. 14.--Diagram of vein. The different shadings show
+the variations in the nature of the deposits.]
+
+A vein deposit such as we are considering may, though rarely, be
+composed of a single mineral. Most commonly we find the deposit
+arranged in a banded form in the manner indicated in the figure (see
+diagram 14). Sometimes one material will abound in the lower portions
+of the fissure and another in its higher parts, a feature which is
+accounted for by the progressive cooling and relinquishment of
+pressure to which the water is subjected on its way to the surface.
+With each decrement of those properties some particular substance goes
+out of the fluid, which may in the end emerge in the form of a warm or
+hot spring, the water of which contains but little mineral matter.
+Where, however, the temperature is high, some part of the deposit,
+even a little gold, may be laid down just about the spring in the
+deposits known as sinter, which are often formed at such places.
+
+In many cases the ore deposits are formed not only in the main channel
+of the fissure, but in all the crevices on either side of that way. In
+this manner, much as in the case of the growth of stalactitic matter
+between the blocks of stone in the roofs of a cavern, large fragments
+of rock, known as "horses," are often pushed out into the body of the
+vein. In some instances the growth of the vein appears to enlarge the
+fissure or place of the deposit as the accumulation goes on, the
+process being analogous to that by which a growing root widens the
+crevice into which it has penetrated. In other instances the fissure
+formed by the force has remained wide open, or at most has been but
+partly filled by the action of the water.
+
+It not infrequently happens that the ascending waters of hot springs
+entering limestones have excavated extensive caves far below the
+surface of the earth, these caverns being afterward in part filled by
+the ores of various metals. We can readily imagine that the water at
+one temperature would excavate the cavern, and long afterward, when at
+a lower heat, they might proceed to fill it in. At a yet later stage,
+when the surface of the country had worn down many thousands of feet
+below the original level, the mineral stores of the caverns may be
+brought near the surface of the earth. Some of the most important
+metalliferous deposits of the Cordilleras are found in this group of
+hot-water caverns. These caverns are essentially like those produced
+by cold water, with the exception of the temperature of the fluid
+which does the work and the opposite direction of the flow.
+
+In following crevice water which is free to obey the impulses of
+gravitation far down into the earth, we enter on a realm where the
+rock or construction water, that which was built into the stone at
+the time of its formation, is plentiful. Where these two groups of
+waters come in contact an admixture occurs, a certain portion of the
+rock water joining that in the crevices. Near the surface of the
+ground we commonly find that all the construction water has been
+washed out by this action. Yet if the rocks be compact, or if they
+have layers of a soft and clayey nature, we may find the construction
+water, even in very old deposits, remaining near the surface of the
+ground. Thus in the ancient Silurian beds of the Ohio Valley a boring
+carried a hundred feet below the level of the main rivers commonly
+discovers water which is clearly that laid down in the crevices of the
+material at the time when the rocks were formed in the sea. In all
+cases this water contains a certain amount of gases derived from the
+decomposition of various substances, but principally from the
+alteration of iron pyrite, which affords sulphuretted hydrogen. Thus
+the water is forced to the surface with considerable energy, and the
+well is often named artesian, though it flows by gas pressure on the
+principle of the soda-water fountain, and not by gravity, as in the
+case of true artesian wells.
+
+The passage between the work done by the deeply penetrating surface
+water and that due to the fluid intimately blended with the rock built
+into the mass at the time of its formation is obscure. We are,
+however, quite sure that at great depths beneath the earth the
+construction water acts alone not only in making veins, but in
+bringing about many other momentous changes. At a great depth this
+water becomes intensely heated, and therefore tends to move in any
+direction where a chance fissure or other accident may lessen the
+pressure. Creeping through the rocks, and moving from zones of one
+temperature to another, these waters bring about in the fine
+interstices chemical changes which lead to great alterations in the
+constitution of the rock material. It is probably in part to these
+slow driftings of rock water that beds originally made up of small,
+shapeless fragments, such as compose clay slates, sandstones, and
+limestones, may in time be altered into crystalline rocks, where there
+is no longer a trace of the original bits, all the matter having been
+taken to pieces by the process of dissolving, and reformed in the
+regular crystalline order. In many cases we may note how a crystal
+after being made has been in part dissolved away and replaced by
+another mineral. In fact, many of our rocks appear to have been again
+and again made over by the slow-drifting waters, each particular state
+in their construction being due to some peculiarity of temperature or
+of mineral contents which the fluid held. These metamorphic phenomena,
+though important, are obscure, and their elucidation demands some
+knowledge of petrographic science, that branch of geology which
+considers the principles of rock formation. They will therefore not be
+further considered in this work.
+
+
+                           VOLCANOES.
+
+Of old it was believed that volcanoes represented the outpouring of
+fluid rock which came forth from the central realm of the earth, a
+region which was supposed still to retain the liquid state through
+which the whole mass of our earth has doubtless passed. Recent
+studies, however, have brought about a change in the views of
+geologists which is represented by the fact that we shall treat
+volcanic phenomena in connection with the history of rock water.
+
+In endeavouring to understand the phenomena of volcanoes it is very
+desirable that the student should understand what goes on in a normal
+eruption. The writer may, therefore, be warranted in describing some
+observations which he had an opportunity to make at an eruption of
+Vesuvius in 1883, when it was possible to behold far more than can
+ordinarily be discerned in such outbreaks--in fact, the opportunity of
+a like nature has probably not been enjoyed by any other person
+interested in volcanic action. In the winter of 1882-'83 Vesuvius was
+subjected to a succession of slight outbreaks. At the time of the
+observations about to be noted the crater had been reduced to a cup
+about three hundred feet in diameter and about a hundred feet deep.
+The vertical shaft at the bottom, through which the outbursts were
+taking place, was about a hundred feet across. Taking advantage of a
+heavy gale from the northwest, it was practicable, notwithstanding the
+explosions, to climb to the edge of the crater wall. Looking down into
+the throat of the volcano, although the pit was full of whirling
+vapours and the heat was so great that the protection of a mask was
+necessary, it was possible to see something of what was going on at
+the moment of an explosion.
+
+The pipe of the volcano was full of white-hot lava. Even in a day of
+sunshine, which was only partly obscured by the vapours which hung
+about the opening, the heat of the lava made it very brilliant. This
+mass of fluid rock was in continuous motion, swaying violently up and
+down the tube. From four to six times a minute, at the moment of its
+upswaying, it would burst as by the explosion of a gigantic bubble.
+The upper portion of the mass was blown upward in fragments, the
+discharge being like that of shot from a fowling piece; the fragments,
+varying in size from small, shotlike bits to masses larger than a
+man's head, were shot up sometimes to the height of fifteen hundred
+feet above the point of ejection. The wind, blowing at the rate of
+about forty miles an hour, drove the falling bits of rock to the
+leeward, so that there was no considerable danger to be apprehended
+from them. Some seconds after the explosion they could be heard
+rattling down on the farther slope of the cone. Observations on the
+interval between the discharge and the fall of the fragments made it
+easy to compute the height to which they were thrown.
+
+At the moment when the lava in the pipe opened for the passage of the
+vapour which created the explosion the movement, though performed in
+a fraction of a second, was clearly visible. At first the vapour was
+colourless; a few score feet up it began to assume a faint, bluish
+hue; yet higher, when it was more expanded, the tint changed to that
+of steam, which soon became of the ordinary aspect, and gathered in
+swift-revolving clouds. The watery nature of the vapour was perfectly
+evident by its odour. Though commingled with sulphurous-acid gas, it
+still had the characteristic smell of steam. For a half hour it was
+possible to watch the successive explosions, and even to make rough
+sketches of the scene. Occasionally the explosions would come in quick
+succession, so that the lava was blown out of the tube; again, the
+pool would merely sway up and down in a manner which could be
+explained only by supposing that great bubbles of vapour were working
+their way upward toward the point where they could burst. Each of
+these bubbles probably filled a large part of the diameter of the
+pipe. In general, the phenomena recalled the escape of the jet from a
+geyser, or, to take a familiar instance, that of steam from the pipe
+of a high-pressure engine. When the heat is great, steam may often be
+seen at the mouth of the pipe with the same transparent appearance
+which was observed in the throat of the crater. In the cold air of the
+mountain the vapour was rapidly condensed, giving a rainbow hue in the
+clouds when they were viewed at the right angle. The observations were
+interrupted by the fact that the wind so far died away that large
+balls of the ejected lava began to fall on the windward side of the
+cone. These fragments, though cooled and blackened on their outside by
+their considerable journey up and down through the air, were still so
+soft that they splashed when they struck the surface of cinders.
+
+Watching the cone from a distance, one could note that from time to
+time the explosions, increasing in frequency, finally attained a point
+where the action appeared to be continuous. The transition was
+comparable to that which we may observe in a locomotive which, when it
+first gets under way, gives forth occasional jets of steam, but,
+slowly gaining speed, finally pours forth what to eye and ear alike
+seem to be a continuous outrush. All the evidence that we have
+concerning volcanic outbreaks corroborates that just cited, and is to
+the effect that the essence of the action consists in the outbreak of
+water vapour at a high temperature, and therefore endowed with very
+great expansive force. Along with this steam there are many other
+gases, which always appear to be but a very small part of the whole
+escape of a vaporous nature--in fact, the volcanic steam, so far as
+its chemical composition has been ascertained, has the composition
+which we should expect to find in rock water which had been forced out
+from the rock by the tensions that high temperature creates.
+
+Because of its conspicuous nature, the lava which flows from most
+volcanoes, or is blown out from them in the form of finely divided
+ash, is commonly regarded as the primary feature in a volcanic
+outbreak. Such is not really the case. Volcanic explosions may occur
+with very little output of fluid rock, and that which comes forth may
+consist altogether of the finely divided bits of rock to which we give
+the name of ash. In fact, in all very powerful explosions we may
+expect to find no lava flow, but great quantities of this finely
+divided rock, which when it started from the depths of the earth was
+in a fluid state, but was blown to pieces by the contained vapour as
+it approached the surface.
+
+If the student is so fortunate as to behold a flood of lava coming
+forth from the flanks of a volcano, he will observe that even at the
+very points of issue, where the material is white-hot and appears to
+be as fluid as water, the whole surface gives forth steam. On a still
+day, viewed from a distance, the path of a lava flow is marked by a
+dense cloud of this vapour which comes forth from it. Even after the
+lava has cooled so that it is safe to walk upon it, every crevice
+continues to pour forth steam. Years after the flowing has ceased, and
+when the rock surface has become cool enough for the growth of
+certain plants upon it, these crevices still yield steam. It is
+evident, in a word, that a considerable part of a lava mass, even
+after it escapes from the volcanic pipes, is water which is intimately
+commingled with the rock, probably lying between the very finest
+grains of the heated substance. Yet this lava which has come forth
+from the volcano has only a portion of the water which it originally
+contained; a large, perhaps the greater part, has gone forth in the
+explosive way through the crater. It is reasonably believed that the
+fluidity of lava is in considerable measure due to the water which it
+contains, and which serves to give the mass the consistence of paste,
+the partial fluidity of flour and rock grains being alike brought
+about in the same manner.
+
+So much of the phenomena of volcanoes as has been above noted is
+intended to show the large part which interstitial water plays in
+volcanic action. We shall now turn our attention again to the state of
+the deeply buried rock water, to see how far we may be able by it to
+account for these strange explosive actions. When sediments are laid
+down on the sea floor the materials consist of small, irregularly
+shaped fragments, which lie tumbled together in the manner of a mass
+of bricks which have been shot out of a cart. Water is buried in the
+plentiful interspaces between these bits of stone; as before remarked,
+the amount of this construction water varies. In general, it is at
+first not far from one tenth part of the materials. Besides the fluid
+contained in the distinct spaces, there is a share which is held as
+combined water in the intimate structure of the crystals, if such
+there be in the mass. When this water is built into the stone it has
+the ordinary temperature of the sea bottom. As the depositing actions
+continue to work, other beds are formed on the top of that which we
+are considering, and in time the layer may be buried to the depth of
+many thousand feet. There are reasons to believe that on the floors of
+the oceans this burial of beds containing water may have brought great
+quantities of fluid to the depth of twenty miles or more below the
+outer surface of the rocks.
+
+[Illustration: Fig. 15.--Flow of lava invading a forest. A tree in the
+distance is not completely burned, showing that the molten rock had
+lost much of its original heat.]
+
+The effect of deep burial is to increase the heat of strata. This
+result is accomplished in two different ways. The direct effect
+arising from the imposition of weight, that derived from the mass of
+stratified material, is, as we know, to bring about a down-sinking of
+the earth's crust. In the measure of this falling, heat is engendered
+precisely as it is by the falling of a trip-hammer on the anvil, with
+which action, as is well known, we may heat an iron bar to a high
+temperature. It is true that this down-sinking of the surface under
+weight is in part due to the compression of the rocks, and in part to
+the slipping away of the soft underpinning of more or less fluid rock.
+Yet further it is in some measure brought about by the wrinkling of
+the crust. But all these actions result in the conversion of energy of
+position into heat, and so far serve to raise the temperature of the
+rocks which are concerned in the movements. By far the largest source
+of heat, however, is that which comes forth from the earth's interior,
+and which was stored there in the olden day when the matter forming
+the earth gathered into the mass of our sphere. This, which we may
+term the original heat, is constantly flowing forth into space, but
+makes its way slowly, because of the non-conductive, or, as we may
+phrase it, the "blanketing" effect of the outer rock. The effect of
+the strata is the same as that exercised by the non-conductive
+coatings which are put on steam boilers. A more familiar comparison
+may be had from the blankets used for bedclothing. If on top of the
+first blanket we put a second, we keep warmer because the temperature
+of the lower one is elevated by the heat from our body which is held
+in. In the crust of the earth each layer of rock resists the outflow
+of heat, and each addition lifts the temperature of all the layers
+below.
+
+When water-bearing strata have been buried to the depth of ten miles,
+the temperature of the mass may be expected to rise to somewhere
+between seven hundred and a thousand degrees Fahrenheit. If the depth
+attained should be fifty miles, it is likely that the temperature will
+be five times as great. At such a heat the water which the rocks
+contain tends in a very vigorous way to expand and pass into the state
+of vapour. This it can not readily do, because of its close
+imprisonment; we may say, however, that the tendency toward explosion
+is almost as great as that of ignited gunpowder. Such powder, if held
+in small spaces in a mass of cast steel, could be fired without
+rending the metal. The gases would be retained in a highly compressed,
+possibly in a fluid form. If now it happens that any of the strain in
+the rocks such as lead to the production of faults produce fissures
+leading from the surface into this zone of heated water, the tendency
+of the rocks containing the fluid, impelled by its expansion, will be
+to move with great energy toward the point of relief or lessened
+pressure which the crevice affords. Where rocks are in any way
+softened, pressure alone will force them into a cavity, as is shown by
+the fact that beds of tolerably hard clay stones in deep coal mines
+may be forced into the spaces by the pressure of the rocks which
+overlie them--in fact, the expense of cutting out these in-creeping
+rocks is in some British mines a serious item in the cost of the
+product.
+
+The expansion of the water contained in the deep-lying heated rocks
+probably is by far the most efficient agent in urging them toward the
+plane of escape which the fissure affords. When the motion begins it
+pervades all parts of the rock at once, so that an actual flow is
+induced. So far as the movement is due to the superincumbent weight,
+the tendency is at once to increase the temperature of the moving
+mass. The result is that it may be urged into the fissure perhaps even
+hotter than when it started from the original bed place. In proportion
+as the rocky matter wins its way toward the surface, the pressure upon
+it diminishes, and the contained vapours are freer to expand. Taking
+on the vaporous form, the bubbles gather to each other, and when they
+appear at the throat of the volcano they may, if the explosions be
+infrequent, assume the character above noted in the little eruption of
+Vesuvius. Where, however, the lava ascends rapidly through the
+channel, it often attains the open air with so much vapour in it, and
+this intimately mingled with the mass, that the explosion rends the
+materials into an impalpably fine powder, which may float in the air
+for months before it falls to the earth. With a less violent movement
+the vapour bubbles expand in the lava, but do not rend it apart, thus
+forming the porous, spongy rock known as pumice. With a yet slower
+ascent a large part of the steam may go away, so that we may have a
+flow of lava welling forth from the vent, still giving forth steam,
+but with a vapour whose tension is so lowered that the matter is not
+blown apart, though it may boil violently for a time after it escapes
+into the air.
+
+Although the foregoing relatively simple explanation of volcanic
+action can not be said as yet to be generally accepted by geologists,
+the reasons are sufficient which lead us to believe that it accounts
+for the main features which we observe in this class of explosions--in
+other words, it is a good working hypothesis. We shall now proceed in
+the manner which should be followed in all natural inquiry to see if
+the facts shown in the distribution of volcanoes in space and time
+confirm or deny the view.
+
+The most noteworthy feature in the distribution of volcanoes is that,
+at the present time at least, all active vents are limited to the sea
+floors or to the shore lands within the narrow range of three hundred
+miles from the coast. Wherever we find a coast line destitute of
+volcanoes, as is the case with the eastern coast of North and South
+America, it appears that the shore has recently been carried into the
+land for a considerable distance--in other words, old coast lines are
+normally volcanic; that is, here and there have vents of this nature.
+Thus the North Atlantic, the coasts of which appear to have gone
+inland for a great distance in geologically recent times, is
+non-volcanic; while the Pacific coast, which for a long time has
+remained in its present position, has a singularly continuous line of
+craters near the shore extending from Alaska to Tierra del Fuego. So
+uninterrupted is this line of volcanoes that if they were all in
+eruption it would very likely be possible to journey down the coast
+without ever being out of sight of the columns of vapour which they
+would send forth. On the floor of the sea volcanic peaks appear to be
+very widely distributed; only a few of them--those which attain the
+surface of the water--are really known, but soundings show long lines
+of elevations which doubtless represent cones distributed along fault
+lines, none of the peaks of sufficient height to break the surface of
+the sea. It is likely, indeed, that for one marine volcano which
+appears as an island there are scores which do not attain the surface.
+Volcanic islands exist and generally abound in the ocean and greater
+seas; every now and then we observe a new one forming as a small
+island, which is apt to be washed away by the sea shortly after the
+eruption ceases, the disappearance being speedy, for the reason that
+the volcanic ashes of which these cones are composed drift away like
+snow before the movement of the waves.
+
+If the waters of the ocean and seas were drained away so that we could
+inspect the portion of the earth's surface which they cover as readily
+as we do the dry lands, the most conspicuous feature would be the
+innumerable volcanic eminences which lie hidden in these watery
+realms. Wherever the observer passed from the centres of the present
+lands he would note within the limits of those fields only mountains,
+much modified by river action; hills which the rivers had left in
+scarfing away the strata; and dales which had been carved out by the
+flowing waters. Near the shore lines of the vanished seas he would
+begin to find mountains, hills, and vales occasionally commingled with
+volcanic peaks, those structures built from the materials ejected from
+the vents. Passing the coast line to the seaward, the hills and dales
+would quickly disappear, and before long the mountains would vanish
+from his way, and he would gradually enter on a region of vast rolling
+plains beset by volcanic peaks, generally accumulated in long ranges,
+somewhat after the manner of mountains, but differing from those
+elevations not only in origin but in aspect, the volcanic set of peaks
+being altogether made up of conical, cup-topped elevations.
+
+A little consideration will show us that the fact of volcanoes being
+in the limit to the sea floors and to a narrow fringe of shore next
+certain ocean borders is reconcilable with the view as to their
+formation which we have adopted. We have already noted the fact that
+the continents are old, which implies that the parts of the earth
+which they occupy have long been the seats of tolerably continuous
+erosion. Now and then they have swung down partly beneath the sea, and
+during their submersion they received a share of sediments. But, on
+the whole, all parts of the lands except strips next the coast may be
+reckoned as having been subjected to an excess of wearing action far
+exceeding the depositional work. Therefore, as we readily see,
+underneath such land areas there has been no blanketing process going
+on which has served to increase the heat in the deep underlying rocks.
+On the contrary, it would be easy to show, and the reader may see it
+himself, that the progressive cooling of the earth has probably
+brought about a lowering of the temperature in all the section from
+the surface to very great depths, so that not only is the rock water
+unaffected by increase of heat, but may be actually losing
+temperature. In other words, the conditions which we assume bring
+about volcanic action do not exist beneath the old land.
+
+Beneath the seas, except in their very greatest depths, and perhaps
+even there, the process of forming strata is continually going on.
+Next the shores, sometimes for a hundred or two miles away to seaward,
+the principal contribution may be the sediment worn from the lands by
+the waves and the rivers. Farther away it is to a large extent made up
+of the remains of animals and plants, which when dying give their
+skeletons to form the strata. Much of the materials laid down--perhaps
+in all more than half--consist of volcanic dust, ashes, and pumice,
+which drifts very long times before it finds its way to the bottom. We
+have as yet no data of a precise kind for determining the average rate
+of accumulation of sediments upon the sea floor, but from what is
+known of the wearing of the lands, and the amount of volcanic waste
+which finds its way to the seas, it is probably not less than about a
+foot in ten thousand years; it is most likely, indeed, much to exceed
+this amount. From data afforded by the eruptions in Java and in other
+fields where the quantity of volcanic dust contributed to the seas can
+be estimated, the writer is disposed to believe that the average rate
+of sedimentation on the sea floors is twice as great as the estimate
+above given.
+
+Accumulating at the average rate of one foot in ten thousand years, it
+would require a million years to produce a hundred feet of sediments;
+a hundred million to form ten thousand feet, and five hundred million
+to create the thickness of about ten miles of bed. At the rate of two
+feet in ten thousand years, the thickness accumulated would be about
+twenty miles. When we come to consider the duration of the earth's
+geologic history, we shall find reasons for believing that the
+formation of sediment may have continued for as much as five hundred
+million years.
+
+The foregoing inquiries concerning the origin of volcanoes show that
+at the present time they are clearly connected with some process which
+goes on beneath the sea. An extension of the inquiry indicates that
+this relation has existed in earlier geological times; for, although
+the living volcanoes are limited to places within three hundred miles
+of the sea, we find lava flows, ashes, and other volcanic
+accumulations far in the interior of the continents, though the energy
+which brought them forth to the earth's surface has ceased to operate
+in those parts of the land. In these cases of continental volcanoes it
+generally, if not always, appears that the cessation of the activity
+attended the removal of the shore line of the ocean or the
+disappearance of great inland seas. Thus the volcanoes of the
+Yellowstone district may have owed their activity to the immense
+deposits of sediment which were formed in the vast fresh-water lakes
+which during the later Cretaceous and early Tertiary times stretched
+along the eastern face of the Rocky Mountains, forming a Mediterranean
+Sea in North America comparable to that which borders southern Europe.
+It thus appears that the arrangement of volcanoes with reference to
+sea basins has held for a considerable period in the past. Still
+further, when we look backward through the successive formations of
+the earth's crust we find here and there evidences in old lava flows,
+in volcanic ashes, and sometimes in the ruins of ancient cones which
+have been buried in the strata, that igneous activity such as is now
+displayed in our volcanoes has been, since the earliest days of which
+we have any record, a characteristic feature of the earth. There is no
+reason to suppose that this action has in the past been any greater or
+any less than in modern days. All these facts point to the conclusion
+that volcanic action is due to the escape of rock water which has been
+heated to high temperatures, and which drives along with it as it
+journeys toward a crevice the rock in which it has been confined.
+
+We will now notice some other explanations of volcanic action which
+have obtained a certain credence. First, we may note the view that
+these ejections from craters are forced out from a supposed liquid
+interior of the earth. One of the difficulties of this view is that we
+do not know that the earth's central parts are fluid--in fact, many
+considerations indicate that such is not the case. Next, we observe
+that we not infrequently find two craters, each containing fluid lava,
+with the fluid standing at differences of height of several thousand
+feet, although the cones are situated very near each other. If these
+lavas came from a common internal reservoir, the principles which
+control the action of fluids would cause the lavas to be at the same
+elevation. Moreover, this view does not provide any explanation of the
+fact that volcanoes are in some way connected with actions which go on
+on the floors of great water basins. There is every reason to believe
+that the fractures in the rocks under the land are as numerous and
+deep-going as those beneath the sea. If it were a mere question of
+access to a fluid interior, volcanoes should be equally distributed on
+land and sea floors. Last of all, this explanation in no wise accounts
+for the intermixture of water with the fluid rock. We can not well
+believe that water could have formed a part of the deeper earth in the
+old days of original igneous fusion. In that time the water must have
+been all above the earth in the vaporous state.
+
+Another supposition somewhat akin to that mentioned is that the water
+of the seas finds its way down through crevices beneath the floors of
+the ocean, and, there coming in contact with an internal molten mass,
+is converted into steam, which, along with the fluid rock, escapes
+from the volcanic vent. In addition to the objections urged to the
+preceding view, we may say concerning this that the lava, if it came
+forth under these circumstances, would emerge by the short way, that
+by which the water went down, and not by the longer road, by which it
+may be discharged ten thousand feet or more above the level of the
+sea.
+
+The foregoing general account of volcanic action should properly be
+followed by some account of what takes place in characteristic
+eruptions. This history of these matters is so ample that it would
+require the space of a great encyclopaedia to contain them. We shall
+therefore be able to make only certain selections which may serve to
+illustrate the more important facts.
+
+By far the best-known volcanic cone is that of Vesuvius, which has
+been subjected to tolerably complete record for about twenty-four
+hundred years. About 500 B.C. the Greeks, who were ever on the search
+for places where they might advantageously plant colonies, settled on
+the island of Ischia, which forms the western of what is now termed
+the Bay of Naples. This island was well placed for tillage as well as
+for commerce, but the enterprising colonists were again and again
+disturbed by violent outbreaks of one or more volcanoes which lie in
+the interior of this island; at one time it appears that the people
+were driven away by these explosions.
+
+In these pre-Christian days Vesuvius, then known as Monte Somma, was
+not known to be a volcano, it never having shown any trace of
+eruption. It appeared as a regularly shaped mountain, somewhat over
+two thousand feet high, with a central depression about three miles in
+diameter at the top, and perhaps two miles over at the bottom, which
+was plainlike in form, with some lakes of bitter water in the centre.
+The most we know of this central cavity is connected with the
+insurrection of the slaves led by Spartacus, the army of the revolters
+having camped for a time on the plain encircled by the crater walls.
+The outer slopes of the mountain afforded then a remarkably fertile
+soil; some traces, indeed, of the fertility have withstood the modern
+eruptions which have desolated its flanks. This wonderful Bay of
+Naples became the seat of the fairest Roman culture, as well as of a
+very extended commerce. Toward the close of the first century of our
+era the region was perhaps richer, more beautifully cultivated, and
+the seat of a more elaborate luxury than any part of the shore line of
+Europe at the present day. At the foot of the mountain, on the eastern
+border of the bay, the city of Pompeii, with a population of about
+fifty thousand souls, was a considerable port, with an extensive
+commerce, particularly with Egypt. The charming town was also a place
+of great resort for rich Egyptians who cared to dwell in Europe. On
+the flanks of the mountain there was at least one large town,
+Herculaneum, which appears to have been an association of rich men's
+residences. On the eastern side of the bay, at a point now known as
+Baiae, the Roman Government had a naval station, which in the year 79
+was under the command of the celebrated Pliny, a most voluminous
+though unscientific writer on matters of natural history. With him in
+that year there was his nephew, commonly known as the younger Pliny,
+then a student of eighteen years, but afterward himself an author.
+These facts are stated in some detail, for they are all involved in
+the great tragedy which we are now to describe.
+
+For many years there had been no eruption about the Bay of Naples. The
+volcanoes on Ischia had been still for a century or more, and the
+various circular openings on the mainland had been so far quiet that
+they were not recognised as volcanoes. Even the inquisitive Pliny,
+with his great learning, was so little of a geologist that he did not
+know the signs which indicate the seat of volcanic action, though they
+are among the most conspicuous features which can meet the eye. The
+Greeks would doubtless have recognised the meaning of these physical
+signs. In the year 63 the shores of the Bay of Naples were subjected
+to a distinctive earthquake. Others less severe followed in subsequent
+years. In an early morning in the year 79, a servant aroused the elder
+Pliny at Baiae with the news that there was a wonderful cloud rising
+from Monte Somma. The younger Pliny states that in form it was like a
+pine tree, the common species in Italy having a long trunk with a
+crown of foliage on its summit, shaped like an umbrella. This crown of
+the column grew until it spread over the whole landscape, darkening
+the field of view. Shortly after, a despatch boat brought a message to
+the admiral, who at once set forth for the seat of the disturbance. He
+invited his nephew to accompany him, but the prudent young man relates
+in his letters to Tacitus, from whom we know the little concerning the
+eruption which has come down to us, that he preferred to do some
+reading which he had to attend to. His uncle, however, went straight
+forward, intending to land at some point on the shore at the foot of
+the cone. He found the sea, however, so high that a landing was
+impossible; moreover, the fall of rock fragments menaced the ship. He
+therefore cruised along the shore for some distance, landing at a
+station probably near the present village of Castellamare. At this
+point the fall of ashes and pumice was very great, but the sturdy old
+Roman had his dinner and slept after it. There is testimony that he
+snored loudly, and was aroused only when his servants began to fear
+that the fall of ashes and stones would block the way out of his
+bedchamber. When he came forth with his attendants, their heads
+protected by planks resting on pillows, he set out toward Pompeii,
+which was probably the place where he sought to land. After going some
+distance, the brave man fell dead, probably from heart disease; it is
+said that he was at the time exceedingly asthmatic. No sooner were his
+servants satisfied that the life had passed from his body than they
+fled. The remains were recovered after the eruption had ceased. The
+younger Pliny further relates that after his uncle left, the cloud
+from the mountain became so dense that in midday the darkness was that
+of midnight, and the earthquake shocks were so violent that wagons
+brought to the courtyard of the dwelling to bear the members of the
+household away were rolled this way and that by the quakings of the
+earth.
+
+Save for the above-mentioned few and unimportant details concerning
+the eruption, we have no other contemporaneous account. We have,
+indeed, no more extended story until Dion Cassius, writing long after
+the event, tells us that Herculaneum and Pompeii were overwhelmed; but
+he mixes his story with fantastic legends concerning the appearance of
+gods and demons, as is his fashion in his so-called history. Of all
+the Roman writers, he is perhaps the most untrustworthy. Fortunately,
+however, we have in the deposits of ashes which were thrown out at the
+time of this great eruption some basis for interpreting the events
+which took place. It is evident that for many hours the Vesuvian
+crater, which had been dormant for at least five hundred years, blew
+out with exceeding fury. It poured forth no lava streams; the energy
+of the uprushing vapours was too great for that. The molten rock in
+their path was blown into fine bits, and all the hard material cast
+forth as free dust. In the course of the eruption, which probably did
+not endure more than two days, possibly not more than twenty-four
+hours, ash enough was poured forth to form a thick layer which spread
+far over the neighbouring area of land and sea floor. It covered the
+cities of Herculaneum and Pompeii to a depth of more than twenty feet,
+and over a circle having a diameter of twenty miles the average
+thickness may have been something like this amount. So deep was it
+that, although almost all the people of these towns survived, it did
+not seem to them worth while to undertake to excavate their dwelling
+places. At Pompeii the covering did not overtop the higher of the low
+houses. An amount of labour which may be estimated at not over one
+thirtieth of the value, or at least the cost which had been incurred
+in building the city, would have restored it to a perfectly
+inhabitable state. The fact that it was utterly abandoned probably
+indicates a certain superstitious view in connection with the
+eruption.
+
+The fact that the people had time to flee from Herculaneum and
+Pompeii, bearing with them their more valuable effects, is proved by
+the excavations at these places which have been made in modern times.
+The larger part of Pompeii and a considerable portion of Herculaneum
+have been thus explored; only rarely have human remains been found.
+Here and there, particularly in the cellars, the labourers engaged in
+the work of disinterring the cities note that their picks enter a
+cavity; examining the space, they find they have discovered the
+remains of a human skeleton. It has recently been learned that by
+pouring soft plaster of Paris into these openings a mould may be
+obtained which gives in a surprisingly perfect manner the original
+form of the body. The explanation of this mould is as follows: Along
+with the fall of cinders in an eruption there is always a great
+descent of rain, arising from the condensation of the steam which
+pours forth from the volcano. This water, mingling with the ashes,
+forms a pasty mud, which often flows in vast streams, and is
+sometimes known as mud lava. This material has the qualities of
+cement--that is, it shortly "sets" in a manner comparable to plaster
+of Paris or ordinary mortar. During the eruption of 79 this mud
+penetrated all the low places in Pompeii, covering the bodies of the
+people, who were suffocated by the fumes of the volcanic emanations.
+We know that these people were not drowned by the inundation; their
+attitudes show that they were dead before the flowing matter
+penetrated to where they lay.
+
+It happened that Pompeii lay beyond the influence of the subsequent
+great eruptions of Vesuvius, so that it afterward received only slight
+ash showers. Herculaneum, on the other hand, has century by century
+been more and more deeply buried until at the present time it is
+covered by many sheets of lava. This is particularly to be regretted,
+for the reason that, while Pompeii was a seaport town of no great
+wealth or culture, Herculaneum was the residence place of the gentry,
+people who possessed libraries, the records of which can be in many
+cases deciphered, and from which we might hope to obtain some of the
+lost treasures of antiquity. The papyrus rolls on which the books of
+that day were written, though charred by heat and time, are still
+interpretable.
+
+After the great explosion of 79, Vesuvius sank again into repose. It
+was not until 1056 that vigorous eruptions again began. From time to
+time slight explosions occurred, none of which yielded lava flows; it
+was not until the date last mentioned that this accompaniment of the
+eruption began to appear. In 1636, after a repose of nearly a century
+and a half, there came a very great outbreak, which desolated a wide
+extent of country on the northwestern side of the cone. At this stage
+in the history of the crater the volcanic flow began to attain the
+sea. Washing over the edge of the old original crater of Monte Somma,
+and thus lowering its elevation, these streams devastated, during the
+eruption just mentioned and in various other outbreaks, a wide field
+of cultivated land, overwhelming many villages. The last considerable
+eruption which yielded large quantities of lava was that of 1872,
+which sent its tide for a distance of about six miles.
+
+Since 1636 the eruptions of Vesuvius have steadily increased in
+frequency, and, on the whole, diminished in violence. In the early
+years of its history the great outbreaks were usually separated by
+intervals of a century or more, and were of such energy that the lava
+was mostly blown to dust, forming clouds so vast that on two occasions
+at least they caused a midnight darkness at Constantinople, nearly
+twelve hundred miles away. This is as if a volcano at Chicago should
+completely hide the sun in the city of Boston. In the present state of
+Vesuvius, the cone may be said to be in slight, almost continuous
+eruption. The old central valley which existed before the eruption of
+79, and continued to be distinct for long after that time, has been
+filled up by a smaller cone, bearing a relatively tiny crater of vent,
+the original wall being visible only on the eastern and northern parts
+of its circuit, and here only with much diminished height. On the
+western face the slope from the base of the mountain to the summit of
+the new cone is almost continuous, though the trained eye can trace
+the outline of Monte Somma--its position in a kind of bench, which is
+traceable on that side of the long slope leading from the summit of
+the new cone to the sea. The fact that the lavas of Vesuvius have
+broken out on the southwestern side, while the old wall of the cone
+has remained unbroken on the eastern versant, has a curious
+explanation. The prevailing wind of Naples is from the southwest,
+being the strong counter trades which belong in that latitude. In the
+old days when the Monte Somma cone was constructed these winds caused
+the larger part of the ashes to fall on the leeward side of the cone,
+thus forming a thicker and higher wall around that part of the crater.
+
+From the nature of the recent eruptions of Vesuvius it appears likely
+that the mountain is about to enter on a second period of inaction.
+The pipes leading through the new cone are small, and the mass of this
+elevation constitutes a great plug, closing the old crater mouth. To
+give vent to a large discharge of steam, the whole of this great mass,
+having a depth of nearly two thousand feet, would have to be blown
+away. It seems most likely that when the occasion for such a discharge
+comes, the vapours of the eruption will seek a vent through some other
+of the many volcanic openings which lie to the westward of this great
+cone. The history of these lesser volcanoes points to the conclusion
+that when the path by way of Vesuvius is obstructed they may give
+relief to the steam which is forcing its course to the surface. Two or
+three times since the eruption of Pliny, during periods when Vesuvius
+had long been quiet, outbreaks have taken place on Ischia or in the
+Phlaegraen Fields, a region dotted with small craters which lies to the
+west of Naples. The last of these occurred in 1552, and led to the
+formation of the beautiful little cone known as Monte Nuovo. This
+eruption took place near the town of Puzzuoli, a place which was then
+the seat of a university, the people of which have left us records of
+the accident.
+
+[Illustration: Fig. 16.--Diagrammatic sections through Mount Vesuvius,
+showing changes in the form of the cone. (From Phillips.)]
+
+The outbreak which formed Monte Nuovo was slight but very
+characteristic. It occurred in and beside a circular pool known as the
+Lucrine Lake, itself an ancient crater. At the beginning of the
+disturbance the ground opened in ragged cavities, from which mud and
+ashes and great fragments of hard rock were hurled high in the air,
+some of the stones ascending to a height of several thousand feet.
+With slight intermissions this outbreak continued for some days,
+resulting in the formation of a hill about five hundred feet high,
+with a crater in its top, the bottom of which lay near the level of
+the sea. Although this volcanic elevation, being made altogether of
+loose fragments, is rapidly wearing down, while the crater is filling
+up, it remains a beautiful object in the landscape, and is also
+noteworthy for the fact that it is the only structure of this nature
+which we know from its beginning. In the Phlaegraen Field there are a
+number of other craters of small size, with very low cones about them.
+These appear to have been the product of brief, slight eruptions. That
+known as the Solfatara, though not in eruption during the historic
+period, is interesting for the fact that from the crevices of the
+rocks about it there comes forth a continued efflux of carbonic-acid
+gas. This substance probably arises from the effect of heat contained
+in old lavas which are in contact with limestone in the deep
+under-earth. We know such limestones are covered by the lavas of
+Vesuvius, for the reason that numerous blocks of the rock are thrown
+out during eruptions, and are often found embedded in the lava
+streams. It is an interesting fact that these craters of the
+Phlaegraen Field, lying between the seats of vigorous eruption on
+Ischia and at Vesuvius, have never been in vigorous eruption. Their
+slight outbreaks seem to indicate that they have no permanent
+connection with the sources whence those stronger vents obtain their
+supply of heated steam.
+
+The facts disclosed by the study of the Vesuvian system of volcanoes
+afford the geologist a basis for many interesting conclusions.
+
+In the first place, he notes that the greater part of the cones, all
+those of small size, are made up of finely divided rock, which may
+have been more or less cemented by the processes of change which
+go on within it. It is thus clear that the lava flows are
+unessential--indeed, we may say accidental--contributions to the mass.
+In the case of Vesuvius they certainly do not amount to as much as one
+tenth of the elevation due to the volcanic action. The share of the
+lava in Vesuvius is probably greater than the average, for during the
+last six centuries this vent has been remarkably lavigerous.[8]
+Observation on the volcanoes of other districts show that the Vesuvian
+group is in this regard not peculiar. Of nearly two hundred cones
+which the writer has examined, not more than one tenth disclose
+distinct lavas.
+
+[Footnote 8: I venture to use this word in place of the phrase
+"lava-yielding" for the reason that the term is needed in the
+description of volcanoes.]
+
+An inspection of the old inner wall of Monte Somma in that portion
+where it is best preserved, on the north side of the Atria del
+Cavallo, or Horse Gulch--so called for the reason that those who
+ascended Vesuvius were accustomed to leave their saddle animals
+there--we perceive that the body of the old cone is to a considerable
+extent interlaced with dikes or fissures which have been filled with
+molten lava that has cooled in its place. It is evident that during
+the throes of an eruption, when the lava stands high in the crater,
+these rents are frequently formed, to be filled by the fluid rock. In
+fact, lava discharges, though they may afterward course for long
+distances in the open air, generally break their way underground
+through the cindery cone, and first are disclosed at the distance of a
+mile or more from the inner walls of the crater. Their path is
+probably formed by riftings in the compacted ashes, such as we trace
+on the steep sides of the Atria del Cavallo, as before noted. For the
+further history of these fissures, we shall have to refer to facts
+which are better exhibited in the cone of AEtna.
+
+The amount of rock matter which has been thrown forth from the
+volcanoes about the Bay of Naples is very great. Only a portion of it
+remains in the region around these cones; by far the greater part has
+been washed or blown away. After each considerable eruption a wide
+field is coated with ashes, so that the tilled grounds appear as if
+entirely sterilized; but in a short time the matter in good part
+disappears, a portion of it decays and is leached away, and the most
+of the remainder washes into the sea. Only the showers, which
+accumulate a deep layer, are apt to be retained on the surface of the
+country. A great deal of this powdered rock drifts away in the wind,
+sometimes in great quantities, as in those cases where it darkened the
+sky more than a thousand miles from the cone. Moreover, the water of
+the steam which brought about the discharges and the other gases which
+accompanied the vapour have left no traces of their presence, except
+in the deep channels which the rain of the condensing steam have
+formed on the hillsides. Nevertheless, after all these subtractions
+are made, the quantity of volcanic matter remaining on the surface
+about the Bay of Naples would, if evenly distributed, form a layer
+several hundred feet in thickness--perhaps, indeed, a thousand feet in
+depth--over the territory in which the vents occur. All this matter
+has been taken in relatively recent times from the depths of the
+earth. The surprising fact is that no considerable and, indeed, no
+permanent subsidence of the surface has attended this excavation. We
+can not believe that this withdrawal of material from the under-earth
+has resulted in the formation of open underground spaces. We know full
+well that any such, if it were of considerable size, would quickly be
+crushed in by the weight of the overlying rocks. We have, indeed, to
+suppose that these steam-impelled lavas, which are driven toward the
+vent whence they are to go forth in the state of dust or fluid, come
+underground from distances away, probably from beneath the floors of
+the sea to the westward.
+
+Although the shores of the Bay of Naples have remained in general with
+unchanged elevation for about two thousand years, they have here and
+there been subjected to slight oscillations which are most likely
+connected with the movement of volcanic matter toward the vents where
+it is to find escape. The most interesting evidence of this nature is
+afforded by the studies which have been made on the ruins of the
+Temple of Serapis at Puzzuoli. This edifice was constructed in
+pre-Christian times for the worship of the Egyptian god Serapis, whose
+intervention was sought by sick people. The fact that this divinity of
+the Nile found a residence in this region shows how intimate was the
+relation between Rome and Egypt in this ancient day. The Serapeium was
+built on the edge of the sea, just above its level. When in modern
+days it began to be studied, its floor was about on its original
+level, but the few standing columns of the edifice afford indubitable
+evidence that this part of the shore has been lowered to the amount of
+twenty feet or more and then re-elevated. The subsidence is proved by
+the fact that the upper part of the columns which were not protected
+by the _debris_ accumulated about them have been bored by certain
+shellfish, known as _Lithodomi_, which have the habit of excavating
+shelters in soft stone, such as these marble columns afford. At
+present the floor on which the ruin stands appears to be gradually
+sinking, though the rate of movement is very slow.
+
+Another evidence that the ejections may travel for a great distance
+underground on their way to the vent is afforded by the fact that
+Vesuvius and AEtna, though near three hundred miles apart, appear to
+exchange activities--that is, their periods of outbreak are not
+simultaneous. Although these elements of the chronology of the two
+cones may be accidental, taken with similar facts derived from other
+fields, they appear to indicate that vents, though far separated from
+each other, may, so to speak, be fed from a common subterranean
+source. It is a singular fact in this connection that the volcano of
+Stromboli, though situated between these two cones, is in a state of
+almost incessant activity. This probably indicates that the last-named
+vent derives its vapours from another level in the earth than the
+greater cones. In this regard volcanoes probably behave like springs,
+of which, indeed, they may be regarded as a group. The reader is
+doubtless aware that hot and cold springs often escape very near
+together, the difference in the temperature being due to the depth
+from which their waters come forth.
+
+As the accidents of volcanic explosion are of a nature to be very
+damaging to man, as well as to the lower orders of Nature, it is fit
+that we should note in general the effect of the Neapolitan eruptions
+on the history of civilization in that region. As stated above, the
+first Greek settlements in this vicinity--those on the island of
+Ischia--were much disturbed by volcanic outbreaks, yet the island
+became the seat of a permanent and prosperous colony. The great
+eruption of 79 probably cost many hundred lives, and led to the
+abandonment of two considerable cities, which, however, could at small
+cost have been recovered to use. Since that day various eruptions have
+temporarily desolated portions of the territory, but only in very
+small fields have the ravages been irremediable. Where the ground was
+covered with dust, it has in most places been again tillable, and so
+rapid is the decay of the lavas that in a century after their flow has
+ceased vines can in most cases be planted on their surfaces. The city
+of Naples, which lies amid the vents, though not immediately in
+contact with any of them, has steadfastly grown and prospered from the
+pre-Christian times. It is doubtful if any lives have ever been lost
+in the city in consequence of an eruption, and no great inconvenience
+has been experienced from them. Now and then, after a great ash
+shower, the volcanic dust has to be removed, but the labour is less
+serious than that imposed on many northern cities by a snowstorm.
+Through all these convulsions the tillage of the district has been
+maintained. It has ever been the seat of as rich and profitable a
+husbandry as is afforded by any part of Italy. In fact, the ash
+showers, as they import fine divided rock very rich in substances
+necessary for the growth of plants, have in a measure served to
+maintain the fertility of the soil, and by this action have in some
+degree compensated for the injury which they occasionally inflict.
+Comparing the ravages of the eruptions with those inflicted by war,
+unnecessary disease, or even bad politics, and we see that these
+natural accidents have been most merciful to man. Many a tyrant has
+caused more suffering and death than has been inflicted by these rude
+operations of Nature.
+
+From the point of view of the naturalist, AEtna is vastly more
+interesting than Vesuvius. The bulk of the cone is more than twenty
+times as great as that of the Neapolitan volcano, and the magnitude of
+its explosions, as well as the range of phenomena which they exhibit,
+incomparably greater. It happens, however, that while human history of
+the recorded kind has been intimately bound up with the tiny Vesuvian
+cone, partly because the relatively slight nature of its disturbances
+permitted men to dwell beside it, the larger AEtna has expelled culture
+from the field near its vent, and has done the greater part of its
+work in the vast solitude which it has created.[9]
+
+[Footnote 9: In part the excellent record of Vesuvius is due to the fact
+that since the early Christian centuries the priests of St. Januarius,
+the patron of Naples, have been accustomed to carry his relics in
+procession whenever an eruption began. The cessation of the outbreak has
+been written down to the credit of the saint, and thus we are provided
+with a long story of the successive outbreaks.]
+
+AEtna has been in frequent eruption for a very much longer time than
+Vesuvius. In the odes of Pindar, in the sixth century before Christ,
+we find records of eruptions. It is said also that the philosopher
+Empedocles sought fame and death by casting himself into the fiery
+crater. There has thus in the case of this mountain been no such long
+period of repose as occurred in Vesuvius. Though our records of the
+outbreaks are exceedingly imperfect, they serve to show that the vent
+has maintained its activity much more continuously than is ordinarily
+the case with volcanoes. AEtna is characteristically a lava-yielding
+cone; though the amount of dust put forth is large, the ratio of the
+fluid rock which flows away from the crater is very much greater than
+at Vesuvius. Nearly half the cone, indeed, may be composed of this
+material. Our space does not permit anything like a consecutive story
+of the AEtnean eruptions since the dawn of history, or even a full
+account of its majestic cone; we can only note certain features of a
+particularly instructive nature which have been remarked by the many
+able men who have studied this structure and the effects of its
+outbreak.
+
+The most important feature exhibited by AEtna is the vast size of its
+cone. At its apex its height, though variable from the frequent
+destruction and rebuilding of the crater walls, may be reckoned as
+about eleven thousand feet. The base on which the volcanic material
+lies is probably less than a thousand feet above the sea, so that the
+maximum thickness of the heap of volcanic ejections is probably about
+two miles. The average depth of this coating is probably about five
+thousand feet, and, as the cone has an average diameter of about
+thirty miles, we may conclude that the cone now contains about a
+thousand cubic miles of volcanic materials. Great as is this mass,
+it is only a small part of the ejected material which has gone forth
+from the vent. All the matter which in its vaporous state went forth
+with the eruption, the other gases and vapours thus discharged, have
+disappeared. So, too, a large part of the ash and much of the lava has
+been swept away by the streams which drain the region, and which in
+times of eruption are greatly swollen by the accompanying torrential
+rains. The writer has estimated that if all the emanations from the
+volcano--solid, fluid, and gaseous--could be heaped on the cone, they
+would form a mass of between two and three thousand cubic miles in
+contents. Yet notwithstanding this enormous outputting of earthy
+matter, the earth on which the AEtnean cone has been constructed has
+not only failed to sink down, but has been in process of continuous,
+slow uprising, which has lifted the surface more than a thousand feet
+above the level which it had at the time when volcanic action began in
+this field. Here, even more clearly than in the case of Vesuvius, we
+see that the materials driven forth from the crater are derived not
+from just beneath its foundation, but from a distance, from realms
+which in the case of this insular volcano are beneath the sea floors.
+It is certain that here the migration of rock matter, impelled by the
+expansion of its contained water toward the vent, has so far exceeded
+that which has been discharged through the crater that an uprising of
+the surface such as we have observed has been brought about.
+
+[Illustration: _Mount AEtna, seen from near Catania. The imperfect
+cones on the sky line to the left are those of small secondary
+eruptions._]
+
+There are certain peculiarities of Mount AEtna which are due in part to
+its great size and in part to the climatal conditions of the region in
+which it lies. The upper part of the mountain in winter is deeply
+snow-clad; the frozen water often, indeed, forms great drifts in the
+gorges near the summit. Here it has occasionally happened that a layer
+of ashes has deeply buried the mass, so that it has been preserved for
+years, becoming gradually more inclosed by the subsequent eruptions.
+At one point where this compact snow--which has, indeed, taken on the
+form of ice--has been revealed to view, it has been quarried and
+conveyed to the towns upon the seacoast. It is likely that there are
+many such masses of ice inclosed between the ash layers in the upper
+part of the mountain, where, owing to the height, the climate is very
+cold. This curious fact shows how perfect a non-conductor the ash beds
+of a volcano are to protect the frozen water from the heat of the
+rocks about the crater.
+
+The furious rains which beset the mountain in times of great eruptions
+excavate deep channels on its sides. The lava outbreaks which attend
+almost every eruption, and which descend from the base of the cinder
+cone at the height of from five to eight thousand feet above the sea,
+naturally find their way into these channels, where they course in the
+manner of rivers until the lower and less valleyed section of the cone
+is reached.
+
+Such a lava flow naturally begins to freeze on the surface, the lava
+at first becoming viscid, much in the manner of cream on the surface
+of milk. Urged along by the more fluid lava underneath, this viscid
+coating takes a ropy or corrugated form. As the freezing goes deeper,
+a firm stone roof may be formed across the gorge, which, when the
+current of lava ceases to flow from the crater, permits the lower part
+of the stream to drain away, leaving a long cavern or scries of caves
+extending far up the cone. The nature of this action is exactly
+comparable to that which we may observe when on a frosty morning after
+rain we may find the empty channels which were occupied by rills of
+water roofed over with ice; the ice roofs are temporary, while those
+of lava may endure for ages. Some of these lava-stream caves have been
+disclosed, in the manner of ordinary caverns, by the falling of their
+roofs; but the greater part are naturally hidden beneath the
+ever-increasing materials of the cone.
+
+The lava-stream caves of AEtna are not only interesting because of
+their peculiarities of form, which we shall not undertake to describe,
+but also for the reason that they help us to account for a very
+peculiar feature in the history of the great cone. On the slopes of
+the volcano, below the upper cindery portion, there are several
+hundred lesser cones, varying from a few score to seven hundred feet
+in height. Each of these has its appropriate crater, and has evidently
+been the seat of one or more eruptions. As the greater part of these
+cones are ancient, many of them being almost effaced by the rain or
+buried beneath the ejections which have surrounded their bases since
+the time they were formed, we are led to believe that many thousands
+of them have been formed during the history of the volcano. The
+history of these subsidiary cones appears to be connected with the
+lava caves noted above. These caverns, owing to the irregularities of
+their form, contain water. They are, in fact, natural cisterns, where
+the abundant rainfall of the mountain finds here and there storage.
+When, during the throes of an eruption, dikes such as we know often to
+penetrate the mountain, are riven outward from the crater through the
+mass of the cone, and filled with lava, the heated rock must often
+come in contact with these masses of buried water. The result of this
+would inevitably be the local generation of steam at a high
+temperature, which would force its way out in a brief but vigorous
+eruption, such as has been observed to take place when these
+peripheral volcanoes are formed. Sometimes it has happened that after
+the explosion the lava has found its way in a stream from the fissure
+thus opened. That this explanation is sufficient is in a measure shown
+by observations on certain effects of lava flows from Vesuvius. The
+writer was informed by a very judicious observer, a resident of
+Naples, who had interested himself in the phenomena of that volcano,
+that the lava streams when they penetrated a cistern, such as they
+often encounter in passing over villages or farmsteads, vaporized the
+water, and gave rise, through the action of the steam, to small
+temporary cones, which, though generally washed away by the further
+flow of the liquid rock, are essentially like those which we find on
+AEtna. Such subsidiary, or, as they are sometimes called, parasitic
+cones, are known about other volcanoes, but nowhere are they so
+characteristic as on the flanks of that wonderful volcano.
+
+A very conspicuous feature in the AEtnean cone consists of a great
+valley known as the Val del Bove, or Bull Hollow, which extends from
+the base of the modern and ever-changeable cinder cone down the flanks
+of the older structure to near its base. This valley has steep sides,
+in places a thousand or more feet high, and has evidently been formed
+by the down-settling of portions of the cone which were left without
+support by the withdrawal from beneath them of materials cast forth in
+a time of explosion. In an eruption this remarkable valley was the
+seat of a vast water flood, the fluid being cast forth from the crater
+at the beginning of the explosion. In the mouths of this and other
+volcanoes, after a long period of repose, great quantities of water,
+gathering from rains or condensed from the steam which slowly escapes
+from these openings, often pours like a flood down the sides of the
+mountains. In the great eruption of Galongoon, in Java, such a mass of
+water, cast forth by a terrific explosion, mingled with ashes, so that
+the mass formed a thick mud, was shot forth with such energy that it
+ravaged an area nearly eighty miles in diameter, destroying the
+forests and their wild inhabitants, as well as the people who dwelt
+within the range of the amazing disaster. So powerfully was this water
+driven from the crater that the districts immediately at the base of
+the cone were in a manner overshot by the vast stream, and escaped
+with relatively little injury.
+
+When it comes forth from the base of the cinder cone, or from one of
+the small peripheral craters, the lava stream usually appears to be
+white hot, and to flow with almost the ease of water. It does not
+really have that measure of fluidity; its condition is rather that of
+thin paste; but the great weight of the material--near two and a half
+times that of water--causes the movement down the slope to be speedy.
+The central portion of the lava stream long retains its high
+temperature; but the surface, cooling, is first converted into a tough
+sheet, which, though it may bend, can hardly be said to flow. Further
+hardening converts these outlying portions of the current into hard,
+glassy stone, which is broken into fragments in a way resembling the
+ice on the surface of a river. It thus comes about that the advancing
+front of the lava stream becomes covered, and its motion hindered by
+the frozen rock, until the rate of ongoing may not exceed a few feet
+an hour, and the appearance is that of a heap of stone slowly rolling
+down a slope. Now and then a crevice is formed, through which a thin
+stream of liquid lava pours forth, but the material, having already
+parted with much of its heat, rapidly cools, and in turn becomes
+covered with the coating of frozen fragments. In this state of the
+stream the lava flow stands on all sides high above the slope which it
+is traversing; it is, in fact, walled in by its own solidified parts,
+though it is urged forward by the contribution which continues to flow
+in the under arches. In this state of the movement trifling accidents,
+or even human interference, may direct the current this way or that.
+
+Some of the most interesting chapters in the history of AEtna relate to
+the efforts of the people to turn these slow-moving streams so that
+their torrents might flow into wilderness places rather than over the
+fields and towns. In the great flow of 1669, which menaced the city of
+Catania, a large place on the seashore to the southeast of the cone, a
+public-spirited citizen, Senor Papallardo, protecting himself and his
+servants with clothing made of hides, and with large shields, set
+forth armed with great hooks with the purpose of diverting the course
+of the lava mass. He succeeded in pulling away the stones on the
+flank of the stream, so that a flow of the molten rock was turned in
+another direction. The expedient would probably have been successful
+if he had been allowed to continue his labours; but the inhabitants of
+a neighbouring village, which was threatened by the off-shooting
+current which Papallardo had created, took up arms and drove him and
+his retainers away. The flow continued until it reached Catania. The
+people made haste to build the city walls on the side of danger higher
+than it was before, but the tide mounted over its summit.
+
+Although the lavas which come forth from the volcano evidently have a
+high temperature, their capacity for melting other rocks is relatively
+small. They scour these rocks, because of their weight, even more
+energetically than do powerful torrents of water, but they are
+relatively ineffective in melting stone. On AEtna and elsewhere we may
+often observe lavas which have flowed through forests. When the tide
+of molten rock has passed by, the trees may be found charred but not
+entirely burned away; even stems a few inches in diameter retain
+strength enough to uphold considerable fringes and clots of the lava
+which has clung to them. These facts bear out the conclusion that the
+fluidity of the heated stone depends in considerable measure on the
+water which is contained, either in its fluid or vaporous state,
+between the particles of the material.
+
+If we consider the Italian volcanoes as a whole, we find that they lie
+in a long, discontinuous line extending from the northern part of the
+valley of the Po, within sight of the Alps, to AEtna, and in
+subterranean cones perhaps to the northern coast of Africa. At the
+northern end of the line we have a beautiful group of extinct
+volcanoes, known as the Eugean Mountains. Thence southward to southern
+Tuscany craters are wanting, but there is evidence of fissures in the
+earth which give forth thermal waters. From southern Tuscany southward
+through Rome to Naples there are many extinct craters, none of which
+have been active in the historic period. From Naples southward the
+cones of this system, about a dozen in number, are on islands or close
+to the margin of the sea. It is a noteworthy fact that the greater
+part of these shore or insular vents have been active since the dawn
+of history; several of them frequently and furiously so, while none of
+those occupying an inland position have been the seat of explosions.
+This is a striking instance going to show the relation of these
+processes to conditions which are brought about on the sea bottom.
+
+AEtna is, as we have noticed, a much more powerful volcano than
+Vesuvius. Its outbreaks are more vigorous, its emanations vastly
+greater in volume, and the mass of its constructions many times as
+great as those accumulated in any other European cone. There are,
+however, a number of volcanoes in the world which in certain features
+surpass AEtna as much as that crater does Vesuvius. Of these we shall
+consider but two--Skaptar Jokul, of Iceland, remarkable for the volume
+of its lava flow, and Krakatoa, an island volcano between Java and
+Sumatra, which was the seat of the greatest explosion of which we have
+any record.
+
+The whole of Iceland may be regarded as a volcanic mass composed
+mainly of lavas and ashes which have been thrown up by a group of
+volcanoes lying near the northern end of the long igneous axis which
+extends through the centre of the Atlantic. The island has been the
+seat of numerous eruptions; in fact, since its settlement by the
+Northmen in 1070 its sturdy inhabitants have been almost as much
+distressed by the calamities which have come from the internal heat as
+they have been by the enduring external cold. They have, indeed, been
+between frost and fire. The greatest recorded eruption of Iceland
+occurred in 1783, when the volcano of Skaptar, near the southern
+border of the island, poured forth, first, a vast discharge of dust
+and ashes, and afterward in the languid state of eruption inundated a
+series of valleys with the greatest lava flow of which we have any
+written record. The dust poured forth into the upper air, being finely
+divided and in enormous quantity, floated in the air for months,
+giving a dusky hue to the skies of Europe, which led the common people
+and many of the learned to fear that the wrath of God was upon them,
+and that the day of judgment was at hand. Even the poet Cowper, a man
+of high culture and education, shared in this unreasonable view.
+
+The lava flow in this eruption filled one of the considerable valleys
+of the island, drying up the river, and inundating the plains on
+either side. Estimates which have been made as to the volume of this
+flow appear to indicate that it may have amounted to more than the
+bulk of the Mont Blanc.
+
+This great eruption, by the direct effect of the calamity, and by the
+famine due to the ravaging of the fields and the frightening of the
+fish from the shores which it induced, destroyed nearly one fifth of
+the Icelandic people. It is, in fact, to be remembered as one of the
+three or four most calamitous eruptions of which we have any account,
+and, from the point of view of lava flow, the greatest in history.
+
+Just a hundred years after the great Skaptar eruption, which darkened
+the skies of Europe, the island of Krakatoa, an isle formed by a small
+volcano in the straits of Java, was the seat of a vapour explosion
+which from its intensity is not only unparalleled, but almost
+unapproached in all accounts of such disturbances. Krakatoa had long
+been recognised as a volcanic isle; it is doubtful, however, if it had
+ever been seen in eruption during the three centuries or more since
+European ships began to sail by it until the month of May of the year
+above mentioned. Then an outbreak of what may be called ordinary
+violence took place, which after a few days so far ceased that
+observers landed and took account of the changes which the convulsion
+had brought about. For about three months there were no further signs
+of activity, but on the 29th of August a succession of vast explosions
+took place, which blew away a great part of the island, forming in its
+place a submarine crater two or three miles in diameter, creating
+world-wide disturbances of sea and air. The sounds of the outbreak
+were heard at a distance of sixteen hundred miles away. The waves of
+the air attendant on the explosion ran round the earth at least once,
+as was distinctly indicated by the self-recording barometers; it is
+possible, indeed, that, crossing each other in their east and west
+courses, these atmospheric tides twice girdled the sphere. In effect,
+the air over the crater was heaved up to the height of some tens of
+thousands of feet, and thence rolled off in great circular waves, such
+as may be observed in a pan of milk when a sharp blow pushes the
+bottom upward.
+
+The violent stroke delivered to the waters of the sea created a vast
+wave, which in the region where it originated rolled upon the shores
+with a surf wall fifty or more feet high. In a few minutes about
+thirty thousand people were overwhelmed. The wave rolled on beyond its
+destructive limits much in the manner of the tide; its influence was
+felt in a sharp rise and fall of the waters as far as the Pacific
+coast of North America, and was indicated by the tide gauges in the
+Atlantic as far north as the coast of Europe.
+
+Owing to the violence of the eruption, Krakatoa poured forth no lava,
+but the dust and ashes which ascended into the air--or, in
+other words, the finely divided lava which escaped into the
+atmosphere--probably amounted in bulk to more than twenty cubic miles.
+The coarser part of this material, including much pumice, fell upon
+the seas in the vicinity, where, owing to its lightness, it was free
+to drift in the marine currents far and wide throughout the oceanic
+realm. The finer particles, thrown high into the air, perhaps to the
+height of nearly a hundred thousand feet--certainly to the elevation
+of more than half this amount--drifted far and wide in the
+atmosphere, so that for years the air of all regions was clouded by
+it, the sunrise and sunset having a peculiar red glow, which the dust
+particles produce by the light which they reflect. In this period, at
+all times when the day was clear, the sun appeared to be surrounded by
+a dusky halo. In time the greater part of this dust was drawn down by
+gravity, some portion of it probably falling on every square foot of
+the earth. Since the disappearance of the characteristic phenomena
+which it produced in the atmosphere, European observers have noted the
+existence of faint clouds lying in the upper part of the air at the
+height of a hundred miles or more above the surface. These clouds,
+which were at first distinctly visible in the earliest stage of dawn
+and in the latest period of the sunset glow, seemed to be in rapid
+motion to the eastward, and to be mounting higher above the earth. It
+has been not unreasonably supposed that these shining clouds represent
+portions of the finest dust from Krakatoa, which has been thrown so
+far above the earth's attraction that it is separating itself from the
+sphere. If this view be correct, it seems likely that we may look to
+great volcanic explosions as a source whence the dustlike particles
+which people the celestial spaces may have come. They may, in a word,
+be due to volcanic explosions occurring on this and other celestial
+spheres.
+
+The question suggested above as to the possibility of volcanic
+ejections throwing matter from the earth beyond the control of its
+gravitative energy is one of great scientific interest. Computations
+(not altogether trustworthy) show that a body leaving the earth's
+surface under the conditions of a cannon ball fired vertically upward
+would have to possess a velocity at the start of at least seven miles
+a second in order to go free into space. It would at first sight seem
+that we should be able to reckon whether volcanoes can propel earth
+matter upward with this speed. In fact, however, sufficient data are
+not obtainable; we only know in a general way that the column of
+vapour rises to the height of thirty or forty thousand feet, and this
+in eruptions of no great magnitude. In an accident such as that at
+Krakatoa, even if an observer were near enough to see clearly what was
+going on, the chance of his surviving the disturbance would be small.
+Moreover, the ascending vapours, owing to their expansion of the steam
+in the column, begin to fly out sideways on its periphery, so that the
+upper part of the central section in the discharge is not visible from
+the earth.
+
+It is in the central section of the uprushing mass, if anywhere, that
+the dust might attain the height necessary to put it beyond the
+earth's attraction, bringing it fairly into the realm of the solar
+system, or to the position where its own motion and the attraction of
+the other spheres would give it an independent orbital movement about
+the sun, or perhaps about the earth. We can only say that observations
+on the height of volcanic ejections are extremely desirable; they can
+probably only be made from a balloon. An ascension thus made beyond
+the cloud disk which the eruption produces might bring the observer
+where he could discern enough to determine the matter. Although the
+movements of the rocky particles could not be observed, the colour
+which they would give to the heavens might tell the story which we
+wish to know. There is evidence that large masses of stone hurled up
+by volcanic eruption have fallen seven miles from the base of the
+cone. Assuming that the masses went straight upward at the beginning
+of their ascent, and that they were afterward borne outwardly by the
+expansion of the column, computations which have a general but no
+absolute value appear to indicate that the masses attained a height of
+from thirty to fifty miles, and had an initial velocity which, if
+doubled, might have carried them into space.
+
+Last of all, we shall note the conditions which attend the eruptions
+of submarine volcanoes. Such explosions have been observed in but a
+few instances, and only in those cases where there is reason to
+believe that the crater at the time of its explosion had attained to
+within a few hundred feet of the sea level. In these cases the
+ejections, never as yet observed in the state of lava, but in the
+condition of dust and pumice, have occasionally formed a low island,
+which has shortly been washed away by the waves. Knowing as we do that
+volcanoes abound on the sea floor, the question why we do not oftener
+see their explosions disturbing the surface of the waters is very
+interesting, but not as yet clearly explicable. It is possible,
+however, that a volcanic discharge taking place at the depth of
+several thousand feet below the surface of the water would not be able
+to blow the fluid aside so as to open a pipe to the surface, but would
+expend its energy in a hidden manner near the ocean floor. The vapours
+would have to expand gradually, as they do in passing up through the
+rock pipe of a volcano, and in their slow upward passage might be
+absorbed by the water. The solid materials thrown forth would in this
+case necessarily fall close about the vent, and create a very steep
+cone, such, indeed, as we find indicated by the soundings off certain
+volcanic islands which appear only recently to have overtopped the
+level of the waters.
+
+As will be seen, though inadequately from the diagrams of Vesuvius,
+volcanic cones have a regularity and symmetry of form far exceeding
+that afforded by the outlines of any other of the earth's features.
+Where, as is generally the case, the shape of the cone is determined
+by the distribution of the falling cinders or divided lava which
+constitutes the mass of most cones, the slope is in general that known
+as a catenary curve--i.e., the line formed by a chain hanging between
+two points at some distance from the vertical. It is interesting to
+note that this graceful outline is a reflection or consequence of the
+curve described by the uprushing vapour. The expansion in the
+ascending column causes it to enlarge at a somewhat steadfast rate,
+while the speed of the ascent is ever diminishing. Precisely the same
+action can be seen in the like rush of steam and other gases and
+vapours from the cannon's mouth; only in the case of the gun, even of
+the greatest size, we can not trace the movement for more than a few
+hundred feet. In this column of ejection the outward movement from the
+centre carries the bits of lava outwardly from the centre of the
+shaft, so that when they lose their ascending velocity they are drawn
+downward upon the flanks of the cone, the amount falling upon each
+part of that surface being in a general way proportional to the
+thickness of the vaporous mass from which they descend. The result is,
+that the thickest part of the ash heap is formed on the upper part of
+the crater, from which point the deposit fades away in depth in every
+direction. In a certain measure the concentration toward the centre of
+the cone is brought about by the draught of air which moves in toward
+the ascending column.
+
+Although, in general, ejections of volcanic matter take place through
+cones, that being the inevitable form produced by the escaping steam,
+very extensive outpourings of lava, ejections which in mass probably
+far exceed those thrown forth through ordinary craters, are
+occasionally poured out through fissures in the earth's crust. Thus in
+Oregon, Idaho, and Washington, in eastern Europe, in southern India,
+and at some other points, vast flows, which apparently took place from
+fissures, have inundated great realms with lava ejections. The
+conditions which appear to bring about these fissure eruptions of lava
+are not yet well understood. A provisional and very probable account
+of the action can be had in the hypothesis which will now be set
+forth.
+
+Where any region has been for a long time the seat of volcanic action,
+it is probable that a large amount of rock in a more or less fluid
+condition exists beneath its surface. Although the outrushing steam
+ejects much of this molten material, there are reasons to suppose that
+a yet greater part lies dormant in the underground spaces. Thus in the
+case of AEtna we have seen that, though some thousands of miles of
+rock matter have come forth, the base of the cone has been uplifted,
+probably by the moving to that region of more or less fluid rock. If
+now a region thus underlaid by what we may call incipient lavas is
+subjected to the peculiar compressive actions which lead to
+mountain-building, we should naturally expect that such soft material
+would be poured forth, possibly in vast quantities through fault
+fissures, which are so readily formed in all kinds of rock when
+subject to irregular and powerful strains, such as are necessarily
+brought about when rocks are moved in mountain-making. The great
+eruptions which formed the volcanic table-lands on the west coast of
+North America appear to have owed the extrusion of their materials to
+mountain-building actions. This seems to have been the case also in
+some of those smaller areas where fissure flows occur in Europe. It is
+likely that this action will explain the greater part of these massive
+eruptions.
+
+It need not be supposed that the rock beneath these countries, which
+when forced out became lava, was necessarily in the state of perfect
+fluidity before it was forced through the fissures. Situated at great
+depth in the earth, it was under a pressure so great that its
+particles may have been so brought together that the material was
+essentially solid, though free to move under the great strains which
+affected it, and acquiring temperature along with the fluidity which
+heat induces as it was forced along by the mountain-building pressure.
+As an illustration of how materials may become highly heated when
+forced to move particle on particle, it may be well to cite the case
+in which the iron stringpiece on top of a wooden dam near Holyoke,
+Mass., was affected when the barrier went away in a flood. The iron
+stringer, being very well put together, was, it is said, drawn out by
+the strain until it became sensibly reddened by the motion of its
+particles, and finally fell hissing into the waters below. A like
+heating is observable when metal is drawn out in making wire. Thus a
+mass of imperfectly fluid rock might in a forced journey of a few
+miles acquire a decided increase of temperature.
+
+Although the most striking volcanic action--all such phenomena,
+indeed, as commonly receives the name--is exhibited finally on the
+earth's surface, a great deal of work which belongs in the same group
+of geological actions is altogether confined to the deep-lying rock,
+and leads to the formation of dikes which penetrate the strata, but do
+not rise to the open air. We have already noted the fact that dikes
+abound in the deeper parts of volcanic cones, though the fissures into
+which they find their way are seldom riven up to the surface. In the
+same way beneath the ground in non-volcanic countries we may discover
+at a great depth in the older, much-changed rock a vast number of
+these crevices, varying from a few inches to a hundred feet or more in
+width, which have been filled with lavas, the rock once molten having
+afterward cooled. In most cases these dikes are disclosed to us
+through the down-wearing of the earth that has removed the beds into
+which the dikes did not penetrate, thus disclosing the realm in which
+the disturbances took place.
+
+Where, as is occasionally the case in deep mines, or on some bare
+rocky cliff of great height, we can trace a dike in its upward course
+through a long distance, we find that we can never distinctly discover
+the lower point of its extension. No one has ever seen in a clear way
+the point of origin of such an injection. We can, however, often
+follow it upward to the place where there was no longer a rift into
+which it could enter. In its upward path the molten matter appears
+generally to have followed some previously existing fracture, a joint
+plane or a fault, which generally runs through the rocks on those
+planes. We can observe evidence that the material was in the state of
+igneous fluidity by the fact that it has baked the country rocks on
+either side of the fissure, the amount of baking being in proportion
+to the width of the dike, and thus to the amount of heat which it
+could give forth. A dike six inches in diameter will sometimes barely
+sear its walls, while one a hundred feet in width will often alter the
+strata for a great distance on either side. In some instances, as in
+the coal beds near Richmond, Va., dikes occasionally cut through beds
+of bituminous coal. In these cases we find that the coal has been
+converted into coke for many feet either side of a considerable
+injection. The fact that the dike material was molten is still further
+shown by the occurrence in it of fragments which it has taken up from
+the walls, and which may have been partly melted, and in most cases
+have clearly been much heated.
+
+Where dikes extend up through stratified beds which are separated from
+each other by distinct layers, along which the rock is not firmly
+bound together, it now and then happens, as noted by Mr. G.K. Gilbert,
+of the United States Geological Survey, that the lava has forced its
+way horizontally between these layers, gradually uplifting the
+overlying mass, which it did not break through, into a dome-shaped
+elevation. These side flows from dikes are termed laccolites, a word
+which signifies the pool-like nature of the stony mass which they form
+between the strata.
+
+In many regions, where the earth has worn down so as to reveal the
+zone of dikes which was formed at a great depth, the surface of the
+country is fairly laced with these intrusions. Thus on Cape Ann, a
+rocky isle on the east coast of Massachusetts, having an area of about
+twenty square miles, the writer, with the assistance of his colleague,
+Prof. R.S. Tarr, found about four hundred distinct dikes exhibited on
+the shore line where the rocks had been swept bare by the waves. If
+the census of these intrusions could have been extended over the whole
+island, it would probably have appeared that the total number exceeded
+five thousand. In other regions square miles can be found where the
+dikes intercepted by the surface occupy an aggregate area greater than
+that of the rocks into which they have been intruded.
+
+Now and then, but rarely, the student of dikes finds one where the
+bordering walls, in place of having the clean-cut appearance which
+they usually exhibit, has its sides greatly worn away and much melted,
+as if by the long-continued passage of the igneous fluid through the
+crevice. Such dikes are usually very wide, and are probably the paths
+through which lavas found their way to the surface of the earth,
+pouring forth in a volcanic eruption. In some cases we can trace their
+relation to ancient volcanic cones which have worn down in all their
+part which were made up of incoherent materials, so that there remains
+only the central pipe, which has been preserved from decay by the
+coherent character of the lava which filled it.
+
+The hypothesis that dikes are driven upward into strata by the
+pressure of the beds which overlie materials hot and soft enough to be
+put in motion when a fissure enters them, and that their movement
+upward through the crevice is accounted for by this pressure, makes
+certain features of these intrusions comprehensible. Seeing that very
+long, slender dikes are found penetrating the rock, which could not
+have had a high temperature, it becomes difficult to understand how
+the lava could have maintained its fluidity; but on the supposition
+that it was impelled forward by a strong pressure, and that the energy
+thus transmitted through it was converted into heat, we discover a
+means whereby it could have been retained in the liquid condition,
+even when forced for long distances through very narrow channels.
+Moreover, this explanation accounts for the fact which has long
+remained unexplained that dikes, except those formed about volcanic
+craters, rarely, if ever, rise to the surface.
+
+The materials contained in dikes differ exceedingly in their chemical
+and mineral character. These variations are due to the differences in
+Nature of the deposits whence they come, and also in a measure to
+exchanges which take place between their own substance and that of the
+rocks between which they are deposited. This process often has
+importance of an economic kind, for it not infrequently leads to the
+formation of metalliferous veins or other aggregations of ores, either
+in the dike itself or in the country rock. The way in which this is
+brought about may be easily understood by a familiar example. If flesh
+be placed in water which has the same temperature, no exchange of
+materials will take place; but if the water be heated, a circulation
+will be set up, which in time will bring a large part of the soluble
+matter into the surrounding water. This movement is primarily
+dependent on differences of temperature, and consequently differences
+in the quantity of soluble substances which the water seeks to take
+up. When a dike is injected into cooler rocks, such a slow circulation
+is induced. The water contained in the interstices of the stone
+becomes charged with mineral materials, if such exist in positions
+where it can obtain possession of them, and as cooling goes on, these
+dissolved materials are deposited in the manner of veins. These veins
+are generally laid down on the planes of contact between the two kinds
+of stone, but they may be formed in any other cavities which exist in
+the neighbourhood. The formation of such veins is often aided by the
+considerable shrinkage of the lava in the dike, which, when it cools,
+tends to lose about fifteen per cent of its volume, and is thus likely
+to leave a crevice next the boundary walls. Ores thus formed afford
+some of the commonest and often the richest mineral deposits. At
+Leadville, in Colorado, the great silver-bearing lodes probably were
+produced in this manner, wherein lavas, either those of dikes or those
+which flowed in the open air, have come in contact with limestones.
+The mineral materials originally in the once molten rock or in the
+limy beds was, we believe, laid down on ancient sea floors in the
+remains of organic forms, which for their particular uses took the
+materials from the old sea water. The vein-making action has served to
+assemble these scattered bits of metal into the aggregation which
+constitutes a workable deposit. In time, as the rocks wear down, the
+materials of the veins are again taken into solution and returned to
+the sea, thence perhaps to tread again the cycle of change.
+
+In certain dikes, and sometimes also, perhaps, in lavas known as
+basalts, which have flowed on the surface, the rock when cooling, from
+the shrinkage which then occurs, has broken in a very regular way,
+forming hexagonal columns which are more or less divided on their
+length by joints. When worn away by the agencies of decay, especially
+where the material forms steep cliffs, a highly artificial effect is
+produced, which is often compared, where cut at right angles to the
+columns, to pavements, or, where the division is parallel to the
+columns, to the pipes of an organ.
+
+What we know of dikes inclines us to the opinion that as a whole they
+represent movements of softened rock where the motion-compelling agent
+is not mainly the expansion of the contained water which gives rise to
+volcanic ejection, but rather in large part due to the weight of
+superincumbent strata setting in motion materials which were somewhat
+softened, and which tended to creep, as do the clays in deep coal
+mines. It is evident, however; it is, moreover, quite natural, that
+dike work is somewhat mingled with that produced by the volcanic
+forces; but while the line between the two actions is not sharp, the
+discrimination is important, and occurs with a distinctness rather
+unusual on the boundary line between two adjacent fields of phenomena.
+
+                  *       *       *       *       *
+
+We have now to consider the general effects of the earth's interior
+heat so far as that body of temperature tends to drive materials from
+the depths of the earth to the surface. This group of influences is
+one of the most important which operates on our sphere; as we shall
+shortly see, without such action the earth would in time become an
+unfit theatre for the development of organic life. To perceive the
+effect of these movements, we must first note that in the great
+rock-constructing realm of the seas organic life is constantly
+extracting from the water substances, such as lime, potash, soda, and
+a host of other substances necessary for the maintenance of
+high-grade organisms, depositing these materials in the growing
+strata. Into these beds, which are buried as fast as they form, goes
+not only these earthy materials, but a great store of the sea water as
+well. The result would be in course of time a complete withdrawal into
+the depths of the earth of those substances which play a necessary
+part in organic development. The earth would become more or less
+completely waterless on its surface, and the rocks exposed to view
+would be composed mainly of silica, the material which to a great
+extent resists solution, and therefore avoids the dissolving which
+overtakes most other kinds of rocks. Here comes in the machinery of
+the hot springs, the dikes, and the volcanoes. These agents, operating
+under the influence of the internal heat of the earth, are constantly
+engaged in bearing the earthy matter, particularly its precious more
+solvent parts, back to the surface. The hot springs and volcanoes work
+swiftly and directly, and return the water, the carbon dioxide, and a
+host of other vaporizable and soluble and fusible substances to the
+realm of solar activity, to the living surface zone of the earth. The
+dikes operate less immediately, but in the end to the same effect.
+They lift their materials miles above the level where they were
+originally laid, probably from a zone which is rarely if ever exposed
+to view, placing them near the surface, where the erosive agents can
+readily find access to them.
+
+Of the three agents which serve to export earth materials from its
+depths, volcanoes are doubtless the most important. They send forth
+the greater part of the water which is expelled from the rocks.
+Various computations which the writer has made indicate that an
+ordinary volcano, such as AEtna, in times of most intense explosion,
+may send forth in the form of steam one fourth of a cubic mile or
+more of water during each day of its discharge, and in a single great
+eruption may pour forth several times this quantity. In its history
+AEtna has probably returned to the atmosphere some hundred cubic miles
+of water which but for the process would have remained permanently
+locked up in its rock prison.
+
+The ejection of rock material, though probably on the average less in
+quantity than the water which escapes, is also of noteworthy
+importance. The volcanoes of Java and the adjacent isles have, during
+the last hundred and twenty years, delivered to the seas more earth
+material than has been carried into those basins by the great rivers.
+If we could take account of all the volcanic ejections which have
+occurred in this time, we should doubtless find that the sum of the
+materials thus cast forth into the oceans was several times as great
+as that which was delivered from the lands by all the superficial
+agents which wear them away. Moreover, while the material from the
+land, except the small part which is in a state of complete solution,
+all falls close to the shore, the volcanic waste, because of its fine
+division or because of the blebs of air which its masses contain, may
+float for many years before it finds its way to the bottom, it may be
+at the antipodes of the point at which it came from the earth. While
+thus journeying through the sea the rock matter from the volcanoes is
+apt to become dissolved in water; it is, indeed, doubtful if any
+considerable part of that which enters the ocean goes by gravitation
+to its floor. The greater portion probably enters the state of
+solution and makes its way thence through the bodies of plants and
+animals again into the ponderable state.
+
+If an observer could view the earth from the surface of the moon, he
+would probably each day behold one of these storms which the volcanoes
+send forth. In the fortnight of darkness, even with the naked eye, it
+would probably be possible to discern at any time several eruptions,
+some of which would indicate that the earth's surface was ravaged by
+great catastrophes. The nearer view of these actions shows us that
+although locally and in small measure they are harmful to the life of
+the earth, they are in a large way beneficent.
+
+
+
+
+                           CHAPTER VIII.
+
+                             THE SOIL.
+
+
+The frequent mention which it has been necessary to make of soil
+phenomena in the preceding chapters shows how intimately this feature
+in the structure of the earth is blended with all the elements of its
+physical history. It is now necessary for us to take up the phenomena
+of soils in a consecutive manner.
+
+The study of any considerable river basin enables us to trace the more
+important steps which lead to the destructure and renovation of the
+earth's detrital coating. In such an interpretation we note that
+everywhere the rocks which were built on the sea bottom, and more or
+less made over in the great laboratory of the earth's interior, are at
+the surface, when exposed to the conditions of the atmosphere, in
+process of being taken to pieces and returned to the sea. This action
+goes on everywhere; every drop of rain helps it. It is aided by frost,
+or even by the changes of expansion and contraction which occur in the
+rocks from variations of heat. The result is that, except where the
+slopes are steep, the surface is quickly covered with a layer of
+fragments, all of which are in the process of decay, and ready to
+afford some food to plants. Even where the rock appears bare, it is
+generally covered with lichens, which, adhering to it, obtain a share
+of nutriment from the decayed material which they help to hold on the
+slope. When they have retained a thin sheet of the _debris_, mosses
+and small flowering plants help the work of retaining the detritus.
+Soon the strong-rooted bushes and trees win a foothold, and by sending
+their rootlets, which are at first small but rapidly enlarge, into the
+crevices, they hasten the disruption of the stones.
+
+If the construction of soil goes on upon a steep cliff, the quantity
+retained on the slope may be small, but at the base we find a talus,
+composed of the fragments not held by the vegetation, which gradually
+increases as the cliff wears down, until the original precipice may be
+quite obliterated beneath a soil slope. At first this process is
+rapid; it becomes gradually slower and slower as the talus mounts up
+the cliff and as the cliff loses its steepness, until finally a gentle
+slope takes the place of the steep.
+
+From the highest points in any river valley to the sea level the
+broken-up rock, which we term soil, is in process of continuous
+motion. Everywhere the rain water, flowing over the surface or soaking
+through the porous mass, is conveying portions of the material which
+is taken into solution in a speedy manner to the sea. Everywhere the
+expansion of the soil in freezing, or the movements imposed on it by
+the growth of roots, by the overturning of trees, or by the
+innumerable borings and burrowings which animals make in the mass, is
+through the action of gravitation slowly working down the slope. Every
+little disturbance of the grains or fragments of the soil which lifts
+them up causes them when they fall to descend a little way farther
+toward the sea level. Working toward the streams, the materials of the
+soil are in time delivered to those flowing waters, and by them urged
+speedily, though in most cases interruptedly, toward the ocean.
+
+There is another element in the movement of the soils which, though
+less appreciable, is still of great importance. The agents of decay
+which produce and remove the detritus, the chemical changes of the bed
+rock, and the mechanical action which roots apply to them, along with
+the solutional processes, are constantly lowering the surface of the
+mass. In this way we can often prove that a soil continuously
+existing has worked downward through many thousand feet of strata. In
+this process of downgoing the country on which the layer rests may
+have greatly changed its form, but the deposit, under favourable
+conditions, may continue to retain some trace of the materials which
+it derived from beds which have long since disappeared, their position
+having been far up in the spaces now occupied by the air. Where the
+slopes are steep and streams abound, we rarely find detritus which
+belonged in rock more than a hundred feet above the present surface of
+the soil. Where, however, as on those isolated table-lands or buttes
+which abound in certain portions of the Mississippi Valley, as well as
+in many other countries, we find a patch of soil lying on a nearly
+level surface, which for geologic ages has not felt the effect of
+streams, we may discover, commingled in the _debris_, the harder
+wreckage derived from the decay of a thousand feet or more of vanished
+strata.
+
+When we consider the effect of organic life on the processes which go
+on in the soil, we first note the large fact that the development of
+all land vegetation depends upon the existence of this detritus--in a
+word, on the slow movement of the decaying rocky matter from the point
+where it is disrupted to its field of rest in the depths of the sea.
+The plants take their food from the portion of this rocky waste which
+is brought into solution by the waters which penetrate the mass. On
+the plants the animals feed, and so this vast assemblage of organisms
+is maintained. Not only does the land life maintain itself on the
+soil, and give much to the sea, but it serves in various ways to
+protect this detrital coating from too rapid destruction, and to
+improve its quality. To see the nature of this work we should visit a
+region where primeval forests still lie upon the slopes of a hilly
+region. In the body of such a wood we find next the surface a coating
+of decayed vegetable matter, made up of the falling leaves, bark,
+branches, and trunks which are constantly descending to the earth.
+Ordinarily, this layer is a foot or more in thickness; at the top it
+is almost altogether composed of vegetable matter; at the bottom it
+verges into the true soil. An important effect of this decayed
+vegetation is to restrain the movement of the surface water. Even in
+the heaviest rains, provided the mass be not frozen, the water is
+taken into it and delivered in the manner of springs to the larger
+streams. We can better note the measure of this effect by observing
+the difference in the ground covered by this primeval forest and that
+which we find near by which has been converted into tilled fields.
+With the same degree of rapidity in the flow, the distinct stream
+channels on the tilled ground are likely to be from twenty to a
+hundred times in length what they are on the forest bed. The result is
+that while the brook which drains the forested area maintains a
+tolerably constant flow of clean water, the other from the tilled
+ground courses only in times of heavy rain, and then is heavily
+charged with mud. In the virgin conditions of the soil the downwear is
+very slow; in its artificial state this wearing goes on so rapidly
+that the sloping fields are likely to be worn to below the soil level
+in a few score years.
+
+Not only does the natural coating of vegetation, such as our forests
+impose upon the country, protect the soil from washing away, but the
+roots of the larger plants are continually at work in various ways to
+increase the fertility and depth of the stratum. In the form of
+slender fibrils these underground branches enter the joints and bed
+planes of the rock, and there growing they disrupt the materials,
+giving them a larger surface on which decay may operate. These bits,
+at first of considerable size, are in turn broken up by the same
+action. Where the underlying rocks afford nutritious materials, the
+branches of our tap-rooted trees sometimes find their way ten feet or
+more below the base of the true soil. Not only do they thus break up
+the stones, but the nutrition which they obtain in the depths is
+brought up and deposited in the parts above the ground, as well as in
+the roots which lie in the true soil, so that when the tree dies it
+becomes available for other plants. Thus in the forest condition of a
+country the amount of rock material contributed to the deposit in
+general so far exceeds that which is taken away to the rivers by the
+underground water as to insure the deepening of the soil bed to the
+point where only the strongest roots--those belonging to our
+tap-rooted trees--can penetrate through it to the bed rocks.
+
+Almost all forests are from time to time visited by winds which uproot
+the trees. When they are thus rent from the earth, the underground
+branches often form a disk containing a thick tangle of stones and
+earth, and having a diameter of ten or fifteen feet. The writer has
+frequently observed a hundred cubic feet of soil matter, some of it
+taken from the depth of a yard or more, thus uplifted into the air. In
+the path of a hurricane or tornado we may sometimes find thousands of
+acres which have been subjected to this rude overturning--a natural
+ploughing. As the roots rot away, the _debris_ which they held falls
+outside of the pit, thus forming a little hillock along the side of
+the cavity. After a time the thrusting action of other roots and the
+slow motion of the soil down the slope restore the surface from its
+hillocky character to its original smoothness; but in many cases the
+naturalist who has learned to discern with his feet may note these
+irregularities long after it has been recovered with the forest.
+
+Great as is the effect of plants on the soil, that influence is almost
+equalled by the action of the animals which have the habit of entering
+the earth, finding there a temporary abiding place. The number of
+these ground forms is surprisingly great. It includes, indeed, a host
+of creatures which are efficient agents in enriching the earth. The
+species of earthworms, some of which occupy forested districts as well
+as the fields, have the habit of passing the soil material through
+their bodies, extracting from the mass such nutriment as it may
+contain. In this manner the particles of mineral matter become
+pulverized, and in a measure affected by chemical changes in the
+bodies of the creatures, and are thus better fitted to afford plant
+food. Sometimes the amount of the earth which the creatures take in in
+moving through their burrows and void upon the surface is sufficient
+to form annually a layer on the surface of the ground having a depth
+of one twentieth of an inch or more. It thus may well happen that the
+soil to the depth of two or three feet is completely overturned in the
+course of a few hundred years. As the particles which the creatures
+devour are rather small, the tendency is to accumulate the finer
+portions of the soil near the surface of the earth, where by solution
+they may contribute to the needs of the lowly plants. It is probably
+due to the action of these creatures that small relics of ancient men,
+such as stone tools, are commonly found buried at a considerable depth
+beneath the earth, and rarely appear upon the surface except where it
+has been subjected to deep ploughing or to the action of running
+streams.
+
+Along with the earthworms, the ants labour to overturn the soil;
+frequently they are the more effective of the two agents. The common
+species, though they make no permanent hillocks, have been observed by
+the writer to lay upon the surface each year as much as a quarter of
+an inch of sand and other fine materials which they have brought up
+from a considerable depth. In many regions, particularly in those
+occupied by glacial drift, and pebbly alluvium along the rivers, the
+effect of this action, like that of earthworms, is to bring to the
+surface the finer materials, leaving the coarser pebbles in the
+depths. In this way they have changed the superficial character of the
+soil over great areas; we may say, indeed, over a large part of the
+earth, and this in a way which fits it better to serve the needs of
+the wild plants as well as the uses of the farmer.
+
+Many thousand species of insects, particularly the larger beetles,
+have the habit of passing their larval state in the under earth. Here
+they generally excavate burrows, and thus in a way delve the soil. As
+many of them die before reaching maturity, their store of organic
+matter is contributed to the mass, and serves to nourish the plants.
+If the student will carefully examine a section of the earth either in
+its natural or in its tilled state, he will be surprised to find how
+numerous the grubs are. They may often be found to the number of a
+score or more of each cubic foot of material. Many of the species
+which develop underground come from eggs which have carefully been
+encased in organic matter before their deposition in the earth. Thus
+some of the carrion beetles are in the habit of laying their eggs in
+the bodies of dead birds or field mice, which they then bury to the
+depth of some inches in the earth. In this way nearly all the small
+birds and mammals of our woods disappear from view in a few hours
+after they are dead. Other species make balls from the dung of cattle
+in which they lay their eggs, afterward rolling the little spheres, it
+may be for hundreds of feet, to the chambers in the soil which they
+have previously prepared. In this way a great deal of animal matter is
+introduced into the earth, and contributes to its fertility.
+
+Many of our small mammals have the habit of making their dwelling
+places in the soil. Some of them, such as the moles, normally abide in
+the subterranean realm for all their lives. Others use the excavations
+as places of retreat. In any case, these excavations serve to move the
+particles of the soil about, and the materials which the animals drag
+into the earth, as well as the excrement of the creatures, act to
+enrich it. This habit of taking food underground is not limited to the
+mammals; it is common with the ants, and even the earthworms, as noted
+by Charles Darwin in his wonderful essay on these creatures, are
+accustomed to drag into their burrows bits of grass and the slender
+leaves of pines. It is not known what purpose they attain by these
+actions, but it is sufficiently common somewhat to affect the
+conditions of the soil.
+
+The result of these complicated works done by animals and plants on
+the soil is that the material to a considerable depth are constantly
+being supplied with organic matter, which, along with the mineral
+material, constitutes that part of the earth which can support
+vegetation. Experiment will readily show that neither crushed rock nor
+pure vegetable mould will of itself serve to maintain any but the
+lowliest vegetation. It requires that the two materials be mixed in
+order that the earth may yield food for ordinary plants, particularly
+for those which are of use to man, as crops. On this account all the
+processes above noted whereby the waste of plant and animal life is
+carried below the surface are of the utmost importance in the creation
+and preservation of the soil. It has been found, indeed, in almost all
+cases, necessary for the farmer to maintain the fertility of his
+fields to plough-in quantities of such organic waste. By so doing he
+imitates the work which is effected in virgin soil by natural action.
+As the process is costly in time and material, it is often neglected
+or imperfectly done, with the result that the fields rapidly diminish
+in fertility.
+
+The way in which the buried organic matter acts upon the soil is not
+yet thoroughly understood. In part it accomplishes the results by the
+materials which on its decay it contributes to the soil in a state in
+which they may readily be dissolved and taken up by the roots into
+their sap; in part, however, it is believed that they better the
+conditions by affording dwelling places for a host of lowly species,
+such as the forms which are known as bacteria. The organisms probably
+aid in the decomposition of the mineral matter, and in the conversion
+of nitrogen, which abounds in the air or the soil, into nitrates of
+potash and soda--substances which have a very great value as
+fertilizers. Some effect is produced by the decay of the foreign
+matter brought into the soil, which as it passes away leaves channels
+through which the soil water can more readily pass.
+
+By far the most general and important effect arising from the decay
+of organic matter in the earth is to be found in the carbon dioxide
+which is formed as the oxygen of the air combines with the carbon
+which all organic material contains. As before noted, water thus
+charged has its capacity for taking other substances into solution
+vastly increased, and on this solvent action depends in large part the
+decay of the bed rocks and the solution of materials which are to be
+appropriated by the plants.
+
+Having now sketched the general conditions which lead to the formation
+of soils, we must take account of certain important variations in
+their conditions due to differences in the ways in which they are
+formed and preserved. These matters are not only of interest to the
+geologist, but are of the utmost importance to the life of mankind, as
+well as all the lower creatures which dwell upon the lands. First, we
+should note that soils are divisible into three great groups, which,
+though not sharply parted from each other, are sufficiently peculiar
+for the purposes of classification. Where the earth material has been
+derived from the rocks which nearly or immediately underlie it, we
+have a group of soils which may be entitled those of immediate
+derivation--that is, derived from rocks near by, or from beds which
+once overlaid the level and have since been decayed away. Next, we
+have alluvial soils, those composed of materials which have been
+transported by streams, commonly from a great distance, and laid down
+on their flood plains. Third, the soils the mineral matters of which
+have been brought into their position by the action of glaciers; these
+in a way resemble those formed by rivers, but the materials are
+generally imperfectly sorted, coarse and fine being mingled together.
+Last of all, we have the soils due to the accumulation of blown dust
+or blown sand, which, unlike the others, occupy but a small part of
+the land surface. It would be possible, indeed, to make yet another
+division, including those areas which when emerging from the sea were
+covered with fine, uncemented detritus ready at once to serve the
+purposes of a soil. Only here and there, and but seldom, do we find
+soils of this nature.
+
+It is characteristic of soils belonging to the group to which we have
+given the title of immediate derivation that they have accumulated
+slowly, that they move very gradually down the slopes on which they
+lie, and that in all cases they represent, with a part of their mass
+at least, levels of rock which have disappeared from the region which
+they occupied. The additions made to their mass are from below, and
+that mass is constantly shrinking, generally at a pretty rapid rate,
+by the mineral matter which is dissolved and goes away with the spring
+water. They also are characteristically thin on steep slopes,
+thickening toward the base of the incline, where the diminished grade
+permits the soil to move slowly, and therefore to accumulate.
+
+In alluvial soils we find accumulations which are characterized by
+growth on their upper surfaces, and by the distant transportation of
+the materials of which they are composed. In these deposits the
+outleaching removes vast amounts of the materials, but so long as the
+floods from time to time visit their surfaces the growth of the
+deposits is continued. This growth rarely takes place from the waste
+of the bed rocks on which the alluvium lies. It is characteristic of
+alluvial soils that they are generally made up of _debris_ derived
+from fields where the materials have undergone the change which we
+have noted in the last paragraph; therefore these latter deposits have
+throughout the character which renders the mineral materials easily
+dissolved. Moreover, the mass as it is constructed is commonly mingled
+with a great deal of organic waste, which serves to promote its
+fertility. On these accounts alluvial grounds, though they vary
+considerably in fertility, commonly afford the most fruitful fields of
+any region. They have, moreover, the signal advantage that they often
+may be refreshed by allowing the flood waters to visit them, an
+action which but for the interference of man commonly takes place once
+each year. Thus in the valley of the Nile there are fields which have
+been giving rich grain harvests probably for more than four thousand
+years, without any other effective fertilizing than that derived from
+the mud of the great river.
+
+The group of glaciated soils differs in many ways from either of those
+mentioned. In it we find the mineral matter to have been broken up,
+transported, and accumulated without the influence of those conditions
+which ordinarily serve to mix rock _debris_ with organic matter during
+the process by which it is broken into bits. When vegetation came to
+preoccupy the fields made desolate by glacial action, it found in most
+places more than sufficient material to form soils, but the greater
+part of the matter was in the condition of pebbles of very hard rock
+and sand grains, fragments of silex. Fortunately, the broken-up state
+of this material, by exposing a great surface of the rocky matter to
+decay, has enabled the plants to convert a portion of the mass into
+earth fit for the uses of their roots. But as the time which has
+elapsed since the disappearance of the glaciers is much less than that
+occupied in the formation of ordinary soil, this decay has in most
+cases not yet gone very far, so that in a cubic foot of glaciated
+waste the amount of material available for plants is often only a
+fraction of that held in the soils of immediate derivation.
+
+In the greater portion of the fields occupied by glacial waste the
+processes which lead to the introduction of organic matter into the
+earth have not gone far enough to set in effective work the great
+laboratory which has to operate in order to give fertile soil. The
+pebbles hinder the penetration of the roots as well as the movement of
+insects and other animals. There has not been time enough for the
+overturning of trees to bring about a certain admixture of vegetable
+matter with the soil--in a word, the process of soil-making, though
+the first condition, that of broken-up rock, has been accomplished,
+is as yet very incomplete. It needs, indeed, care in the introduction
+of organic matter for its completion.
+
+It is characteristic of glacial soils that they are indefinitely deep.
+This often is a disadvantageous feature, for the reason that the soil
+water may pass so far down into the earth that the roots are often
+deprived of the moisture which they need, and which in ordinary soils
+is retained near the surface by the hard underlayer. On the other
+hand, where the glacial waste is made up of pebbles formed from rocks
+of varied chemical composition, which contain a considerable share of
+lime, potash, soda, and other substances which are required by plants,
+the very large surface which they expose to decay provides the soil
+with a continuous enrichment. In a cubic foot of pebbly glacial earth
+we often find that the mass offers several hundred times as much
+surface to the action of decay as is afforded by the underlying solid
+bed rock from which a soil of immediate derivation has to win its
+mineral supply. Where the pebbly glacial waste is provided with a
+mixture of vegetable matter, the process of decay commonly goes
+forward with considerable rapidity. If the supply of such matter is
+large, such as may be produced by ploughing in barnyard manure or
+green crops, the nutritive value of the earth may be brought to a very
+high point.
+
+It is a familiar experience in regions where glacial soils exist that
+the earth beneath the swamps when drained is found to be
+extraordinarily well suited for farming purposes. On inspecting the
+pebbles from such places, we observe that they are remarkably decayed.
+Where the masses contain large quantities of feldspar, as is the case
+in the greater part of our granitic and other crystalline rocks, this
+material in its decomposition is converted into kaolin or feldspar
+clay, and gives the stones a peculiar white appearance, which marks
+the decomposition, and indicates the process by which a great variety
+of valuable soil ingredients are brought into a state where they may
+be available for plants.
+
+In certain parts of the glacial areas, particularly in the region near
+the margin of the ice sheet, where the glacier remained in one
+position for a considerable time, we find extensive deposits of
+silicious sand, formed of the materials which settled from the
+under-ice stream, near where they escaped from the glacial cavern.
+These kames and sand plains, because of the silicious nature of their
+materials and the very porous nature of the soil which they afford,
+are commonly sterile, or at most render a profit to the tiller by dint
+of exceeding care. Thus in Massachusetts, although the first settlers
+seized upon these grounds, and planted their villages upon them
+because the forests there were scanty and the ground free from
+encumbering boulders, were soon driven to betake themselves to those
+areas where the drift was less silicious, and where the pebbles
+afforded a share of clay. Very extensive fields of this sandy nature
+in southeastern New England have never been brought under tillage.
+Thus on the island of Martha's Vineyard there is a connected area
+containing about thirty thousand acres which lies in a very favourable
+position for tillage, but has been found substantially worthless for
+such use. The farmers have found it more advantageous to clear away
+the boulders from the coarser drift in order to win soil which would
+give them fair returns.
+
+Those areas which are occupied by soil materials which have been
+brought into their position by the action of the wind may, as regards
+their character, be divided into two very distinct groups--the dunes
+and loess deposits. In the former group, where, as we have noted (see
+page 123), the coarse sea sands or those from the shores of lakes are
+driven forward as a marching hillock, the grains of the material are
+almost always silicious. The fragments in the motion are not taken up
+into the air, but are blown along the surface. Such dune accumulations
+afford an earth which is even more sterile than that of the glacial
+sand plains, where there is generally a certain admixture of pebbles
+from rocks which by their decomposition may afford some elements of
+fertility. Fortunately for the interests of man, these wind-borne
+sands occupy but a small area; in North America, in the aggregate,
+there probably are not more than one thousand square miles of such
+deposits.
+
+Where the rock material drifted by the winds is so fine that it may
+rise into the air in the form of dust, the accumulations made of it
+generally afford a fertile soil, and this for the reason that they are
+composed of various kinds of rock, and not, as in the case of dunes,
+of nearly pure silica. In some very rare cases, where the seashore is
+bordered by coral reefs, as it is in parts of southern Florida, and
+the strand is made up of limestone bits derived from the hard parts
+which the polyps secrete, small dunes are made of limy material.
+Owing, however, in part to the relatively heavy nature of this
+substance, as well as to the rapid manner in which its grains become
+cemented together, such limestone dunes never attain great size nor
+travel any distance from their point of origin.
+
+As before noted, dust accumulations form the soil in extended areas
+which lie to the leeward of great deserts. Thus a considerable part of
+western China and much of the United States to the west of the
+Mississippi is covered by these wind-blown earths. Wherever the
+rainfall is considerable these loess deposits have proved to have a
+high agricultural value.
+
+Where a region has an earth which has recently passed from beneath the
+sea or a great lake, the surface is commonly covered by incoherent
+detritus which has escaped consolidation into hard rock by the fact
+that it has not been buried and thus brought into the laboratory of
+the earth's crust. When such a region becomes dry land, the materials
+are immediately ready to enter into the state of soil. They commonly
+contain a good deal of waste derived from the organic life which
+dwelt upon the sea bottom and was embedded in the strata as they were
+formed. Where these accumulations are made in a lake, the land
+vegetation at once possesses the field, even a single year being
+sufficient for it to effect its establishment. Where the lands emerge
+from the sea, it requires a few years for the salt water to drain away
+so that the earth can be fit for the uses of plants. In a general way
+these sea-bottom soils resemble those formed in the alluvial plains.
+They are, however, commonly more sandy, and their substances less
+penetrated by that decay which goes on very freely in the atmosphere
+because of the abundant supply of oxygen, and but slowly on the sea
+floor. Moreover, the marine deposits are generally made up in large
+part of silicious sand, a material which is produced in large
+quantities by the disruption of the rocks along the sea coast. The
+largest single field of these ocean-bottom soils of North America is
+found in the lowland region of the southern United States, a wide belt
+of country extending along the coast from the Rio Grande to New York.
+Although the streams have channelled shallow valleys in the beds of
+this region, the larger part of its surface still has the peculiar
+features of form and composition which were impressed upon it when it
+lay below the surface of the sea.
+
+Local variations in the character of the soil covering are exceedingly
+numerous, and these differences of condition profoundly affect the
+estate of man. We shall therefore consider some of the more important
+of these conditions, with special reference to their origin.
+
+The most important and distinctly marked variation in the fertility of
+soils is that which is produced by differences in the rainfall. No
+parts of the earth are entirely lacking in rain, but over considerable
+areas the precipitation does not exceed half a foot a year. In such
+realms the soil is sterile, and the natural coating of vegetation
+limited to those plants which can subsist on dew or which can take on
+an occasional growth at such times as moisture may come upon them.
+With a slight increase in precipitation, the soil rapidly increases in
+productivity, so that we may say that where as much as about ten
+inches of water enters the earth during the summer half of the year,
+it becomes in a considerable measure fit for agriculture. Observations
+indicate that the conditions of fertility are not satisfied where the
+rainfall is just sufficient to fill the pores of the soil; there must
+be enough water entering the earth to bring about a certain amount of
+outflow in the form of springs. The reason of this need becomes
+apparent when we study the evident features of those soils which,
+though from season to season charged with water, do not yield springs,
+but send the moisture away through the atmosphere. Wherever these
+conditions occur we observe that the soil in dry seasons becomes
+coated with a deposit of mineral matter, which, because of its taste,
+has received the name of alkali. The origin of this coating is as
+follows: The pores of the soil, charged from year to year with
+sufficient water to fill them, become stored with a fluid which
+contains a very large amount of dissolved mineral matter--too much,
+indeed, to permit the roots of plants, save a few species which have
+become accustomed to the conditions, to do their appointed work. In
+fact, this water is much like that of the sea, which the roots of only
+a few of our higher plants can tolerate. When the dry season comes on,
+the heat of the sun evaporates the water at the surface, leaving
+behind a coating composed of the substances which the water contains.
+The soil below acts in the manner of a lamp-wick to draw up fluid as
+rapidly as the heat burns it away. When the soil water is as far as
+possible exhausted, the alkali coating may represent a considerable
+part of the soluble matter of the soil, and in the next rainy season
+it may return in whole or in part to the under-earth, again to be
+drawn in the manner before described to the upper level. It is
+therefore only when a considerable share of the ground water goes
+forth to the streams in each year that the alkaline materials are in
+quantity kept down to the point where the roots of our crop-giving
+plants can make due use of the soil. Where, in an arid region, the
+ground can be watered from the enduring streams or from artificial
+reservoirs, the main advantage arising from the process is commonly
+found in the control which it gives the farmer in the amount of the
+soil water. He can add to the rainfall sufficient to take away the
+excess of mineral matter. When such soils are first brought under
+tillage it is necessary to use a large amount of water from the
+canals, in order to wash away the old store of alkali. After that a
+comparatively small contribution will often keep the soil in excellent
+condition for agriculture. It has been found, however, in the
+irrigated lands beside the Nile that where too much saving is
+practised in the irrigation, the alkaline coating will appear where it
+has been unknown before, and with it an unfitness of the earth to bear
+crops.
+
+Although the crust of mineral matters formed in the manner above
+described is characteristic of arid countries, and in general peculiar
+to them, a similar deposit may under peculiar conditions be formed in
+regions of great rainfall. Thus on the eastern coast of New England,
+where the tidal marshes have here and there been diked from the sea
+and brought under tillage, the dissolved mineral matters of the soil,
+which are excessive in quantity, are drawn to the surface, forming a
+coating essentially like that which is so common in arid regions. The
+writer has observed this crust on such diked lands, having a thickness
+of an eighth of an inch. In fact, this alkali coating represents
+merely the extreme operation of a process which is going on in all
+soils, and which contributes much to their fertility. When rain falls
+and passes downward into the earth, it conveys the soluble matter to a
+depth below the surface, often to beyond the point where our ordinary
+crop plants, such as the small grains, can have access to it, and
+this for the reason that their roots do not penetrate deeply. When dry
+weather comes and evaporation takes place from the surface, the fluid
+is drawn up to the upper soil layer, and there, in process of
+evaporation, deposits the dissolved materials which it contains. Thus
+the mineral matter which is fit for plant food is constantly set in
+motion, and in its movement passes the rootlets of the plants. It is
+probably on this account--at least in part--that very wet weather is
+almost as unfavourable to the farmer as exceedingly dry, the normal
+alternation in the conditions being, as is well known, best suited to
+his needs.
+
+So long as the earth is subjected to conditions in which the rainfall
+may bring about a variable amount of water in the superficial detrital
+layer, we find normal fruitful soils, though in their more arid
+conditions they may be fit for but few species of plants. When, by
+increasing aridity, we pass to conditions where there is no tolerably
+permanent store of water in the _debris_, the material ceases to have
+the qualities of a soil, and becomes mere rock waste. At the other
+extreme of the scale we pass to conditions where the water is
+steadfastly maintained in the interstices of the detritus, and there
+again the characteristic of the soil and its fitness for the uses of
+land vegetation likewise disappear. In a word, true soil conditions
+demand the presence of moisture, but that in insufficient quantities,
+to keep the pores of the earth continually filled; where they are thus
+filled, we have the condition of swamps. Between these extremes the
+level at which the water stands in the soil in average seasons is
+continually varying. In rainy weather it may rise quite to the
+surface; in a dry season it may sink far down. As this water rises and
+falls, it not only moves, as before noted, the soluble mineral
+materials, but it draws the air into and expels it from the earth with
+each movement. This atmospheric circulation of the soil, as has been
+proved by experiment, is of great importance in maintaining its
+fertility; the successive charges of air supply the needs of the
+microscopic underground creatures which play a large part in enriching
+the soil, and the direct effect of the oxygen in promoting decay is
+likewise considerable. A part of the work which is accomplished by
+overturning the earth in tillage consists in this introduction of the
+air into the pores of the soil, where it serves to advance the actions
+which bring mineral matters into solution.
+
+[Illustration: _Mountain gorge, Himalayas, India. Note the difference
+in the slope of the eroded rocks and the effect of erosion upon them;
+also the talus slopes at the base of the cliffs which the torrent is
+cutting away. On the left of the foreground there is a little bench
+showing a recent higher line of the water._]
+
+In the original conditions of any country which is the seat of
+considerable rainfall, and where the river system is not so far
+developed as to provide channels for the ready exit of the waters, we
+commonly find very extensive swamps; these conditions of bad drainage
+almost invariably exist where a region has recently been elevated
+above the level of the sea, and still retains the form of an irregular
+rolling plain common to sea floors, and also in regions where the work
+done by glaciers has confused the drainage which the antecedent
+streams may have developed. In an old, well-elaborated river system
+swamps are commonly absent, or, if they occur, are due to local
+accidents of an unimportant nature.
+
+For our purpose swamps may be divided into three groups--climbing
+bogs, lake bogs, and marine marshes. The first two of these groups
+depend on the movements of the rain water over the land; the third on
+the action of the tides. Beginning our account with the first and most
+exceptional of these groups, we note the following features in their
+interesting history:
+
+Wherever in a humid region, on a gentle slope--say with an inclination
+not exceeding ten feet to the mile--the soil is possessed by any
+species of plants whose stems grow closely together, so that from
+their decayed parts a spongelike mass is produced, we have the
+conditions which favour the development of climbing bogs. Beginning
+usually in the shores of a pool, these plants, necessarily of a
+water-loving species, retain so much moisture in the spongy mass
+which they form that they gradually extend up the slope. Thus
+extending the margin of their field, and at the same time thickening
+the deposit which they form, these plants may build a climbing bog
+over the surface until steeps are attained where the inclination is so
+great that the necessary amount of water can not be held in the spongy
+mass, or where, even if so held, the whole coating will in time slip
+down in the manner of an avalanche.
+
+The greater part of the climbing bogs of the world are limited to the
+moist and cool regions of high latitudes, where species of moss
+belonging to the genus _Sphagnum_ plentifully flourish. These plants
+can only grow where they are continuously supplied with a bath of
+water about their roots. They develop in lake bogs as far south as
+Mexico, but in the climbing form they are hardly traceable south of
+New England, and are nowhere extensively developed within the limits
+of the United States. In more northern parts of this continent, and in
+northwestern Europe, particularly in the moist climate of Ireland,
+climbing bogs occupy great areas, and hold up their lakes of
+interstitially contained water over the slopes of hills, where the
+surface rises at the rate of thirty feet or more to the mile. So long
+as the deposit of decayed vegetable matter which has accumulated in
+this manner is thin, therefore everywhere penetrated by the fibrous
+roots of the moss, it may continue to cling to its sloping bed; but
+when it attains a considerable thickness, and the roots in the lower
+part decay, the pulpy mass, water-laden in some time of heavy rain,
+break away in a vast torrent of thick, black mud, which may inundate
+the lower lands, causing widespread destruction.
+
+In more southern countries, other water-loving plants lead to the
+formation of climbing bogs. Of these, the commonest and most effective
+are the species of reeds, of which our Indian cane is a familiar
+example. Brakes of this vegetation, plentifully mingled with other
+species of aquatic growth, form those remarkable climbing bogs known
+as the Dismal and other swamps, which numerously occur along the coast
+line of the United States from southern Maryland to eastern Texas.
+Climbing bogs are particularly interesting, not only from the fact
+that they are eminently peculiar effects of plant growth, but because
+they give us a vivid picture of those ancient morasses in which grew
+the plants that formed the beds of vegetable matter now appearing in
+the state of coal. Each such bed of buried swamp material was, with
+rare exceptions, where the accumulation took place in lakes, gathered
+in climbing bogs such as we have described.
+
+Lake bogs occur in all parts of the world, but in their best
+development are limited to relatively high latitudes, and this for the
+reason that the plants which form vegetable matter grow most
+luxuriantly in cool climates and in regions where the level of the
+basin is subject to less variation than occurs in the alternating wet
+and dry seasons which exist in nearly all tropical regions. The
+fittest conditions are found in glaciated regions, where, as before
+noted, small lakes are usually very abundant. On the shores of one of
+these pools, of size not so great that the waves may attain a
+considerable height, or in the sheltered bay of a larger lake, various
+aquatic plants, especially the species of pond lilies, take root upon
+the bottom, and spread their expanded leaves on the surface of the
+water. These flexible-leaved and elastic-stemmed plants can endure
+waves which attain no more than a foot or two of height, and by the
+friction which they afford make the swash on the shore very slight. In
+the quiet water, rushes take root, and still further protect the
+strand, so that the very delicate vegetation of the mosses, such as
+the _Sphagnum_, can fix itself on the shore.
+
+As soon as the _Sphagnum_ mat has begun its growth, the strength given
+by its interlaced fibres enables it to extend off from the shore and
+float upon the water. In this way it may rapidly enlarge, if not
+broken up by the waves, so that its front advances into the lake at
+the rate of several inches each year. While growing outwardly it
+thickens, so that the bottom of the mass gradually works down toward
+the floor of the basin. At the same time the lower part of the sheet,
+decaying, contributes a shower of soft peat mud to the floor of the
+lake. In this way, growing at its edge, deepening, and contributing to
+an upgrowth from the bottom, a few centuries may serve entirely to
+fill a deep basin with peaty accumulation. In general, however, the
+surface of the bog closes over the lake before the accumulation has
+completely filled the shoreward portions of the area. In these
+conditions we have what is familiarly known as a quaking bog, which
+can be swayed up and down by a person who quickly stoops and rises
+while standing on the surface. In this state the tough and thick sheet
+of growing plants is sufficient to uphold a considerable weight, but
+so elastic that the underlying water can be thrown into waves. Long
+before the bog has completely filled the lake with the peaty
+accumulations the growth of trees is apt to take place on its surface,
+which often reduces the area to the appearance of a very level wet
+wood.
+
+[Illustration: Fig. 17.--Diagram showing beginning of peat bog: A,
+lake; B, lilies and rushes; C, lake bog; D, climbing bog.]
+
+Climbing and lake bogs in the United States occupy a total area of
+more than fifty thousand square miles. In all North America the total
+area is probably more than twice as great. Similar deposits are
+exceedingly common in the Eurasian continent and in southern
+Patagonia. It is probable that the total amount of these fields in
+different parts of the world exceeds half a million square miles.
+These two groups of fresh-water swamps have an interest, for the
+reason that when reduced to cultivation by drainage and by subsequent
+removal of the excess of peaty matter, by burning or by natural decay,
+afford very rich soil. The fairest fields of northern Europe,
+particularly in Great Britain and Ireland, have been thus won to
+tillage. In the first centuries of our era a large part of
+England--perhaps as much as one tenth of the ground now tilled in that
+country--was occupied by these lands, which retained water in such
+measure as to make them unfit for tillage, the greater portion of this
+area being in the condition of thin climbing bog. For many centuries
+much of the energy of the people was devoted to the reclamation of
+these valuable lands. This task of winning the swamp lands to
+agriculture has been more completely accomplished in England than
+elsewhere, but it has gone far on the continent of Europe,
+particularly in Germany. In the United States, owing to the fact that
+lands have been cheap, little of this work of swamp-draining has as
+yet been accomplished. It is likely that the next great field of
+improvement to be cultivated by the enterprising people will be found
+in these excessively humid lands, from which the food-giving resources
+for the support of many million people can be won.
+
+[Illustration: Fig. 18.--Diagram showing development of swamp: A,
+remains of lake; B, surface growth; c, peat.]
+
+The group of marine marshes differs in many important regards from
+those which are formed in fresh water. Where the tide visits any
+coast line, and in sheltered positions along that shore, a number of
+plants, mostly belonging to the group of grasses, species which have
+become accustomed to having their roots bathed by salt water, begin
+the formation of a spongy mat, which resembles that composed of
+_Sphagnum_, only it is much more solid. This mat of the marine marshes
+soon attains a thickness of a foot or more, the upper or growing
+surface lying in a position where it is covered for two or three hours
+at each visit of the tide. Growing rapidly outward from the shore, and
+having a strength which enables it to resist in a tolerably effective
+manner waves not more than two or three feet high, this accumulation
+makes head against the sea. To a certain extent the waves undermine
+the front of the sheet and break up masses of it, which they
+distribute over the shallow bottom below the level at which these
+plants can grow. In this deeper water, also, other marine animals and
+plants are continually developing, and their remains are added to the
+accumulations which are ever shallowing the water, thus permitting a
+further extension of the level, higher-lying marsh. This process
+continues until the growth has gone as far as the scouring action of
+the tidal currents will permit. In the end the bay, originally of
+wide-open water, is only such at high tide. For the greater part of
+the time it appears as broad savannas, whose brilliant green gives
+them the aspect of rare fertility.
+
+Owing to the conditions of their growth, the deposits formed in marine
+marshes contain no distinct peat, the nearest approach to that
+substance being the tangle of wirelike roots which covers the upper
+foot or so of the accumulation. The greater part of the mass is
+composed of fine silt, brought in by the streams of land water which
+discharge into the basin, and by the remains of animals which dwelt
+upon the bottom or between the stalks of the plants that occupy the
+surface of the marshes. These interspaces afford admirable shelter to
+a host of small marine forms. The result is, that the tidal marshes,
+as well as the lower-lying mud flats, which have been occupied by the
+mat of vegetation, afford admirable earth for tillage. Unfortunately,
+however, there are two disadvantages connected with the redemption of
+such lands. In the first place, it is necessary to exclude the sea
+from the area, which can only be accomplished by considerable
+engineering work; in the second place, the exclusion of the tide
+inevitably results in the silting up of the passage by which the water
+found its way to the sea. As these openings are often used for
+harbours, the effect arising from their destruction is often rather
+serious. Nevertheless, in some parts of the world very extensive and
+most fertile tracts of land have thus been won from the sea; a large
+part of Holland and shore-land districts in northern Europe are made
+up of fields which were originally covered by the tide. Near the mouth
+of the Rhine, indeed, the people have found these sea-bottom soils so
+profitable that they have gone beyond the zone of the marshes, and
+have drained considerable seas which of old were permanently covered,
+even at the lowest level of the waters.
+
+On the coast of North America marine marshes have an extensive
+development, and vary much in character. In the Bay of Fundy, where
+the tides have an altitude of fifty feet or more, the energy of their
+currents is such that the marsh mat rarely forms. Its place, however,
+is taken by vast and ever-changing mud flats, the materials of which
+are swept to and fro by the moving waters. The people of this region
+have learned an art of a peculiar nature, by which they win broad
+fields of excellent land from the sea. Selecting an area of the flats,
+the surface of which has been brought to within a few feet of high
+tide, they inclose it with a stout barrier or dike, which has openings
+for the free admission of the tidal waters. Entering this basin, the
+tide, moving with considerable velocity, bears in quantities of
+sediment. In the basin, the motion being arrested, this sediment
+falls to the bottom, and serves to raise its level. In a few months
+the sheet of sediment is brought near the plane of the tidal movement,
+then the gates are closed at times when the tide has attained half of
+its height, so that the ground within the dike is not visited by the
+sea water, and can be cultivated.
+
+[Illustration: Fig. 19.--Map of Ipswich marshes, Massachusetts, formed
+behind a barrier beach.]
+
+Along the coast of New England the ordinary marine marshes attain an
+extensive development in the form of broad-grassed savannas. With this
+aspect, though with a considerable change in the plants which they
+bear, the fringe of savannas continues southward along the coast to
+northern Florida. In the region about the mouth of the Savannah River,
+so named from the vast extent of the tidal marshes, these fields
+attain their greatest development. In central and southern Florida,
+however, where the seacoast is admirably suited for their development,
+these coastal marshes of the grassy type disappear, their place being
+taken by the peculiar morasses formed by the growth of the mangrove
+tree.
+
+In the mangrove marshes the tree which gives the areas their name
+covers all the field which is visited by the tide. This tree grows
+with its crown supported on stiltlike roots, at a level above high
+tide. From its horizontal branches there grow off roots, which reach
+downward into the water, and thence to the bottom. The seeds of the
+mangrove are admirably devised so as to enable the plant to obtain a
+foothold on the mud flats, even where they are covered at low tide
+with a depth of two or three feet of water. They are several inches in
+length, and arranged with booklets at their lower ends; floating near
+the bottom, they thus catch upon it, and in a few weeks' growth push
+the shoot to the level of the water, thus affording a foundation for a
+new plantation. In this manner, extending the old forests out into the
+shallow water of the bays, and forming new colonies wherever the water
+is not too deep, these plants rapidly occupy all the region which
+elsewhere would appear in the form of savannas.
+
+[Illustration: Fig. 20.--Diagram showing mode of growth of mangroves.]
+
+The tidal marshes of North America, which may be in time converted to
+the uses of man, probably occupy an area exceeding twenty thousand
+square miles. If the work of reclaiming such lands from the sea ever
+attains the advance in this country that it has done in Holland, the
+area added to the dry land by engineering devices may amount to as
+much as fifty thousand square miles--a territory rather greater than
+the surface of Kentucky, and with a food-yielding power at least five
+times as great as is afforded by that fertile State. In fact, these
+conquests from the sea are hereafter to be among the great works which
+will attract the energies of mankind. In the arid region of the
+Cordilleras, as well as in many other countries, the soil, though
+destitute of those qualities which make it fit for the uses of man,
+because of the absence of water in sufficient amount, is, as regards
+its structure and depth, as well as its mineral contents, admirably
+suited to the needs of agriculture. The development of soils in desert
+regions is in almost all cases to be accounted for by the former
+existence in the realms they occupy of a much greater rainfall than
+now exists. Thus in the Rocky Mountain country, when the deep soils
+of the ample valleys were formed, the lakes, as we have before noted,
+were no longer dead seas, as is at present so generally the case, but
+poured forth great streams to the sea. Here, as elsewhere, we find
+evidence that certain portions of the earth which recently had an
+abundant rainfall have now become starved for the lack of that supply.
+All the soils of arid regions where the trial has been made have
+proved very fertile when subjected to irrigation, which can often be
+accomplished by storing the waters of the brief rainy season or by
+diverting those of rivers which enter the deserts from well-watered
+mountain fields. In fact, the soil of these arid realms yields
+peculiarly ample returns to the husbandman, because of certain
+conditions due to the exceeding dryness of the air. This leads to an
+absence of cloudy weather, so that from the time the seed is planted
+the growth is stimulated by uninterrupted and intense sunshine. The
+same dryness of the air leads, as we have seen, to a rapid evaporation
+from the surface, by which, in a manner before noted, the dissolved
+mineral matter is brought near the top of the soil, where it can best
+serve the greater part of our crop plants. On these accounts an acre
+of irrigated soil can be made to yield a far greater return than can
+be obtained from land of like chemical composition in humid regions.
+
+In many parts of the world, particularly in the northern and western
+portions of the Mississippi Valley, there are widespread areas, which,
+though moderately well watered, were in their virgin state almost
+without forests. In the prairie region the early settlers found the
+country unwooded, except along the margins of the streams. On the
+borders of the true prairies, however, they found considerable areas
+of a prevailingly forested land, with here and there a tract of
+prairie. There were several of these open fields south of the Ohio,
+though the country there is in general forested; one of these prairie
+areas, in the Green River district of Kentucky, was several thousand
+square miles in extent. At first it was supposed that the absence of
+trees in the open country of the Mississippi Valley was due to some
+peculiarity of the soil, but experience shows that plantations
+luxuriantly develop, and that the timber will spread rapidly in the
+natural way. In fact, if the seeds of the trees which have been
+planted since the settlement of the country were allowed to develop as
+they seek to do, it would only be a few centuries before the region
+would be forest-clad as far west as the rainfall would permit the
+plants to develop. Probably the woods would attain to near the
+hundredth meridian.
+
+In the opinion of the writer, the treeless character of the Western
+plains is mainly to be accounted for by the habit which our Indians
+had of burning the herbage of a lowly sort each year, so that the
+large game might obtain better pasturage. It is a well-known fact to
+all those who have had to deal with cattle on fields which are in the
+natural state that fire betters the pasturage. Beginning this method
+of burning in the arid regions to the west of the original forests,
+the natural action of the fire has been gradually to destroy these
+woods. Although the older and larger trees, on account of their thick
+bark and the height of their foliage above the ground, escaped
+destruction, all the smaller and younger members of the species were
+constantly swept away. Thus when the old trees died they left no
+succession, and the country assumed its prairie character. That the
+prairies were formed in this manner seems to be proved by the
+testimony which we have concerning the open area before mentioned as
+having existed in western Kentucky. It is said that around the
+timberless fields there was a wide fringe of old fire-scarred trees,
+with no undergrowth beneath their branches, and that as they died no
+kind of large vegetation took their place. When the Indians who set
+these fires were driven away, as was the case in the last decade of
+the last century, the country at once began to resume its timbered
+condition. From the margin and from every interior point where the
+trees survived, their seeds spread so that before the open land was
+all subjugated to the plough it was necessary in many places to clear
+away a thick growth of the young forest-building trees.
+
+The soils which develop on the lavas and ashes about an active volcano
+afford interesting subjects for study, for the reason that they show
+how far the development of the layer which supports vegetation may
+depend upon the character of the rocks from which it is derived. Where
+the materials ejected from a volcano lie in a rainy district, the
+process of decay which converts the rock into soil is commonly very
+rapid, a few years of exposure to the weather being sufficient to
+bring about the formation of a fertile soil. This is due to the fact
+that most lavas, as well as the so-called volcanic ashes, which are of
+the same material as the lavas, only blown to pieces, are composed of
+varied minerals, the most of which are readily attacked by the agents
+of decay. Now and then, however, we find the materials ejected from a
+particular volcano, or even the lavas and ashes of a single eruption,
+in such a chemical state that soils form upon them with exceeding
+slowness.
+
+                  *       *       *       *       *
+
+The foregoing incomplete considerations make it plain that the
+soil-covering of the earth is the result of very delicate adjustments,
+which determine the rate at which the broken-down rocks find their
+path from their original bed places to the sea. The admirable way in
+which this movement is controlled is indicated by the fact that almost
+everywhere we find a soil-covering deep enough for the use of a varied
+vegetation, but rarely averaging more than a dozen feet in depth. Only
+here and there are the rocks bare or the earth swathed in a profound
+mass of detritus. This indicates how steadfast and measured is the
+march of the rock waste from the hills to the sea. Unhappily, man,
+when by his needs he is forced to till the soil, is compelled to break
+up this ancient and perfect order. He has to strip the living mantle
+from the earth, replacing it with growth of those species which serve
+his needs. Those plants which are most serviceable--which are, indeed,
+indispensable in the higher civilization, the grains--require for
+their cultivation that the earth be stripped bare and deeply stirred
+during the rainy season, and thus subjected to the most destructive
+effect of the rainfall. The result is, that in almost all grain fields
+the rate of soil destruction vastly surpasses that at which the
+accumulation is being made. We may say, indeed, that, except in
+alluvial plains, where the soil grows by flood-made additions to its
+upper surface, no field tilled in grain can without exceeding care
+remain usable for a century. Even though the agriculturist returns to
+the earth all the chemical substances which he takes away in his
+crops, the loss of the soil by the washing away of its substance to
+the stream will inevitably reduce the region to sterility.
+
+It is not fanciful to say that the greatest misfortune which in a
+large way man has had to meet in his agriculture arises from this
+peculiar stress which grain crops put upon the soil. If these grains
+grew upon perennial plants, in the manner of our larger fruits, the
+problem of man's relation to the soil would be much simpler than it is
+at present. He might then manage to till the earth without bringing
+upon it the inevitable destruction which he now inflicts. As it is, he
+should recognise that his needs imperil this ancient and precious
+element in the earth's structure, and he should endeavour in every
+possible way to minimize the damage which he brings about. This result
+he may accomplish in certain simple ways.
+
+First, as regards the fertility of the soil, as distinguished from the
+thickness of the coating, it may be said that modern discoveries
+enable us to see the ways whereby we may for an indefinite period
+avoid the debasement of our great heritage, the food-giving earth. We
+now know in various parts of the world extensive and practically
+inexhaustible deposits, whence may be obtained the phosphates,
+potash, soda, etc., which we take from the soil in our crops. We also
+have learned ways in which the materials contained in our sewage may
+be kept from the sea and restored to the fields. In fact, the recent
+developments of agriculture have made it not only easy, but in most
+cases profitable, to avoid this waste of materials which has reduced
+so many regions to poverty. We may fairly look forward to the time,
+not long distant, when the old progressive degradation in the
+fertility of the soil coating will no longer occur. It is otherwise
+with the mass of the soil, that body of commingled decayed rock and
+vegetable matter which must possess a certain thickness in order to
+serve its needs. As yet no considerable arrest has been made in the
+processes which lead to the destruction of this earthy mass. In all
+countries where tillage is general the rivers are flowing charged with
+all they can bear away of soil material. Thus in the valley of the Po,
+a region where, if the soil were forest-clad, the down-wearing of the
+surface would probably be at no greater rate than one foot in five
+thousand years, the river bears away the soil detritus so rapidly that
+at the present time the downgoing is at the rate of one foot in eight
+hundred years, and each decade sees the soil disappear from hillsides
+which were once fertile, but are now reduced to bare rocks. All about
+the Mediterranean the traveller notes extensive regions which were
+once covered with luxuriant forests, and were afterward the seats of
+prosperous agriculture, where the soil has utterly disappeared,
+leaving only the bare rocks, which could not recover its natural
+covering in thousands of years of the enforced fallow.
+
+Within the limits of the United States the degradation of the soil,
+owing to the peculiar conditions of the country, is in many districts
+going forward with startling rapidity. It has been the habit of our
+people--a habit favoured by the wide extent of fertile and easily
+acquired frontier ground--recklessly to till their farms until the
+fields were exhausted, and then to abandon them for new ground. By
+shallow ploughing on steep hillsides, by neglect in the beginning of
+those gulches which form in such places, it is easy in the hill
+country of the eastern United States to have the soil washed away
+within twenty years after the protecting forests have been destroyed.
+The writer has estimated that in the States south of the Ohio and
+James Rivers more than eight thousand square miles of originally
+fertile ground have by neglect been brought into a condition where it
+will no longer bear crops of any kind, and over fifteen hundred miles
+of the area have been so worn down to the subsoil or the bed rock that
+it may never be profitable to win it again to agricultural uses.
+
+Hitherto, in our American agriculture, our people have been to a great
+extent pioneers; they have been compelled to win what they could in
+the cheapest possible way and with the rudest implements, and without
+much regard to the future of those who were in subsequent generations
+to occupy the fields which they were conquering from the wilderness
+and the savages. The danger is now that this reckless tillage, in a
+way justified of old, may be continued and become habitual with our
+people. It is, indeed, already a fixed habit in many parts of the
+country, particularly in the South, where a small farmer expects to
+wear out two or three plantations in the course of his natural life.
+Many of them manage to ruin from one to two hundred acres of land in
+the course of half a century of uninterrupted labour. This system
+deserves the reprobation of all good citizens; it would be well,
+indeed, if it were possible to do so, to stamp it out by the law. The
+same principle which makes it illegal for a man to burn his own
+dwelling house may fairly be applied in restraining him from
+destroying the land which he tills.
+
+There are a few simple principles which, if properly applied, may
+serve to correct this misuse of our American soil. The careful tiller
+should note that all soils whatever which lie on declivities having a
+slope of more than one foot in thirty inevitably and rapidly waste
+when subject to plough tillage. This instrument tends to smear and
+consolidate the layer of earth over which its heel runs, so that at a
+depth of a few inches below the surface a layer tolerably impervious
+to water is formed. The result is that the porous portion of the
+deposit becomes excessively charged with water in times of heavy rain,
+and moves down the hillside in a rapid manner. All such steep slopes
+should be left in their wooded state, or, if brought into use, should
+be retained as pasture lands.
+
+Where, as is often the case with the farms in hilly countries, all the
+fields are steeply inclined, it is an excellent precaution to leave
+the upper part of the slope with a forest covering. In this condition
+not only is the excessive flow of surface water diminished, but the
+moisture which creeps down the slope from the wooded area tends to
+keep the lower-lying fields in a better state for tillage, and
+promotes the decay of the underlying rocks, and thus adds to the body
+and richness of the earth.
+
+On those soils which must be tilled, even where they tend to wash
+away, the aim should be to keep the detritus open to such a depth that
+it may take in as much as possible of the rainfall, yielding the water
+to the streams through the springs. This end can generally be
+accomplished by deep ploughing; it can, in almost all cases, be
+attained by under-drainage. The effect of allowing the water to
+penetrate is not only to diminish the superficial wearing, but to
+maintain the process of subsoil and bed-rock decay by which the
+detrital covering is naturally renewed. Where, as in many parts of the
+country, the washing away of the soil can not otherwise be arrested,
+the progress of the destruction can be delayed by forming with the
+skilful use of the plough ditches of slight declivity leading along
+the hillsides to the natural waterways. One of the most satisfactory
+marks of the improvement which is now taking place in the agriculture
+of the cotton-yielding States of this country is to be found in the
+rapid increase in the use of the ditch system here mentioned. This
+system, combined with ploughing in the manner where the earth is with
+each overturning thrown uphill, will greatly reduce the destructive
+effect of rainfall on steep-lying fields. But the only effective
+protection, however, is accomplished by carefully terracing the
+slopes, so that the tilled ground lies in level benches. This system
+is extensively followed in the thickly settled portions of Europe, but
+it may be a century before it will be much used in this country.
+
+The duty of the soil-tiller by the earth with which he deals may be
+briefly summed up: He should look upon himself as an agent necessarily
+interfering with the operations which naturally form and preserve the
+soil. He should see that his work brings two risks; he may impoverish
+the accumulation of detrital material by taking out the plant food
+more rapidly than it is prepared for use. This injurious result may be
+at any time reparable by a proper use of manures. Not so, however,
+with the other form of destruction, which results in the actual
+removal of the soil materials. Where neglect has brought about this
+disaster, it can only be repaired by leaving the area to recover
+beneath the slowly formed forest coating. This process in almost all
+cases requires many thousands of years for its accomplishment. The man
+who has wrought such destruction has harmed the inheritance of life.
+
+
+
+
+                            CHAPTER IX.
+
+                     THE ROCKS AND THEIR ORDER.
+
+
+In the preceding chapters of this book the attention of the student
+has been directed mainly to the operations of those natural forces
+which act upon the surface of the earth. Incidentally the consequences
+arising from the applications of energy to the outer part of the
+planet have been attended to, but the main aim has been to set forth
+the work which solar energy, operating in the form of heat,
+accomplishes upon the lands. We have now to consider one of the great
+results of these actions, which is exhibited in the successive strata
+that make up the earth's crust.
+
+The most noteworthy effect arising from the action of the solar forces
+on the earth and their co-operation with those which originate in our
+sphere is found in the destruction of beds or other deposits of rock,
+and the removal of the materials to the floors of water basins, where
+they are again aggregated in strata, and gradually brought once more
+into a stable condition within the earth. This work is accomplished by
+water in its various states, the action being directly affected by
+gravitation. In the form of steam, water which has been built into
+rocks and volcanically expelled by tensions, due to the heat which it
+has acquired at great depths below the surface, blows forth great
+quantities of lava, which is contributed to the formation of strata,
+either directly in the solid form or indirectly, after having been
+dissolved in the sea. Acting as waves, water impelled by solar energy
+transmitted to it by the winds beats against the shores, wearing away
+great quantities of rock, which is dragged off to the neighbouring sea
+bottoms, there to resume the bedded form. Moving ice in glaciers,
+water again applying solar energy given to it by its elevation above
+the sea, most effectively grinds away the elevated parts of the crust,
+the _debris_ being delivered to the ocean. In the rain the same work
+is done, and even in the wind the power of the sun serves to abrade
+the high-lying rocks, making new strata of their fragments.
+
+As gravity enters as an element in all the movements of divided rock,
+the tendency of the waste worn from the land is to gather on to the
+bottoms of basins which contain water. Rarely, and only in a small
+way, this process results in the accumulation of lake deposits; the
+greater part of the work is done upon the sea floor. When the beds are
+formed in lake basins, they may be accumulated in either of two very
+diverse conditions. They may be formed in what are called dead seas,
+in which case the detrital materials are commonly small in amount, for
+the reason that the inflowing streams are inconsiderable; in such
+basins there is normally a large share of saline materials, which are
+laid down by the evaporation of the water. In ordinary lakes the
+deposits which are formed are mostly due to the sediment that the
+rivers import. These materials are usually fine-grained, and the sand
+or pebbles which they contain are plentifully mingled with clay. Hence
+lake deposits are usually of an argillaceous nature. As organic life,
+such as secretes limestone, is rarely developed to any extent in lake
+basins, limy beds are very rarely formed beneath those areas of water.
+Where they occur, they are generally due to the fact that rivers
+charged with limy matter import such quantities of the substance that
+it is precipitated on the bottom.
+
+As lake deposits are normally formed in basins above the level of the
+sea, and as the drainage channels of the basins are always cutting
+down, the effect is to leave such strata at a considerable height
+above the sea level, where the erosive agents may readily attack them.
+In consequence of this condition, lacustrine beds are rarely found of
+great antiquity; they generally disappear soon after they are formed.
+Where preserved, their endurance is generally to be attributed to the
+fact that the region they occupy has been lowered beneath the sea and
+covered by marine strata.
+
+The great laboratory in which the sedimentary deposits are
+accumulated, the realm in which at least ninety-nine of the hundred
+parts of these materials are laid down, is the oceanic part of the
+earth. On the floors of the seas and oceans we have not only the
+region where the greater part of the sedimentation is effected, but
+that in which the work assumes the greatest variety. The sea bottoms,
+as regards the deposits formed upon them, are naturally divided into
+two regions--the one in which the _debris_ from the land forms an
+important part of the sediment, and the other, where the remoteness
+of the shores deprives the sediment of land waste, or at least of
+enough of that material in any such share as can affect the character
+of the deposits.
+
+What we may term the littoral or shore zone of the sea occupies a belt
+of prevailingly shallow water, varying in width from a few score to a
+few hundred miles. Where the bottom descends steeply from the coast,
+where there are no strong off-shore setting currents, and where the
+region is not near the mouth of a large river which bears a great tide
+of sediment to the sea, the land waste may not affect the bottom for
+more than a mile or two from the shore. Where these conditions are
+reversed, the _debris_ from the air-covered region may be found three
+or four hundred miles from the coast line. It should also be noted
+that the incessant up-and-down goings of the land result in a constant
+change in the position of the coast line, and consequently in the
+extension of the land sediment, in the course of a few geological
+periods over a far wider field of sea bottom than that to which they
+would attain if the shores remained steadfast.
+
+It is characteristic of the sediments deposited within the influence
+of the continental detritus that they vary very much in their action,
+and that this variation takes place not only horizontally along the
+shores in the same stratum, but vertically, in the succession of the
+beds. It also may be traced down the slope from the coast line to deep
+water. Thus where all the _debris_ comes from the action of the waves,
+the deposits formed from the shore outwardly will consist of coarse
+materials, such as pebbles near the coast, of sand in the deeper and
+remoter section, and of finer silt in the part of the deposit which is
+farthest out. With each change in the level of the coast line the
+position of these belts will necessarily be altered. Where a great
+river enters the sea, the changes in the volume of sediment which it
+from time to time sends forth, together with the alternations in the
+position of its point of discharge, led to great local complexities in
+the strata. Moreover, the turbid water sent forth by the stream may,
+as in the case of the tide from the Amazon, be drifted for hundreds of
+miles along the coast line or into the open sea.
+
+The most important variations which occur in the deposits of the
+littoral zone are brought about by the formations of rocks more or
+less composed of limestone. Everywhere the sea is, as compared with
+lake waters, remarkably rich in organic life. Next the shore, partly
+because the water is there shallow, but also because of its relative
+warmth and the extent to which it is in motion, organic life, both
+that of animals and plants, commonly develops in a very luxuriant way.
+Only where the bottom is composed of drifting sands, which do not
+afford a foothold for those species which need to rest upon the shore,
+do we fail to find that surface thickly tenanted with varied forms.
+These are arranged according to the depth of the bottom. The species
+of marine plants which are attached to fixed objects are limited to
+the depth within which the sunlight effectively penetrates the water;
+in general, it may be said that they do not extend below a depth of
+one hundred feet. The animal forms are distributed, according to their
+kinds, over the floor, but few species having the capacity to endure
+any great range in the pressure of the sea water. Only a few forms,
+indeed, extend from low tide to the depth of a thousand feet.
+
+The greatest development of organic life, the realm in which the
+largest number of species occur, and where their growth is most rapid,
+lies within about a hundred feet of the low-tide level. Here sunlight,
+warmth, and motion in the water combine to favour organic development.
+It is in this region that coral reefs and other great accumulations of
+limestone, formed from the skeletons of polyps and mollusks, most
+abundantly occur. These deposits of a limy nature depend upon a very
+delicate adjustment of the conditions which favour the growth of
+certain creatures; very slight geographic changes, by inducing
+movements of sand or mud, are apt to interrupt their formation,
+bringing about a great and immediate alteration in the character of
+the deposits. Thus it is that where geologists find considerable
+fields of rock, where limestones are intercalated with sandstones and
+deposits of clay, they are justified in assuming that the strata were
+laid down near some ancient shore. In general, these coast deposits
+become more and more limy as we go toward the tropical realms, and
+this for the reason that the species which secrete large amounts of
+lime are in those regions most abundant and attain the most rapid
+growth. The stony polyps, the most vigorous of the limestone makers,
+grow in large quantities only in the tropical realm, or near to it,
+where ocean streams of great warmth may provide the creatures with the
+conditions of temperature and food which they need.
+
+As we pass from the shore to the deeper sea, the share of land
+detritus rapidly diminishes until, as before remarked, at the distance
+of five hundred miles from the coast line, very little of that waste,
+except that from volcanoes, attains the bottom of the sea. By far the
+larger part of the contributions which go to the formation of these
+deep-sea strata come from organic remains, which are continually
+falling upon the sea floor. In part, this waste is derived from
+creatures which dwell upon the bottom; in considerable measure,
+however, it is from the dead bodies of those forms which live near the
+surface of the sea, and which when dying sink slowly through the
+intermediate realm to the bottom.
+
+Owing to the absence of sunlight, the prevailingly cold water of the
+deeper seas, and the lack of vegetation in those realms, the growth of
+organic forms on the deep-sea floor is relatively slow. Thus it
+happens that each shell or other contribution to the sediment lies for
+some time on the bottom before it is buried. While in this condition
+it is apt to be devoured by some of the many species which dwell on
+the bottom and subsist from the remains of animals and plants which
+they find there. In all cases the fossilization of any form depends
+upon the accumulation of sediment before the processes of destruction
+have overtaken them, and among these processes we must give the first
+place to the creatures which subsist on shells, bones, or other
+substances of like nature which find their way to the ocean floor. In
+the absolute darkness, the still water, and the exceeding cold of the
+deeper seas, animals find difficult conditions for development.
+Moreover, in this deep realm there is no native vegetation, and, in
+general, but little material of this nature descends to the bottom
+from the surface of the sea. The result is, the animals have to
+subsist on the remains of other animals which at some step in the
+succession have obtained their provender from the plants which belong
+on the surface or in the shallow waters of the sea. This limitation
+of the food supply causes the depths of the sea to be a realm of
+continual hunger, a region where every particle of organic matter is
+apt to be seized upon by some needy creature.
+
+In consequence of the fact that little organic matter on the deeper
+sea floors escapes being devoured, the most of the material of this
+nature which goes into strata enters that state in a finely divided
+condition. In the group of worms alone--forms which in a great
+diversity of species inhabit the sea floor--we find creatures which
+are specially adapted to digesting the _debris_ which gathers on the
+sea bottom. Wandering over this surface, much in the manner of our
+ordinary earthworms, these creatures devour the mud, voiding the
+matter from their bodies in a yet more perfectly divided form. Hence
+it comes about that the limestone beds, so commonly formed beneath the
+open seas, are generally composed of materials which show but few and
+very imperfect fossils. Studying any series of limestone beds, we
+commonly find that each layer, in greater or less degree, is made up
+of rather massive materials, which evidently came to their place in
+the form of a limy mud. Very often this lime has crystallized, and
+thus has lost all trace of its original organic structure.
+
+One of the conspicuous features which may be observed in any
+succession of limestone beds is the partings or divisions into layers
+which occur with varied frequency. Sometimes at vertical intervals of
+not more than one or two inches, again with spacings of a score of
+feet, we find divisional planes, which indicate a sudden change in the
+process of rock formation. The lime disappears, and in place of it we
+have a thin layer of very fine detritus, which takes on the form of a
+clay. Examining these partings with care, we observe that on the upper
+surface on the limestone the remains of the animal which dwelt on the
+ancient sea floor are remarkably well preserved, they having evidently
+escaped the effect of the process which reduced their ancestors,
+whose remains constitute the layer, to mud. Furthermore, we note that
+the shaly layer is not only lacking in lime, but commonly contains no
+trace of animals such as might have dwelt on the bottom. The fossils
+it bears are usually of species which swam in the overlying water and
+came to the bottom after death. Following up through the layer of
+shale, we note that the ordinary bottom life gradually reappears, and
+shortly becomes so plentiful that the deposit resumes the character
+which it had before the interruption began. Often, however, we note
+that the assemblage of species which dwelt on the given area of sea
+floor has undergone a considerable change. Forms in existence in the
+lower layer may be lacking in the upper, their place being taken by
+new varieties.
+
+So far the origin of these divisional planes in marine deposits has
+received little attention from geologists; they have, indeed, assumed
+that each of these alterations indicates some sudden disturbance of
+the life of the sea floors. They have, however, generally assumed that
+the change was due to alterations in the depth of the sea or in the
+run of ocean currents. It seems to the writer, however, that while
+these divisions may in certain cases be due to the above-mentioned
+and, indeed, to a great variety of causes, they are in general best to
+be explained by the action of earthquakes. Water being an exceedingly
+elastic substance, an earthquake passes through it with much greater
+speed than it traverses the rocks which support the ocean floor. The
+result is that, when the fluid and solid oscillate in the repeated
+swingings which a shock causes, they do not move together, but rub
+over each other, the independent movements having the swing of from a
+few inches to a foot or two in shocks of considerable energy.
+
+When the sea bottom and the overlying water, vibrating under the
+impulse of an earthquake shock, move past each other, the inevitable
+result is the formation of muddy water; the very fine silt of the
+bottom is shaken up into the fluid, which afterward descends as a
+sheet to its original position. It is a well-known fact that such
+muddying of water, in which species accustomed to other conditions
+dwell, inevitably leads to their death by covering their breathing
+organs and otherwise disturbing the delicately balanced conditions
+which enable them to exist. We find, in fact, that most of the tenants
+of the water, particularly the forms which dwell upon the bottom, are
+provided with an array of contrivances which enable them to clear away
+from their bodies such small quantities of silt as may inconvenience
+them. Thus, in the case of our common clam, the breathing organs are
+covered with vibratory cilia, which, acting like brooms, sweep off any
+foreign matter which may come upon their surfaces. Moreover, the
+creature has a long, double, spoutlike organ, which it can elevate
+some distance above the bottom, through which it draws and discharges
+the water from which it obtains food and air. Other forms, such as the
+crinoids, or sea lilies, elevate the breathing parts on top of tall
+stems of marvellous construction, which brings those vital organs at
+the level, it may be, of three or four feet above the zone of mud. In
+consequence of the peculiar method of growth, the crinoids often
+escape the damage done by the disturbance of the bottom, and thus form
+limestone beds of remarkable thickness; sometimes, indeed, we find
+these layers composed mainly of crinoidal remains, which exhibit only
+slight traces of partings such as we have described, being essentially
+united for the depth of ten or twenty feet. Where the layers have been
+mainly accumulated by shellfish, their average thickness is less than
+half a foot.
+
+When we examine the partitions between the layers of limestone, we
+commonly find that, however thin, they generally extend for an
+indefinite distance in every direction. The writer has traced some of
+these for miles; never, indeed, has he been able to find where they
+disappeared. This fact makes it clear that the destruction which took
+place at the stage where these partings were formed was widespread; so
+far as it was due to earthquake shocks, we may fairly believe that in
+many cases it occurred over areas which were to be measured by tens of
+thousands of square miles. Indeed, from what we know of earthquake
+shocks, it seems likely that the devastation may at times have
+affected millions of square miles.
+
+Another class of accidents connected with earthquakes may also
+suddenly disturb the mud on the sea bottom. When, as elsewhere noted,
+a shock originates beneath the sea, the effect is suddenly to elevate
+the water over the seat of the jarring and the regions thereabouts to
+the height of some feet. This elevation quickly takes the shape of a
+ringlike wave, which rolls off in every direction from its point of
+origin. Where the sea is deep, the effect of this wave on the bottom
+may be but slight; but as the undulation attains shallower water, and
+in proportion to the shoaling, the front of the surge is retarded in
+its advance by the friction of the bottom, while the rear part, being
+in deeper water, crowds upon the advancing line. The action is
+precisely that which has been described as occurring in wind-made
+waves as they approach the beach; but in this last-named group of
+undulations, because of the great width of the swell, the effect of
+the shallowing is evident in much deeper water. It is likely that at
+the depth of a thousand feet the passing of one of these vast surges
+born of earthquakes may so stir the mud of the sea floor as to bring
+about a widespread destruction of life, and thus give rise to many of
+the partitions between strata.
+
+If we examine with the microscope the fine-grained silts which make up
+the shaly layers between limestones, we find the materials to be
+mostly of inorganic origin. It is hard to trace the origin of the
+mineral matter which it contains; some of the fragments are likely to
+prove of Volcanic origin; others, bits of dust from meteorites; yet
+others, dust blown from the land, which may, as we know, be conveyed
+for any distance across the seas. Mingled with this sediment of an
+inorganic origin we almost invariably find a share of organic waste,
+derived not from creatures which dwelt upon the bottom, but from those
+which inhabited the higher-lying waters. If, now, we take a portion of
+the limestone layer which lies above or below the shale parting, and
+carefully dissolve out with acids the limy matter which it contains,
+we obtain a residuum which in general character, except so far as the
+particles may have been affected by the acid, is exactly like the
+material which forms the claylike partition. We are thus readily led
+to the conclusion that on the floors of the deeper seas there is
+constantly descending, in the form of a very slow shower, a mass of
+mineral detritus. Where organic life belonging to the species which
+secrete hard shells or skeletons is absent, this accumulation,
+proceeding with exceeding slowness, gradually accumulates layers,
+which take on a shaly character. Where limestone-making animals
+abound, they so increase the rate of deposition that the proportion of
+the mineral material in the growing strata is very much reduced; it
+may, indeed, become as small as one per cent of the mass. In this case
+we may say that the deposit of limestone grew a hundred times as fast
+as the intervening beds of shale.
+
+The foregoing considerations make it tolerably clear that the sea
+floor is in receipt of two diverse classes of sediment--those of a
+mineral and those of an organic origin. The mineral, or inorganic,
+materials predominate along the shores. They gradually diminish in
+quantity toward the open sea, where the supply is mainly dependent on
+the substances thrown forth from volcanoes, on pumice in its massive
+or its comminuted form--i.e., volcanic dust, states of lava in which
+the material, because of the vesicles which it contains, can float for
+ages before it comes to rest on the sea bottom. Variations in the
+volcanic waste contributed to the sea floor may somewhat affect the
+quantity of the inorganic sediments, but, as a whole, the downfalling
+of these fragments is probably at a singularly uniform rate. It is
+otherwise with the contributions of sediment arising from organic
+forms. This varies in a surprising measure. On the coral reefs, such
+as form in the mid oceans, the proportion of matter which has not come
+into the accumulation through the bodies of animals and plants may be
+as small as one tenth of one per cent, or less. In the deeper seas, it
+is doubtful whether the rate of animal growth is such as to permit the
+formation of any beds which have less than one half of their mass made
+up of materials which fell through the water.
+
+In certain areas of the open seas the upper part of the water is dwelt
+in by a host of creatures, mostly foraminifera, which extract
+limestone from the water, and, on dying, send their shells to the
+bottom. Thus in the North Atlantic, even where the sea floor is of
+great depth beneath the surface, there is constantly accumulating a
+mass of limy matter, which is forming very massive limestone strata,
+somewhat resembling chalk deposits, such as abundantly occur in Great
+Britain, in the neighbouring parts of Europe, in Texas, and elsewhere.
+Accumulations such as this, where the supply is derived from the
+surface of the water, are not affected by the accidents which divide
+beds made on the bottom in the manner before described. They may,
+therefore, have the singularly continuous character which we note in
+the English chalk, where, for the thickness of hundreds of feet, we
+may have no evident partitions, except certain divisions, which have
+evidently originated long after the beds were formed.
+
+We have already noted the fact that, while the floors of the deeper
+seas appear to lack mountainous elevations, those arising from the
+folding of strata, they are plentifully scattered over with volcanic
+cones. We may therefore suppose that, in general, the deposits formed
+on the sea floor are to a great extent affected by the materials which
+these vents cast forth. Lava streams and showers represent only a
+part of the contributions from volcanoes, which finally find their way
+to the bottom. In larger part, the materials thrown forth are probably
+first dissolved in the water and then taken up by the organic species;
+only after the death of these creatures does the waste go to the
+bottom. As hosts of these creatures have no solid skeleton to
+contribute to the sea floor, such mineral matter as they may obtain is
+after their death at once restored to the sea.
+
+Not only does the contribution of organic sediment diminish in
+quantity with the depth which is attained, but the deeper parts of the
+ocean bed appear to be in a condition where no accumulations of this
+nature are made, and this for the reason that the water dissolves the
+organic matter more rapidly than it is laid down. Thus in place of
+limestone, which would otherwise form, we have only a claylike
+residuum, such as is obtained when we dissolve lime rocks in acids.
+This process of solution, by which the limy matter deposited on the
+bottom is taken back into the water, goes on everywhere, but at a rate
+which increases with the depth. This increase is due in part to the
+augmentation of pressure, and in part to the larger share of carbonic
+dioxide which the water at great depths holds. The result is, that
+explorations with the dredge seem to indicate that on certain parts of
+the deeper sea floors the rocks are undergoing a process of
+dissolution comparable to that which takes place in limestone caverns.
+So considerable is the solvent work that a large part of the inorganic
+waste appears to be taken up by the waters, so as to leave the bottom
+essentially without sedimentary accumulations. The sea, in a word,
+appears to be eating into rocks which it laid down before the
+depression attained its present great depth.
+
+We should here note something of the conditions which determine the
+supply of food which the marine animals obtain. First of all, we may
+recur to the point that the ocean waters appear to contain something
+of all the earth materials which do not readily decompose when they
+are taken into the state of solution. These mineral substances,
+including the metals, are obtained in part from the lands, through the
+action of the rain water and the waves, but perhaps in larger share
+from the volcanic matter which, in the form of floating lava, pumice,
+or dust, is plentifully delivered to the sea. Except doubtfully, and
+at most in a very small way, this chemical store of the sea water can
+not be directly taken into the structures of animals; it can only be
+immediately appropriated by the marine plants. These forms can only
+develop in that superficial realm of the seas which is penetrated by
+the sunlight, or say within the depth of five hundred feet, mostly
+within one hundred feet of the surface, about one thirtieth of the
+average, and about one fiftieth of the maximum ocean depth. On this
+marine plant life, and in a small measure on the vegetable matter
+derived from the land, the marine animals primarily depend for their
+provender. Through the conditions which bring about the formation of
+_Sargassum_ seas, those areas of the ocean where seaweeds grow afloat,
+as well as by the water-logging and weighting down of other vegetable
+matter, some part of the plant remains is carried to the sea floor,
+even to great depths; but the main dependence of the deep-sea forms of
+animals is upon other animal forms, which themselves may have obtained
+their store from yet others. In fact, in any deep-sea form we might
+find it necessary to trace back the food by thousands of steps before
+we found the creature which had access to the vegetable matter. It is
+easy to see how such conditions profoundly limit the development of
+organic being in the abysm of the ocean.
+
+The sedentary animals, or those which are fixed to the sea bottom--a
+group which includes the larger part of the marine species--have to
+depend for their sustenance on the movement of the water which passes
+their station. If the seas were perfectly still, none of these
+creatures except the most minute could be fed; therefore the currents
+of the ocean go far by their speed to determine the rate at which life
+may flourish. At great depths, as we have seen, these movements are
+practically limited to that which is caused by the slow movement which
+the tide brings about. The amount of this motion is proportional to
+the depth of the sea; in the deeper parts, it carries the water to and
+fro twice each day for the distance of about two hundred and fifty
+feet. In the shallower water this motion increases in proportion to
+the shoaling, and in the regions near the shores the currents of the
+sea which, except the massive drift from the poles, do not usually
+touch the bottom, begin to have their influence. Where the water is
+less than a hundred feet in depth, each wave contributes to the
+movement, which attains its maximum near the shore, where every surge
+sweeps the water rapidly to and fro. It is in this surge belt, where
+the waves are broken, that marine animals are best provided with food,
+and it is here that their growth is most rapid. If the student will
+obtain a pint of water from the surf, he will find that it is clouded
+by fragments of organic matter, the quantity in a pound of the fluid
+often amounting to the fiftieth part of its weight. He will thus
+perceive that along the shore line, though the provision of victuals
+is most abundant, the store is made from the animals and plants which
+are ground up in the mill. In a word, while the coast is a place of
+rapid growth, it is also a region of rapid destruction; only in the
+case of the coral animals, which associate their bodies with a number
+of myriads in large and elaborately organized communities, do we find
+animals which can make such head against the action of the waves that
+they can build great deposits in their realm.
+
+It should be noted that a part of the advantage which is afforded to
+organic life by the shore belt is due to the fact that the waters are
+there subjected to a constant process of aeration by the whipping into
+foam and spray which occurs where the waves overturn.
+
+It will be interesting to the student to note the great number of
+mechanical contrivances which have been devised to give security to
+animals and plants which face these difficult conditions arising from
+successive violent blows of falling water. Among these may be briefly
+noted those of the limpets--mollusks which dwell in a conical shell,
+which faces the water with a domelike outside, and which at the moment
+of the stroke is drawn down upon the rock by the strong muscle which
+fastens the creature to its foundation. The barnacles, which with
+their wedge-shaped prows cut the water at the moment of the stroke,
+but open in the pauses between the waves, so that the creature may
+with its branching arms grasp at the food which floats about it; the
+nullipores, forms of seaweed which are framed of limestone and cling
+firmly to the rock--afford yet other instances of protective
+adaptations contrived to insure the safety of creatures which dwell in
+the field of abundant food supply.
+
+                  *       *       *       *       *
+
+The facts above presented will show the reader that the marine
+sediments are formed under conditions which permit a great variety in
+the nature of the materials of which they are composed. As soon as the
+deposits are built into rocks and covered by later accumulations,
+their materials enter the laboratory of the under earth, where they
+are subjected to progressive changes. Even before they have attained a
+great depth, through the laying down of later deposits upon them,
+changes begin which serve to alter their structure. The fragments of a
+soluble kind begin to be dissolved, and are redeposited, so that the
+mass commonly becomes much more solid, passing from the state of
+detritus to that of more or less solid rock. When yet more deeply
+buried, and thereby brought into a realm of greater warmth, or perhaps
+when penetrated by dikes and thereby heated, these changes go yet
+further. More of the material is commonly rearranged by solution and
+redeposition, so that limestone may be converted into crystalline
+marble, granular sandstones into firm masses, known as quartzites, and
+clays into the harder form of slate. Where the changes go to the
+extreme point, rocks originally distinctly bedded probably may be so
+taken to pieces and made over that all traces of their stratification
+may be destroyed, all fossils obliterated, and the stone transformed
+into mica schist, or granite or other crystalline rock. It may be
+injected into the overlying strata in the form of dikes, or it may be
+blown forth into the air through volcanoes. Involved in
+mountain-folding, after being more or less changed in the manner
+described, the beds may become tangled together like the rumpled
+leaves of a book, or even with the complexity of snarled thread. All
+these changes of condition makes it difficult for the geologist to
+unravel the succession of strata so that he may know the true order of
+the rocks, and read from them the story of the successive geological
+periods. This task, though incomplete, has by the labours of many
+thousand men been so far advanced that we are now able to divide the
+record into chapters, the divisions of the geologic ages, and to give
+some account of the succession of events, organic and geographic,
+which have occurred since life began to write its records.
+
+
+                           EARTHQUAKES.
+
+In ordinary experience we seem to behold the greater part of the earth
+which meets our eyes as fixed in its position. A better understanding
+shows us that nothing in this world is immovable. In the realm of the
+inorganic world the atoms and molecules even in solid bodies have to
+be conceived as endowed with ceaseless though ordered motions. Even
+when matter is built into the solid rock, it is doubtful whether any
+grain of it ever comes really to rest. Under the strains which arise
+from the contraction of the earth's interior and the chemical changes
+which the rocks undergo, each bit is subject to ever-changing
+thrusts, which somewhat affect its position. If we in any way could
+bring a grain of sand from any stratum under a microscope, so that we
+could perceive its changes of place, we should probably find that it
+was endlessly swaying this way and that, with reference to an ideally
+fixed point, such as the centre of the earth. But even that centre,
+whether of gravity or of figure, is probably never at rest.
+
+Earth movements may be divided into two groups--those which arise from
+the bodily shifting of matter, which conveys the particles this way or
+that, or, as we say, change their place, and those which merely
+produce vibration, in which the particles, after their vibratory
+movement, return to their original place. For purposes of illustration
+the first, or translatory motion, may be compared to that which takes
+place when a bell is carried along upon a locomotive or a ship; and
+the second, or vibratory movement, to what takes place when the bell
+is by a blow made to ring. It is with these ringing movements, as we
+may term them, that we find ourselves concerned when we undertake the
+study of earthquakes.
+
+It is desirable that the reader should preface his study of
+earthquakes by noting the great and, at the same time, variable
+elasticity of rocks. In the extreme form this elasticity is very well
+shown when a toy marble, which is made of a close-textured rock, such
+as that from which it derives its name, is thrown upon a pavement
+composed of like dense material. Experiment will show that the little
+sphere can often be made to bounce to the height of twenty feet
+without breaking. If, then, with the same energy the marble is thrown
+upon a brick floor, the rebound will be very much diminished. It is
+well to consider what happens to produce the rebound. When the sphere
+strikes the floor it changes its shape, becoming shorter in the axis
+at right angles to the point which was struck, and at the same instant
+expanded along the equator of that axis. The flattening remains for
+only a small fraction of a second; the sphere vibrates so that it
+stretches along the line on which it previously shortened, and, as
+this movement takes place with great swiftness, it may be said to
+propel itself away from the floor. At the same time a similar movement
+goes on in the rock of the floor, and, where the rate of vibration is
+the same, the two kicks are coincident, and so the sphere is impelled
+violently away from the point of contact. Where the marble comes in
+contact with brick, in part because of the lesser elasticity of that
+material, due to its rather porous structure, and partly because it
+does not vibrate at the same rate as the marble, the expelling blow is
+much less strong.
+
+All rocks whatever, even those which appear as incoherent sands, are
+more or less set into vibratory motion whenever they are struck by a
+blow. In the crust of the earth various accidents occur which may
+produce that sudden motion which we term a blow. When we have examined
+into the origin of these impulses, and the way in which they are
+transmitted through the rocks, we obtain a basis for understanding
+earthquake shocks. The commonest cause of the jarrings in the earth is
+found in the formation of fractures, known as faults. If the reader
+has ever been upon a frozen lake at a time when the weather was
+growing colder, and the ice, therefore, was shrinking, he may have
+noted the rending sound and the slight vibration which comes with the
+formation of a crack traversing the sheet of ice. At such a time he
+feels a movement which is an earthquake, and which represents the
+simpler form of those tremors arising from the sudden rupture of fault
+planes. If he has a mind to make the experiment, he may hang a bullet
+by a thread from a small frame which rests upon the ice, and note that
+as the vibration occurs the little pendulum sways to and fro, thus
+indicating the oscillations of the ice. The same instrument will move
+in an identical manner when affected by a quaking in the rocks.
+
+Where the rocks are set in vibration by a rent which is formed in
+them, the phenomena are more complicated, and often on a vastly larger
+scale than in the simple conditions afforded by a sheet of ice. The
+rocks on either side of the rupture generally slide over each other,
+and the opposing masses are rent in their friction upon one another;
+the result is, not only the first jar formed by the initial fracture,
+but a great many successive movements from the other breakages which
+occur. Again, in the deeper parts of the crust, the fault fissures are
+often at the moment of their formation filled by a violent inrush of
+liquid rock. This, as it swiftly moves along, tears away masses from
+the walls, and when it strikes the end of the opening delivers a blow
+which may be of great violence. The nature of this stroke may be
+judged by the familiar instance where the relatively slow-flowing
+stream from a hydrant pipe is suddenly choked by closing the stopcock.
+Unless the plumber provides a cushion of air to diminish the energy of
+the blow, it is often strong enough to shake the house. Again, when
+steam or other gases are by a sudden diminution of pressure enabled to
+expand, they may deliver a blow which is exactly like that caused by
+the explosion of gunpowder, which, even when it rushes against the
+soft cushion of the air, may cause a jarring that may be felt as well
+as heard to a great distance. Such movements very frequently occur in
+the eruptions of volcanoes; they cause a quivering of the earth, which
+may be felt for a great distance from the immediate seat of the
+disturbance.
+
+When by any of the sudden movements which have been above described a
+jar is applied to the rocks, the wave flies through the more or less
+elastic mass until the energy involved in it is exhausted. This may
+not be brought about until the motion has travelled for the distance
+of hundreds of miles. In the great earthquake of 1755, known as the
+Lisbon shock, the records make it seem probable that the movement was
+felt over one eighth part of the earth's surface. Such great
+disturbances probably bring about a motion of the rocks near the point
+of origin, which may be expressed in oscillations having an amplitude
+of one to two feet; but in the greater number of earthquakes the
+maximum swing probably does not exceed the tenth of that amount. Very
+sensible shaking, even such as may produce considerable damage to
+buildings, are caused by shocks in which the earth vibrates with less
+than an inch of swing.
+
+When a shock originates, the wave in the rocks due to the compression
+which the blow inflicts runs at a speed varying with the elasticity of
+the substance, but at the rate of about fifteen hundred feet a second.
+The movements of this wave are at right angles to the seat of the
+originating disturbance, so that the shock may come to the surface in
+a line forming any angle between the vertical and the nearly
+horizontal. Where, as in a volcanic eruption, the shock originates
+with an explosion, these waves go off in circles. Where, however, as
+is generally the case, the shock originates in a fault plane, which
+may have a length and depth of many miles, the movement has an
+elliptical form.
+
+If the earthquake wave ran through a uniform and highly elastic
+substance, such as glass, it would move everywhere with equal speed,
+and, in the case of the greater disturbances, the motion might be felt
+over the whole surface of the earth. But as the motion takes place
+through rocks of varying elasticity, the rate at which it journeys is
+very irregular. Moving through materials of one density, and with a
+rate of vibration determined by those conditions, the impulse is with
+difficulty communicated to strata which naturally vibrate at another
+speed. In many cases, as where a shock passing through dense
+crystalline strata encounters a mass of soft sandstone, the wave, in
+place of going on, is reflected back toward its point of origin. These
+earthquake echoes sometimes give rise to very destructive movements.
+It often happens that before the original tremors of a shock have
+passed away from a point on the surface the reflex movements rush in,
+making a very irregular motion, which may be compared to that of the
+waves in a cross-sea.
+
+The foregoing account of earthquake action will serve to prepare the
+reader for an understanding of those very curious and important
+effects which these accidents produce in and on the earth. Below the
+surface the sensible action of earthquake shocks is limited. It has
+often been observed that people in mines hardly note a swaying which
+may be very conspicuous to those on the surface, the reason for this
+being that underground, where the rocks are firmly bound together, all
+those swingings which are due to the unsupported position of such
+objects as buildings, columnar rocks, trees, and the waters of the
+earth, are absent. The effect of the movements which earthquakes
+impress on the under earth is mainly due to the fact that in almost
+every part of the crust tensions or strains of other kinds are
+continually forming. These may for ages prove without effect until the
+earth is jarred, when motions will suddenly take place which in a
+moment may alter the conditions of the rocks throughout a wide field.
+In a word, a great earthquake caused by the formation of an extensive
+fault is likely to produce any number of slight dislocations, each of
+which is in turn shock-making, sending its little wave to complicate
+the great oscillation. Nor does the perturbing effect of these jarring
+movements cease with the fractures which they set up and the new
+strains which are in turn developed by the motions which they induce.
+The alterations of the rocks which are involved in chemical changes
+are favoured by such motions. It is a familiar experience that a
+vessel of water, if kept in the state of repose, may have its
+temperature lowered three or four degrees below the freezing point
+without becoming frozen. If the side of the vessel is then tapped with
+the finger, so as to send a slight quake through the mass, it will
+instantly congeal. Molecular rearrangements are thus favoured by
+shocks, and the consequences of those which run through the earth are,
+from a chemical point of view, probably important.
+
+The reader may help himself to understand something of the complicated
+problem of earth tensions, and the corresponding movements of the
+rocks, by considering certain homely illustrations. He may observe how
+the soil cracks as it shrinks in times of drought, the openings
+closing when it rains. In a similar way the frozen earth breaks open,
+sometimes with a shock which is often counted as an earthquake. Again,
+the ashes in a sifter or the gravel on a sieve show how each shaking
+may relieve certain tensions established by gravity, while they create
+others which are in turn to be released by the next shock. An ordinary
+dwelling house sways and strains with the alternations of temperature
+and moisture to which it is subjected in the round of climatal
+alterations. Now and then we note the movements in a cracking sound,
+but by far the greater part of them escape observation.
+
+With this sketch of the mechanism of earthquake shocks we now turn to
+consider their effects upon the surface of the earth. From a
+geological point of view, the most important effect of earthquake
+shocks is found in the movement of rock masses down steep slopes,
+which is induced by the shaking. Everywhere on the land the agents of
+decay and erosion tend to bring heavy masses into position where
+gravitation naturally leads to their downfall, but where they may
+remain long suspended, provided they are not disturbed. Thus, wherever
+there are high and steep cliffs, great falls of rock are likely to
+occur when the earthquake movements traverse the under earth. In more
+than one instance observers, so placed that they commanded a view of
+distant mountains, have noticed the downfall of precipices in the path
+of the shock before the trembling affected the ground on which they
+stood. In the famous earthquake of 1783, which devastated southern
+Italy, the Prince of Scylla persuaded his people to take refuge in
+their boats, hoping that they might thereby escape the destruction
+which threatened them on the land. No sooner were the unhappy folk on
+the water than the fall of neighbouring cliffs near the sea produced a
+great wave, which overwhelmed the vessels.
+
+Where the soil lies upon steep slopes, in positions in which it has
+accumulated during ages of tranquillity, a great shock is likely to
+send it down into the valleys in vast landslides. Thus, in the
+earthquake of 1692, the Blue Mountains of Jamaica were so violently
+shaken that the soil and the forests which stood on it were
+precipitated into the river beds, so that many tree-clad summits
+became fields of bare rock. The effect of this action is immensely to
+increase the amount of detritus which the streams convey to the sea.
+After the great Jamaica shock, above noted, the rivers for a while
+ceased to flow, their waters being stored in the masses of loose
+material. Then for weeks they poured forth torrents of mud and the
+_debris_ of vegetation--materials which had to be swept away as the
+streams formed new channels.
+
+In all regions where earthquake movements are frequent, and the shock
+of considerable violence, the trained observer notes that the surfaces
+of bare rock are singularly extensive, the fact being that many of
+these areas, where the slope lies at angles of from ten to thirty
+degrees, which in an unshaken region would be thickly soil-covered,
+are deprived of the coating by the downward movement of the waste
+which the disturbances bring about. A familiar example of this action
+may be had by watching the workmen engaged in sifting sand, by casting
+the material on a sloping grating. The work could not be done but for
+an occasional blow applied to the sifter. An arrangement for such a
+jarring motion is commonly found in various ore-dressing machines,
+where the object is to move fragments of matter over a sloping
+surface.
+
+Even where the earth is so level that an earthquake shock does not
+cause a sliding motion of the materials, such as above described,
+other consequences of the shaking may readily be noted. As the motion
+runs through the mass, provided the movement be one of considerable
+violence, crevices several feet in width, and sometimes having the
+length of miles, are often formed. In most cases these fissures,
+opened by one pulsation of the shock, are likely to be closed by the
+return movement, which occurs the instant thereafter. The consequences
+of this action are often singular, and in cases constitute the most
+frightful elements of a shock which the sufferer beholds. In the great
+earthquake of 1811, which ravaged the section of the Mississippi
+Valley between the mouth of the Ohio and Vicksburg, these crevices
+were so numerously formed that the pioneers protected themselves from
+the danger of being caught in their jaws by felling trees so that they
+lay at right angles to the direction in which the rents extended,
+building on these timbers platforms to support their temporary
+dwelling places. The records of earthquakes supply many instances in
+which people have been caught in these earth fissures, and in a single
+case it is recorded that a man who disappeared into the cavity was in
+a moment cast forth in the rush of waters which in this, as in many
+other cases, spouts forth as the walls of the opening come together.
+
+Sometimes these rents are attended by a dislocation, which brings the
+earth on one side much higher than on the other. The step thus
+produced may be many miles in length, and may have a height of twenty
+feet or more. It needs no argument to show that we have here the top
+of a fault such as produced the shock, or it may be one of a secondary
+nature, such as any earthquake is likely to bring about in the strata
+which it traverses. In certain cases two faults conjoin their action,
+so that a portion of the surface disappears beneath the earth,
+entombing whatever may have stood on the vanished site. Thus in the
+great shock known as that of Lisbon, which occurred in 1755, the stone
+quay along the harbour, where many thousand people had sought refuge
+from the falling buildings of the city, suddenly sank down with the
+multitude, and the waters closed over it; no trace of the people or of
+the structure was to be found after the shock was over. There is a
+story to the effect that during the same earthquake an Arab village in
+northern Africa sank down, the earth on either side closing over it,
+so that no trace of the habitations remained. In both these instances
+the catastrophes are best explained by the diagram.
+
+[Illustration: Fig. 21.--Diagram showing how a portion of the earth's
+surface may be sunk by faulting. Fig. A shows the original position;
+B, the position after faulting; b b' and c c' the planes of the
+faults; the arrows the direction of the movement.]
+
+In the earthquake of 1811 the alluvial plains on either side of the
+Mississippi at many points sank down so that arable land was converted
+into lakes; the area of these depressions probably amounted to some
+hundred square miles. The writer, on examining these sunken lands,
+found that the subsidences had occurred where the old moats or
+abandoned channels of the great river had been filled in with a
+mixture of decaying timber and river silt. When violently shaken, this
+loose-textured _debris_ naturally settled down, so that it formed a
+basin occupied by a crescent-shaped lake. The same process of settling
+plentifully goes on wherever the rocks are still in an uncemented
+state. The result is often the production of changes which lead to the
+expulsion of gases. Thus, in the Charleston earthquake of 1883, the
+surface over an area of many hundred square miles was pitted with
+small craters, formed by the uprush of water impelled by its contained
+gases. These little water volcanoes--for such we may call
+them--sometimes occur to the number of a dozen or more on each acre of
+ground in the violently shaken district. They indicate one result of
+the physical and chemical alterations which earthquake shocks bring
+about. As earthquakes increase in violence their effect upon the soil
+becomes continually greater, until in the most violent shocks all the
+loose materials on the surface of the earth may be so shaken about as
+to destroy even the boundaries of fields. After the famous earthquake
+of Riobamba, which occurred on the west coast of South America in
+1797, the people of the district in which the town of that name was
+situated were forced to redivide their land, the original boundaries
+having disappeared. Fortunately, shocks of this description are
+exceedingly rare. They occur in only a few parts of the world.
+
+Certain effects of earthquakes where the shock emerges beneath the sea
+have been stated in the account of volcanic eruptions (see page 299).
+We may therefore note here only certain of the more general facts.
+While passing through the deep seas, this wave may have a height of
+not more than two or three feet and a width of some score miles. As it
+rolls in upon the shore the front of the undulation is retarded by the
+friction of the bottom in such a measure that its speed is diminished,
+while the following part of the waves, being less checked, crowds up
+toward this forward part. The result is, that the surge mounts ever
+higher and higher as it draws near the shore, upon which it may roll
+as a vast wave having the height of fifty feet or more and a width
+quite unparalleled by any wave produced from wind action. Waves of
+this description are most common in the Pacific Ocean. Although but
+occasional, the damage which they may inflict is very great. As the
+movement approaches the shore, vessels, however well anchored, are
+dragged away to seaward by the great back lash of the wave, a
+phenomenon which may be perceived even in the case of the ordinary
+surf. Thus forced to seaward, the crews of the ships may find their
+vessels drawn out for the distance of some miles, until they come near
+the face of the advancing billow. This, as it approaches the shore,
+straightens up to the wall-fronted form, and then topples upon the
+land. Those vessels which are not at once crushed down by the blow are
+generally hurled far inland by the rush of waters. In the great
+Jamaica earthquake of 1692 a British man-of-war was borne over the
+tops of certain warehouses and deposited at a distance from the shore.
+
+Owing to the fact that water is a highly elastic material, the shocks
+transmitted to it from the bottom are sent onward with their energy
+but little diminished. While the impulse is very violent, these
+oscillations may prove damaging to shipping. The log-books of mariners
+abound in stories of how vessels were dismasted or otherwise badly
+shaken by a sudden blow received in the midst of a quiet sea. The
+impression commonly conveyed to the sailors is that the craft has
+struck upon a rock. The explanation is that an earthquake jar, in
+traversing the water, has delivered its blow to the ship. As the speed
+of this jarring movement is very much greater than that of any
+ordinary wave, the blow which it may strike may be most destructive.
+There seems, indeed, little reason to doubt that a portion of the
+vessels which are ever disappearing in the wilderness of the ocean are
+lost by the crushing effect of these quakings which pass through the
+waters of the deep.
+
+We have already spoken of the earthquake shock as an oscillation. It
+is a quality of all bodies which oscillate under the influence of a
+blow, such as originates in earthquake shocks, to swing to and fro,
+after the manner of the metal in a bell or a tuning fork, in a
+succession of movements, each less than the preceding, until the
+impulse is worn out, or rather, we should in strict sense say,
+changed to other forms of energy. The result is, that even in the
+slightest earthquake shock the earth moves not once to and fro, but
+very many times. In a considerable shock the successive diminishing
+swingings amount to dozens before they become so slight as to elude
+perception. Although the first swaying is the strongest, and generally
+the most destructive, the quick to-and-fro motions are apt to continue
+and to complete the devastation which the first brings about. The
+vibrations due to any one shock take place with great rapidity. They
+may, indeed, be compared to those movements which we perceive in the
+margin of a large bell when it has received a heavy blow from the
+clapper. The reader has perhaps seen that for a moment the rim of the
+bell vibrates with such rapidity that it has a misty look--that is,
+the motions elude the sight. It is easy to see that a shaking of this
+kind is particularly calculated to disrupt any bodies which stand free
+in the air and are supported only at their base.
+
+In what we may call the natural architecture of the earth, the
+pinnacles and obelisks, such as are formed in many high countries, the
+effect of these shakings is destructive, and, as we have seen, even
+the firmer-placed objects, such as the strong-walled cliffs and steep
+slopes of earth, break down under the assaults. It is therefore no
+matter of surprise that the buildings which man erects, where they are
+composed of masonry, suffer greatly from these tremblings. In almost
+all cases human edifices are constructed without regard to other
+problems of strength than those which may be measured by their weight
+and the resistance to fracture from gravitation alone. They are not
+built with expectation of a quaking, but of a firm-set earth.
+
+The damage which earthquakes do to buildings is in most cases due to
+the fact that they sway their walls out of plumb, so that they are no
+longer in position to support the weight which they have to bear. The
+amount of this swaying is naturally very much greater than that which
+the earth itself experiences in the movement. A building of any height
+with its walls unsupported by neighbouring structures may find its
+roof rocked to and fro through an arc which has a length of feet,
+while its base moves only through a length of inches. The reader may
+see an example of this nature if he will poise a thin book or a bit of
+plank a foot long on top of a small table; then jarring the table so
+that it swings through a distance of say a quarter of an inch, he will
+see that the columnar object swings at its top through a much greater
+distance, and is pretty sure to be overturned.
+
+Where a building carries a load in its upper parts, such as may be
+afforded by its heavy roof or the stores which it contains, the effect
+of an earthquake shock such as carries the earth to and fro becomes
+much more destructive than it might otherwise be. This weight lags
+behind when the earth slips forward in the first movement of the
+oscillation, with the effect that the walls of the building are pretty
+sure to be thrust so far beyond the perpendicular that they give way
+and are carried down by the weight which they bore. It has often been
+remarked in earthquake shocks that tall columns, even where composed
+of many blocks, survive a shock which overturns lower buildings where
+thin walls support several floors, on each of which is accumulated a
+considerable amount of weight. In the case of the column, the strains
+are even, and the whole structure may rock to and fro without toppling
+over. As the energy of the undulations diminish, it gradually regains
+the quiet state without damage. In the ordinary edifice the irregular
+disposition of the weight does not permit the uniform movement which
+may insure safety. Thus, if the city of Washington should ever be
+violently shaken, the great obelisk, notwithstanding that it is five
+hundred feet high, may survive a disturbance which would wreck the
+lower and more massive edifices which lie about it.
+
+Where, as is fortunately rarely the case, the great shock comes to
+the earth in a vertical direction, the effect upon all movable objects
+is in the highest measure disastrous. In such a case buildings are
+crushed as if by the stroke of a giant's hand. The roofs and floors
+are at one stroke thrown to the foundations, and all the parts of the
+walls which are not supported by strong masonry continuous from top to
+bottom are broken to pieces. In such cases it has been remarked that
+the bodies of men are often thrown considerable distances. It is
+asserted, indeed, that in the Riobamba shock they were cast upward to
+the height of more than ninety feet. It is related that the solo
+survivor of a congregation which had hastened at the outset of the
+disturbance into a church was thrown by the greatest and most
+destructive shock upward and through a window the base of which was at
+the height of more than twenty feet from the ground.
+
+It is readily understood that an earthquake shock may enter a building
+in any direction between the vertical and the horizontal. As the
+movement exhausts itself in passing from the place of its origin, the
+horizontal shocks are usually of least energy. Those which are
+accurately vertical are only experienced where the edifices are placed
+immediately over the point where the motion originates. It follows,
+therefore, that the destructive work of earthquakes is mainly
+performed in that part of the field where the motion is, as regards
+its direction, between the vertical and the horizontal--a position in
+which the edifice is likely to receive at once the destructive effect
+arising from the sharp upward thrust of the vertical movement and the
+oscillating action of that which is in a horizontal direction. Against
+strains of this description, where the movements have an amplitude of
+more than a few inches, no ordinary masonry edifice can be made
+perfectly safe; the only tolerable security is attained where the
+building is of well-framed timber, which by its elasticity permits a
+good deal of motion without destructive consequences. Even such
+buildings, however, those of the strongest type, may be ruined by the
+greater earthquakes. Thus, in the Mississippi Valley earthquake of
+1811, the log huts of the frontiersmen, which are about as strong as
+any buildings can be made, were shaken to pieces by the sharp and
+reiterated shocks.
+
+It is by no means surprising to find that the style of architecture
+adopted in earthquake countries differs from that which is developed
+in regions where the earth is firm-set. The people generally learn
+that where their buildings must meet the trials of earthquakes they
+have to be low and strong, framed in the manner of fortifications, to
+withstand the assault of this enemy. We observe that Gothic
+architecture, where a great weight of masonry is carried upon slender
+columns and walls divided by tall windows, though it became the
+dominant style in the relatively stable lands of northern Europe,
+never gained a firm foothold in those regions about the Mediterranean
+which are frequently visited by severe convulsions of the earth. There
+the Grecian or the Romanesque styles, which are of a much more massive
+type, retain their places and are the fashions to the present day.
+Even this manner of building, though affording a certain security
+against slight tremblings, is not safe in the greater shocks. Again
+and again large areas in southern Italy have been almost swept of
+their buildings by the destructive movements which occur in that
+realm. The only people who have systematically adapted their
+architectural methods to earthquake strains are the Japanese, who in
+certain districts where such risks are to be encountered construct
+their dwellings of wood, and place them upon rollers, so that they may
+readily move to and fro as the shock passes beneath them. In a measure
+the people of San Francisco have also provided against this danger by
+avoiding dangerous weights in the upper parts of their buildings, as
+well as the excessive height to which these structures are lifted in
+some of our American towns.
+
+Earthquakes of sensible energy appear to be limited to particular
+parts of the earth's crust. The regions, indeed, where within the
+period of human history shocks of devastating energy have occurred do
+not include more than one fifteenth part of the earth's surface. There
+is a common notion that these movements are most apt to happen in
+volcanic regions. It is, indeed, true that sensible shocks commonly
+attend the explosions from great craters, but the records clearly show
+that these movements are very rarely of destructive energy. Thus in
+the regions about the base of Vesuvius and of AEtna, the two volcanoes
+of which most is known, the shocks have never been productive of
+extensive disaster. In fact, the reiterated slight jarrings which
+attend volcanic action appear to prevent the formation of those great
+and slowly accumulated strains which in their discharge produce the
+most violent tremblings of the earth. The greatest and most continuous
+earthquake disturbances of history--that before noted in the early
+days of this century, in the Mississippi Valley, where shocks of
+considerable violence continued for two years--came about in a field
+very far removed from active volcanoes. So, too, the disturbances
+beneath the Atlantic floor which originated the shocks that led to the
+destruction of Lisbon, and many other similar though less violent
+movements, are developed in a field apparently remote from living
+volcanoes. Eastern New England, which has been the seat of several
+considerable earthquakes, is about as far away from active vents as
+any place on the habitable globe. We may therefore conclude that,
+while volcanoes necessarily produce shocks resulting from the
+discharge of their gases and the intrusion of lava into the dikes
+which are formed about them, the greater part of the important shocks
+are in no wise connected with volcanic explosions.
+
+With the exception of the earthquake in the Mississippi Valley, all
+the great shocks of which we have a record have occurred in or near
+regions where the rocks have been extensively disturbed by
+mountain-building forces, and where the indications lead us to
+believe that dislocations of strata, such as are competent to rive the
+beds asunder, may still be in progress. This, taken in connection with
+the fact that many of these shocks are attended by the formation of
+fault planes, which appear on the surface, lead us to the conclusion
+that earthquakes of the stronger kind are generally formed by the
+riving of fissures, which may or may not be developed upward to the
+surface. This view is supported by many careful observations on the
+effect which certain great earthquakes have exercised on the buildings
+which they have ravaged. The distinguished observer, Mr. Charles
+Mallet, who visited the seat of the earthquake which, in 1854,
+occurred in the province of Calabria in Italy, with great labour and
+skill determined the direction in which the shock moved through some
+hundreds of edifices on which it left the marks of its passage.
+Platting these lines of motion, he found that they were all referred
+to a vertical plane lying at the depth of some miles beneath the
+surface, and extending for a great distance in a north and south
+direction. This method of inquiry has been applied to other fields,
+with the result that in the case of all the instances which have been
+subjected to this inquiry the seat of the shock has been traced to
+such a plane, which can best be accounted for by the supposition of a
+fault.
+
+The method pursued by Mr. Mallet in his studies of the origin of
+earthquakes, and by those who have continued his inquiry, may be
+briefly indicated as follows: Examining disrupted buildings, it is
+easy to determine those which have been wrecked by a shock that
+emerged from the earth in a vertical direction. In these cases, though
+tall walls may remain standing, the roofs and floors are thrown into
+the cellars. With a dozen such instances the plane of what is called
+the seismic vertical is established (_seismos_ is the Greek for
+earthquake). Then on either side of this plane, which indicates the
+line but not the depth of the disturbance, other observations may be
+made which give the clew to the depth. Thus a building may be found
+where the northwest corner at its upper part has been thrown off. Such
+a rupture was clearly caused by an upward but oblique movement, which
+in the first half of the oscillation heaved the structure upwardly
+into the northwest, and then in the second half, or rebound, drew the
+mass of the building away from the unsupported corner, allowing that
+part of the masonry to fly off and fall to the ground. Constructing a
+line at right angles to the plane of the fracture, it will be found to
+intersect the plane, the position of which has been in part determined
+by finding the line where it intersects the earth, or the seismic
+vertical before noted. Multiplying such observations on either side of
+the last-mentioned line, the attitude of the underground parts of the
+plane, as well as the depth to which it attained, can be approximately
+determined.
+
+It is worth while to consider the extent to which earthquake shocks
+may affect the general quality of the people who dwell in countries
+where these disturbances occur with such frequency and violence as to
+influence their lives. There can be no question that wherever
+earthquakes occur in such a measure as to produce widespread terror,
+where, recurring from time to time, they develop in men a sense of
+abiding insecurity, they become potent agents of degradation. All the
+best which men do in creating a civilization rests upon a sense of
+confidence that their efforts may be accumulated from year to year,
+and that even after death the work of each man may remain as a
+heritage to his kind. It is likely, indeed, that in certain realms, as
+in southern Italy, a part of the failure of the people to advance in
+culture is due to their long experience of such calamities, and the
+natural expectation that they will from time to time recur. In a
+similar way the Spanish settlements in Central and South America,
+which lie mostly in lands that are subject to disastrous shocks, may
+have been retarded by the despair, as well as the loss of property
+and life, which these accidents have so frequently inflicted upon
+them. It will not do, however, to attribute too much to such
+terrestrial influences. By far the most important element in
+determining the destiny of a people is to be found in their native
+quality, that which they owe to their ancestors of distant
+generations. In this connection it is well to consider the history of
+the Icelandic people, where a small folk has for a thousand years been
+exposed to a range and severity of trials, such as earthquakes,
+volcanic explosions, and dearth of harvests may produce, and all these
+in a measure that few if any other countries experience.
+Notwithstanding these misfortunes, the Icelanders have developed and
+maintained a civilization which in all else, except its material
+results, on the average transcends that which has been won by any
+other folk in modern times. If a people have the determining spirit
+which leads to high living, they can successfully face calamities far
+greater than those which earthquakes inflict.
+
+It was long supposed that the regions where earthquakes are not
+noticeable by the unaided senses were exempt from all such
+disturbances. The observations which seismologists have made in recent
+years point to the conclusion that no part of the earth's surface is
+quite exempt from movements which, though not readily perceived, can
+be made visible by the use of appropriate instruments. With an
+apparatus known as the horizontal pendulum it is possible to observe
+vibrations which do not exceed in amplitude the hundredth part of an
+inch. This mechanism consists essentially of a slender bar supported
+near one end by two wires, one from above, the other from below. It
+may readily be conceived that any measurable movement will cause the
+longer end of the rod to sway through a considerable arc. Wherever
+such a pendulum has been carefully observed in any district, it has
+been found that it indicates the occurrence of slight tremors. Even
+certain changes of the barometer, which alter the weight of the
+atmosphere that rests upon the earth to the amount indicated by an
+inch in the height of the mercury column, appears in all cases to
+create such tremors. Many of these slight shocks may be due to the
+effect of more violent quakings, which have run perhaps for thousands
+of miles from their point of origin, and have thus been reduced in the
+amplitude of their movement. Others are probably due to the slight
+motion brought about through the chemical changes of the rocks, which
+are continuously going on. The ease with which even small motions are
+carried to a great distance may be judged by the fact that when the
+ground is frozen the horizontal pendulum will indicate the jarring due
+to a railway train at the distance of a mile or more from the track.
+
+In connection with the earth jarring, it would be well to note the
+occurrence of another, though physically different, kind of movement,
+which we may term earth swayings, or massive movements, which slowly
+dislocate the vertical, and doubtless also the horizontal, position of
+points upon its surface. It has more than once been remarked that in
+mountain countries, where accurate sights have been taken, the heights
+of points between the extremities of a long line appear somewhat to
+vary in the course of a term of years. Thus at a place in the
+Apennines, where two buildings separated by some miles of distance are
+commonly intervisible over the crest of a neighbouring peak, it has
+happened that a change of level of some one of the points has made it
+impossible to see the one edifice from the other. Knowing as we do
+that the line of the seacoast is ever-changing, uprising taking place
+at some points and down-sinking at others, it seems not unlikely that
+these irregular swayings are of very common occurrence. Moreover,
+astronomers are beginning to remark the fact that their observatories
+appear not to remain permanently in the same position--that is, they
+do not have exactly the same latitude and longitude. Certain of these
+changes have recently been explained by the discovery of a new and
+hitherto unnoted movement of the polar axis. It is not improbable,
+however, that the irregular swaying of the earth's crust, due to the
+folding of strata and to the alterations in the volume of rocks which
+are continually going on, may have some share in bringing about these
+dislocations.
+
+Measured by the destruction which was wrought to the interests of man,
+earthquakes deserve to be reckoned among the direst calamities of
+Nature. Since the dawn of history the records show us that the
+destruction of life which is to be attributed to them is to be counted
+by the millions. A catalogue of the loss of life in the accidents of
+this description which have occurred during the Christian era has led
+the writer to suppose that probably over two million persons have
+perished from these shocks in the last nineteen centuries.
+Nevertheless, as compared with other agents of destruction, such as
+preventable disease, war, or famine, the loss which has been inflicted
+by earth movements is really trifling, and almost all of it is due to
+an obstinate carelessness in the construction of buildings without
+reference to the risks which are known to exist in earthquake-ridden
+countries.
+
+Although all our exact knowledge concerning the distribution of
+earthquakes is limited to the imperfect records of two or three
+thousand years, it is commonly possible to measure in a general way
+the liability to such accidents which may exist in any country by a
+careful study of the details of its topography. In almost every large
+area the process of erosion naturally leaves quantities of rock,
+either in the form of detached columns or as detrital accumulations
+deposited on steep slopes. These features are of relatively slow
+formation, and it is often possible to determine that they have been
+in their positions for a time which is to be measured by thousands of
+years. Thus, on inspecting a country such as North America, where the
+historic records cover but a brief time, we may on inquiry determine
+which portions of its area have long been exempt from powerful shocks.
+Where natural obelisks and steep taluses abound--features which would
+have disappeared if the region had been moved by great shocks--we may
+be sure that the field under inspection has for a great period been
+exempt from powerful shaking. Judged by this standard, we may safely
+say that the region occupied by the Appalachian Mountains has been
+exempt from serious trouble. So, too, the section of the Cordilleras
+lying to the east of what is commonly called the Great Basin, between
+the Rocky Mountains and the Sierra Nevada, has also enjoyed a long
+reign of peace. In glaciated countries the record is naturally less
+clear than in those parts of the world which have been subjected to
+long-continued, slow decay of the rocks. Nevertheless, in those fields
+boulders are often found poised in position which they could not have
+maintained if subjected to violent shaking. Judged by this evidence,
+we may say that a large part of the northern section of this
+continent, particularly the area about the Great Lakes, has been
+exempt from considerable shocks since the glacier passed away.
+
+The shores which are subject to the visitations of the great marine
+waves, caused by earthquake shocks occurring beneath the bottom of the
+neighbouring ocean, are so swept by those violent inundations that
+they lose many features which are often found along coasts that have
+been exempted from such visitations. Thus wherever we find extensive
+and delicately moulded dunes, poised stones, or slender pinnacled
+rocks along a coast, we may be sure that since these features were
+formed the district has not been swept by these great waves.
+
+[Illustration: Fig. 22.--Poised rocks indicating a long exemption from
+strong earthquakes in the places where such features occur.]
+
+Around the northern Atlantic we almost everywhere find the glacial
+waste here and there accumulated near the margin of the sea in the
+complicated sculptured outlines which are assumed by kame sands and
+gravels. From a study of these features just above the level of high
+tide, the writer has become convinced that the North Atlantic district
+has long been exempt from the assaults of other waves than those which
+are produced during heavy storms. At the present time the waves
+formed by earthquakes appear to be of destructive violence only on the
+west coast of South America, where they roll in from a region of the
+Pacific lying to the south of the equator and a few hundred miles from
+the shore of the continent, which appears to be the seat of
+exceedingly violent shocks. A similar field occurs in the Atlantic
+between the Lesser Antilles and the Spanish peninsula, but no great
+waves have come thence since the time of the Lisbon earthquake. The
+basin of the Caribbean and the region about Java appear to be also
+fields where these disturbances may be expected, though in each but
+one wave of this nature has been recorded. Therefore we may regard
+these secondary results of a submarine earthquake as seldom phenomena.
+
+
+                  DURATION OF GEOLOGICAL TIME.
+
+Although it is beyond the power of man to conceive any such lapses of
+time as have taken place in the history of this earth, it is
+interesting, and in certain ways profitable, to determine as near as
+possible in the measure of years the duration of the events which are
+recorded in the rocks. Some astronomers, basing their conclusions on
+the heat-containing power of matter, and on the rate at which energy
+in this form flows from the sun, have come to the conclusion that our
+planet could not have been in independent existence for more than
+about twenty million years. The geologist, however, resting his
+conclusions on the records which are the subject of his inquiry, comes
+on many different lines to an opinion which traverses that entertained
+by some distinguished astronomers. The ways in which the student of
+the earth arrives at this opinion will now be set forth.
+
+By noting the amount of sediment carried forth to the sea by the
+rivers, the geologist finds that the lands of the earth--those, at
+least, which are protected by their natural envelopes of
+vegetation--are wearing down at a rate which pretty certainly does
+not exceed one foot in about five thousand years, or two hundred feet
+in a million years. Discovering at many places on the earth's surface
+deposits which originally had a thickness of five thousand feet or
+more, which have been worn down to the depths of thousands of feet in
+a single rather brief section of geological time, the student readily
+finds himself prepared to claim that a period of from five to ten
+million years has often been required for the accomplishment of but a
+very small part of the changes which he knows to have occurred on this
+earth.
+
+As the geologist follows down through the sections of the stratified
+rocks, and from the remains of strata determines the erosion which has
+borne away the greater part of the thick deposits which have been
+exposed to erosion, he comes upon one of those breaks in the
+succession, or encounters what is called an unconformity, as when
+horizontal strata lie against those which are tilted. In many cases he
+may observe that at this time there was a great interval unrepresented
+by deposits at the place where his observations are made, yet a great
+lapse of time is indicated by the fact that a large amount of erosion
+took place in the interval between the two sets of beds.
+
+Putting together the bits of record, and assuming that the rate of
+erosion accomplished by the agents which operate on the land has
+always been about the same, the geologist comes to the conclusion that
+the section of the rocks from the present day to the lowest strata of
+the Laurentian represents in the time required for their formation not
+less than a hundred million years; more likely twice that duration. To
+this argument objection is made by some naturalists that the agents of
+erosion may have been more active in the past than they are at
+present. They suggest that the rainfall may have been much greater or
+the tides higher than they now are. Granting all that can be claimed
+on this score, we note the fact that the rate of erosion evidently
+does not increase in anything like a proportionate way with the
+amount of rainfall. Where a country is protected by its natural
+coating of vegetation, the rain is delivered to the streams without
+making any considerable assault upon the surface of the earth, however
+large the fall may be. Moreover, the tides have little direct cutting
+power; they can only remove detritus which other agents have brought
+into a condition to be borne away. The direct cutting power of the
+tidal movement does not seem to be much greater in the Bay of Fundy,
+where the maximum height of the waves amounts to fifty feet, than on
+the southern coast of Massachusetts, where the range is not more than
+five. So far as the observer can judge, the climatal conditions and
+the other influences which affect the wear of rocks have not greatly
+varied in the past from what they are at the present day. Now and then
+there have been periods of excessive erosion; again, ages in which
+large fields were in the conditions of exceeding drought. It is,
+however, a fair presumption that these periods in a way balance each
+other, and that the average state was much like that which we find at
+present.
+
+If after studying the erosive phenomena exhibited in the structure of
+the earth the student takes up the study of the accumulations of
+strata, and endeavours to determine the time required for the laying
+down of the sediments, he finds similar evidence of the earth's great
+antiquity. Although the process of deposition, which has given us the
+rocks visible in the land masses, has been very much interrupted, the
+section which is made by grouping the observations made in various
+fields shows that something like a maximum thickness of a hundred and
+fifty thousand feet of beds has been accumulated in that part of
+geologic time during which strata were being laid down in the fields
+that are subjected to our study. Although in these rocks there are
+many sets of beds which were rapidly formed, the greater part of them
+have been accumulated with exceeding slowness. Many fine shales, such
+as those which plentifully occur in the Devonian beds of this country,
+must have required a thousand years or more for the deposition of the
+materials that now occupy an inch in depth. In those sections a single
+foot of the rock may well represent a period of ten thousand years. In
+many of the limestones the rate of accumulation could hardly have been
+more speedy. The reckoning has to be rough, but the impression which
+such studies make upon the mind of the unprejudiced observer is to the
+effect that the thirty miles or so of sedimentary deposits could not
+have been formed in less than a hundred million years. In this
+reckoning it should be noted that no account is taken of those great
+intervals of unrecorded time, such as elapsed between the close of the
+Laurentian and the beginning of the Cambrian periods.
+
+There is a third way in which we may seek an interpretation of
+duration from the rocks. In each successive stage of the earth's
+history, in different measure in the various ages, mountains were
+formed which in time, during their exposure to the conditions of the
+land, were worn down to their roots and covered by deposits
+accumulated during the succeeding ages. A score or more of these
+successively constructed series of elevations may readily be observed.
+Of old, it was believed that mountain ranges were suddenly formed, but
+there is, however, ample evidence to prove that these disturbed
+portions of the strata were very gradually dislocated, the rate of the
+mountainous growth having been, in general, no greater in the past
+than it is at the present day, when, as we know full well, the
+movements are going on so slowly that they escape observation. Only
+here and there, as an attendant on earthquake shocks or other related
+movements of the crust, do we find any trace of the upward march which
+produces these elevations. Although not a subject for exact
+measurements, these features of mountain growth indicate a vast lapse
+of time, during which the elevations were formed and worn away.
+
+Yet another and very different method by which we may obtain some
+gauge of the depths of the past is to be found in the steps which have
+led organic life from its lowest and earliest known forms to the
+present state of advancement. Taking the changes of species which have
+occurred since the beginning of the last ice epoch, we find that the
+changes which have been made in the organic life have been very small;
+no naturalist who has obtained a clear idea of the facts will question
+the statement that they are not a thousandth part of the alterations
+which have occurred since the Laurentian time. The writer is of the
+opinion that they do not represent the ten thousandth part of those
+vast changes. These changes are limited in the main to the
+disappearance of a few forms, and to slight modifications in those
+previously in existence which have survived to the present day. So far
+as we can judge, no considerable step in the organic series has taken
+place in this last great period of the earth's history, although it
+has been a period when, as before noted, all the conditions have
+combined to induce rapid modifications in both animals and plants. If,
+then, we can determine the duration of this period, we may obtain a
+gauge of some general value.
+
+Although we can not measure in any accurate way the duration of the
+events which have taken place since the last Glacial period began to
+wane, a study of the facts seems to show that less than a hundred
+thousand years can not well be assumed for this interval. Some of the
+students who have approached the subject are disposed to allow a
+period of at least twice this length as necessary for the perspective
+which the train of events exhibits. Reckoning on the lowest estimate,
+and counting the organic changes which take place during the age as
+amounting to the thousandth part of the organic changes since the
+Laurentian age, we find ourselves in face once again of that
+inconceivable sum which was indicated by the physical record.
+
+Here, again, the critics assert that there may have been periods in
+the history of the earth when the changes of organic life occurred in
+a far swifter manner than in this last section of the earth's history.
+This supposition is inadmissible, for it rests on no kind of proof; it
+is, moreover, contraindicated by the evident fact that the advance in
+the organic series has been more rapid in recent time than at any
+stage of the past. In a word, all the facts with which the geologist
+deals are decidedly against the assumption that terrestrial changes in
+the organic or the inorganic world ever proceed in a spasmodic manner.
+Here and there, and from time to time, local revolutions of a violent
+nature undoubtedly occur, but, so far as we may judge from the aspect
+of the present or the records of the past, these accidents are
+strictly local; the earth has gone forward in its changes much as it
+is now advancing. Its revolutions have been those of order rather than
+those of accident.
+
+The first duty of the naturalist is to take Nature as he finds it. He
+must avoid supposing any methods of action which are not clearly
+indicated in the facts that he observes. The history of his own and of
+all other sciences clearly shows that danger is always incurred where
+suppositions as to peculiar methods of action are introduced into the
+interpretation. It required many centuries of labour before the
+students of the earth came to adopt the principle of explaining the
+problems with which they had to deal by the evidence that the earth
+submitted to them. Wherever they trusted to their imaginations for
+guidance, they fell into error. Those who endeavour to abbreviate our
+conception of geologic time by supposing that in the olden days the
+order of events was other than that we now behold are going counter to
+the best traditions of the science.
+
+Although the aspect of the record of life since the beginning of the
+Cambrian time indicates a period of at least a hundred million years,
+it must not be supposed that this is the limit of the time required
+for the development of the organic series. All the important types of
+animals were already in existence in that ancient period with the
+exception of the vertebrates, the remains of which have apparently now
+been traced down to near the Cambrian level. In other words, at the
+stage where we first find evidence of living beings the series to
+which they belong had already climbed very far above the level of
+lifeless matter. Few naturalists will question the statement that half
+the work of organic advance had been accomplished at the beginning of
+the Cambrian rocks. The writer is of the opinion that the development
+which took place before that age must have required a much longer
+period than has elapsed from that epoch to the present day. We thus
+come to the conclusion that the measurement of duration afforded by
+organic life indicates a yet more lengthened claim of events, and
+demands more time than appears to be required for the formation of the
+stratified rocks.
+
+The index of duration afforded by the organic series is probably more
+trustworthy than that which is found in the sedimentary strata, and
+this for the reason that the records of those strata have been
+subjected to numerous and immeasurable breaks, while the development
+of organic life has of necessity been perfectly continuous. The one
+record can at any point be broken without interrupting the sequences;
+the other does not admit of any breaches in the continuity.
+
+
+                             THE MOON.
+
+Set over against the earth--related to, yet contrasted with it in many
+ways--the moon offers a most profitable object to the student of
+geology. He should often turn to it for those lessons which will be
+briefly noted.
+
+In the beginning of their mutual history the materials of earth and
+moon doubtless formed one vaporous body which had been parted from the
+concentrating mass of the sun in the manner noted in the sketch of
+the history of the solar system. After the earth-moon body had
+gathered into a nebulous sphere, it is most likely that a ring
+resembling that still existing about Saturn was formed about the
+earth, which in time consolidated into the satellite. Thenceforth the
+two bodies were parted, except for the gravitative attraction which
+impelled them to revolve about their common centre of gravity, and
+except for the light and heat they might exchange with one another.
+
+The first stages after the parting of the spheres of earth and moon
+appear to have been essentially the same in each body. Concentrating
+upon their centres, they became in time fluid by heat; further on,
+they entered the rigid state--in a word, they froze--at least in their
+outer parts. At this point in their existence their histories utterly
+diverge; or rather, we may say, the development of the earth continued
+in a vast unfolding, while that of the moon appears to have been
+absolutely arrested in ways which we will now describe.
+
+With the naked eye we see on the moon a considerable variation in the
+light of different parts of its surface; we discern that the darker
+patches appear to be rudely circular, and that they run together on
+their margins. Seeing this little, the ancients fancied that our
+satellite had seas and lands like the earth. The first telescopes did
+not dispel their fancies; even down to the early part of this century
+there were astronomers who believed the moon to be habitable; indeed,
+they thought to find evidence that it was the dwelling place of
+intelligent beings who built cities, and who tried to signal their
+intellectual kindred of this planet. When, however, strong glasses
+were applied to the exploration, these pleasing fancies were rudely
+dispelled.
+
+Seen with a telescope of the better sort, the moon reveals itself to
+be in large part made up of circular depressions, each surrounded by a
+ringlike wall, with nearly level but rough places between. The
+largest of these walled areas is some four hundred miles in diameter;
+thence they grade down to the smallest pits which the glass can
+disclose, which are probably not over as many feet across. The writer,
+from a careful study of these pits, has come to the conclusion that
+the wider are the older and the smaller the last formed. The rude
+elevations about these pits--some of which rise to the height of ten
+thousand feet or more--constitute the principal topographic reliefs of
+the lunar surface. Besides the pits above mentioned, there are
+numerous fractures in the surface of the plains and ringlike ridges;
+on the most of these the walls have separated, forming trenches not
+unlike what we find in the case of some terrestrial breaks such as
+have been noted about volcanoes and elsewhere. It may be that the
+so-called canals of Mars are of the same nature.
+
+[Illustration: Fig. 23.--Lunar mountains near the Gulf of Iris.]
+
+The most curious feature on the moon's surface are the bands of
+lighter colour, which, radiating from certain of the volcanolike
+pits--those of lesser size and probably of latest origin--extend in
+some cases for five hundred miles or more across the surface. These
+light bands have never been adequately explained. It seems most likely
+that they are stains along the sides of cracks, such as are sometimes
+observed about volcanoes.
+
+The eminent peculiarity of the moon is that it is destitute of any
+kind of gaseous or aqueous envelope. That there is no distinct
+atmosphere is clearly shown by the perfectly sharp and sudden way in
+which the light of a star disappears when it goes behind the moon and
+the clear lines of the edge of the satellite in a solar eclipse. The
+same evidence shows that there is no vapour of water; moreover, a
+careful search which the writer has made shows that the surface has
+none of those continuous down grades which mark the work of water
+flowing over the land. Nearly all of the surface consists of shallow
+or deep pits, such as could not have been formed by water action. We
+therefore have not only to conclude that the moon is waterless, but
+that it has been in this condition ever since the part that is turned
+toward us was shaped.
+
+As the moon, except for the slight movement termed its "libration,"
+always turns the same face to us, so that we see in all only about
+four sevenths of its surface, it has naturally been conjectured that
+the unseen side, which is probably some miles lower than that turned
+toward us, might have a different character from that which we behold.
+There are reasons why this is improbable. In the first place, we see
+on the extreme border of the moon, when the libration turns one side
+the farthest around toward the earth, the edge of a number of the
+great walled pits such as are so plenty on the visible area; it is
+fair to assume that these rings are completed in the invisible realm.
+On this basis we can partly map about a third of the hidden side.
+Furthermore, there are certain bands of light which, though appearing
+on the visible side, evidently converge to some points on the other.
+It is reasonable to suppose that, as all other bands radiate from
+walled pits, these also start from such topographic features. In this
+way certain likenesses of the hidden area to that which is visible is
+established, thus making it probable that the whole surface of the
+satellite has the same character.
+
+Clearly as the greater part of the moon is revealed to us--so clearly,
+indeed, that it is possible to map any elevation of its surface that
+attains the height of five hundred feet--the interpretation of its
+features in the light of geology is a matter of very great
+difficulty. The main points seem to be tolerably clear; they are as
+follows: The surface of the moon as we see it is that which was formed
+when that body, passing from the state of fluidity from heat, formed a
+solid crust. The pits which we observe on its surface are the
+depressions which were formed as the mass gradually ceased to boil.
+The later formed of these openings are the smaller, as would be the
+case in such a slowing down of a boiling process.
+
+As the diameter of the moon is only about one fourth of that of the
+earth, its bulk is only about one sixteenth of that of its planet;
+consequently, it must have cooled to the point of solidification ages
+before the larger sphere attained that state. It is probable that the
+same changeless face that we see looked down for millions of years on
+an earth which was still a seething, fiery mass. In a word, all that
+vast history which is traceable in the rocks beneath our feet--which
+is in progress in the seas and lands and is to endure for an
+inconceivable time to come--has been denied our satellite, for the
+reason that it had no air with which to entrap the solar heat and no
+water to apply the solar energy to evolutionary processes. The heat
+which comes upon the moon as large a share for each equal area as it
+comes upon the earth flies at once away from the airless surface, at
+most giving it a temporary warmth, but instituting no geological work
+unless it be a little movement from the expansion and contraction of
+the rocks. During the ages in which the moon has remained thus
+lifeless the earth, owing to its air and water, has applied a vast
+amount of solar energy to geological work in the development and
+redevelopment of its geological features and to the processes of
+organic life. We thus see the fundamental importance of the volatile
+envelopes of our sphere, how absolutely they have determined its
+history.
+
+It would be interesting to consider the causes which led to the
+absence of air and water on the moon, but this matter is one of the
+most debatable of all that relates to that sphere; we shall therefore
+have to content ourselves with the above brief statements as to the
+vast and far-acting effects which have arisen from the non-existence
+of those envelopes on our nearest neighbour of the heavens.
+
+
+                  METHODS IN STUDYING GEOLOGY.
+
+So far as possible the preceding pages, by the method adopted in the
+presentation of facts, will serve to show the student the ways in
+which he may best undertake to trace the order of events exhibited in
+the phenomena of the earth. Following the plan pursued, we shall now
+consider certain special points which need to be noted by those who
+would adopt the methods of the geologist.
+
+At the outset of his studies it may be well for the inquirer to note
+the fact that familiarity with the world about him leads the man in
+all cases to a certain neglect and contempt of all the familiar
+presentations of Nature. We inevitably forget that those points of
+light in the firmament are vast suns, and we overlook the fact that
+the soil beneath our feet is not mere dirt, but a marvellous
+structure, more complicated in its processes than the chemist's
+laboratory, from which the sustenance of our own and all other lives
+is drawn. We feel our own bodies as dear but commonplace possessions,
+though we should understand them as inheritances from the
+inconceivable past, which have come to us through tens of thousands of
+different species and hundreds of millions of individual ancestors. We
+must overlook these things in our common life. If we could take them
+into account, each soul would carry the universe as an intellectual
+burden.
+
+It is, however, well from time to time to contemplate the truth, and
+to force ourselves to see that all this apparently simple and ordinary
+medley of the world about us is a part of a vast procession of events,
+coming forth from the darkness of the past and moving on beyond the
+light of the present day. Even in his professional work the
+naturalist of necessity falls into the commonplace way of regarding
+the facts with which he deals. If he be an astronomer, he catalogues
+the stars with little more sense of the immensities than the man who
+keeps a shop takes account of his wares. Nevertheless, the real profit
+of all learning is in the largeness of the understanding which it
+develops in man. The periods of growth in knowledge are those in which
+the mind, enriched by its store, enlarges its conception while it
+escapes from commonplace ways of thought. With this brief mention of
+what is by far the most important principle of guidance which the
+student can follow, we will turn to the questions of method that the
+student need follow in his ordinary work.
+
+With almost all students a difficulty is encountered which hinders
+them in acquiring any large views as to the world about them. This is
+due to the fact that they can not make and retain in memory clear
+pictures of the things they see. They remember words rather than
+things--in fact, the training in language, which is so large a part of
+an education, tends ever to diminish the element of visual memory. The
+first task of the student who would become a naturalist is to take his
+knowledge from the thing, and to remember it by the mental picture of
+the thing. In all education in Nature, whether the student is guided
+by his own understanding or that of the teacher, a first and very
+continuous aim should be to enforce the habit of recalling very
+distinct images of all objects which it is desired to remember. To
+this end the student should practise himself by looking intently upon
+a landscape or any other object; then, turning away, he should try to
+recall what he has beheld. After a moment the impression by the sight
+should be repeated, and the study of the memory renewed. The writer
+knows by his own experience that even in middle-aged people, where it
+is hard to breed new habits, such deliberate training can greatly
+increase the capacity of the memory for taking in and reproducing
+images which are deemed of importance. Practice of this kind should
+form a part of every naturalist's daily routine. After a certain time,
+it need not be consciously done. The movements of thought and action
+will, indeed, become as automatic as those which the trained fencer
+makes with his foil.
+
+Along with the habit of visualizing memories, and of storing them
+without the use of words, the student should undertake to enlarge his
+powers of conceiving spaces and directions as they exist in the field
+about him. Among savages and animals below the grade of man, this
+understanding of spacial relations is very clear and strong. It
+enables the primitive man to find his way through the trackless
+forest, and the carrier pigeon to recover his mate and dwelling place
+from the distance of hundreds of miles away. In civilized men,
+however, the habit of the home and street and the disuse of the
+ancient freedom has dulled, and in some instances almost destroyed,
+all sense of this shape of the external world. The best training to
+recover this precious capacity will now be set forth.
+
+The student should begin by drawing a map on a true scale, however
+roughly the work may be done, of those features of the earth about him
+with which he is necessarily most familiar. The task may well be begun
+with his own dwelling or his schoolroom. Thence it may be extended so
+as to include the plan of the neighbouring streets or fields. At
+first, only directions and distances should be platted. After a time
+to these indications should be added on the map lines indicating in a
+general way contours or the lines formed by horizontal planes
+intersecting the area subject to delineation. After attaining certain
+rude skill in such work, the student may advantageously make
+excursions to districts which he can see only in a hurried way. As he
+goes, he should endeavour to note on a sketch map the positions of the
+hills and streams and the directions of the roads. A year of holiday
+practice in such work will, if the tasks occupy somewhere about a
+hundred hours of his time, serve greatly to extend or reawaken what
+may be called the topographic sense, and enable him to place in terms
+of space the observations of Nature which he may make.
+
+In his more detailed work the student should select some particular
+field for his inquiry. If he be specially interested in geologic
+phenomena, he will best begin by noting two classes of facts--those
+exhibited in the rocks as they actually appear in the state of repose
+as shown in the outcrops of his neighbourhood, and those shown in the
+active manifestations of geological work, the decay of the rocks and
+the transportation of their waste, or, if the conditions favour, the
+complicated phenomena of the seashores.
+
+As soon as the student begins to observe, he should begin to make a
+record of his studies. To the novice in any science written, and
+particularly sketched, notes are of the utmost importance. These,
+whether in words or in drawings, should be made in face of the facts;
+they should, indeed, be set down at the close of an observation,
+though not until the observer feels that the object he is studying has
+yielded to him all which it can at that time give. It is well to
+remark that where a record is made at the outset of a study the
+student is apt to feel that he is in some way pledged to shape all he
+may see to fit that which he has first written. In his early
+experience as a teacher, the writer was accustomed to have students
+compare their work of observation and delineation with that done by
+trained men on the same ground. It now seems to him best for the
+beginner at first to avoid all such reference of his own work to that
+of others. So great is the need of developing independent motive that
+it is better at the outset to make many blunders than to secure
+accuracy by trust in a leader. The skilful teacher can give fitting
+words of caution which may help a student to find the true way, but
+any reference of his undertakings to masterpieces is sure to breed a
+servile habit. Therefore such comparisons are fitting only after the
+habit of free work has been well formed. The student who can afford
+the help of a master, or, better, the assistance of many, such as some
+of our universities offer, should by all means avail himself of this
+resource. More than any other science, geology, because of the
+complexity of the considerations with which it has to deal, depends
+upon methods of labour which are to a great extent traditional, and
+which can not, indeed, be well transmitted except in the personal way.
+In the distinctly limited sciences, such as mathematics, physics, or
+even those which deal with organic bodies, the methods of work can be
+so far set forth in printed directions that the student may to a great
+extent acquire sound ways of work without the help of a teacher.
+
+Although there is a vast and important literature concerning geology,
+the greater part of it is of a very special nature, and will convey to
+the beginner no substantial information whatever. It is not until he
+has become familiar with the field with which he is enabled to deal in
+the actual way that he can transfer experience thus acquired to other
+grounds. Therefore beyond the pleasing views which he may obtain by
+reading certain general works on the science, the student should at
+the outset of his inquiry limit his work as far as possible to his
+field of practice, using a good text-book, such as Dana's Manual of
+Geology, as a source of suggestions as to the problems which his field
+may afford.
+
+The main aim of the student in this, as in other branches of inquiry,
+is to gain practice in following out the natural series of actions. To
+the primitive man the phenomenal world presents itself as a mere
+phantasmagoria, a vast show in which the things seen are only related
+to each other by the fact that they come at once into view. The end of
+science is to divine the order of this host, and the ways in which it
+is marshalled in its onward movement and the ends to which its march
+appears to be directed. So far as the student observes well, and thus
+gains a clear notion of separated facts, he is in a fair way to
+gather the data of knowledge which may be useful; but the real value
+of these discernments is not gained until the observations go
+together, so as to make something with a perspective. Until the store
+of separate facts is thus arranged, it is merely crude material for
+thought; it is not in the true meaning science, any more than a store
+of stone and mortar is architecture. When the student has developed an
+appetite for the appreciation of order and sources of energy in
+phenomena, he has passed his novitiate, and becomes one of that happy
+body of men who not only see what is perceived by the mass of their
+fellows, but are enabled to look through those chains of action which,
+when comprehended, serve to rationalize and ennoble all that the
+senses of man, aided by the instruments which he has devised, tell us
+concerning the visible world.
+
+
+
+
+
+                                INDEX.
+
+    AEtna, Mount, 381.
+
+    Agriculture,
+      American, 346;
+      in England, winning swamp lands for, 335;
+      recent developments of, 345.
+
+    Alaska, changes on the coast of, 96.
+
+    Ants taking food underground, 319;
+      work of the, on the soil, 318.
+
+    Apsides, revolution of the, 61, 62.
+
+    Arabians, chemical experiments of the, 13.
+
+    Arches, natural, in cavern districts, 258.
+
+    Artesian wells, 258, 259.
+
+    Arts, advance of Italian fine, 19.
+
+    Asteroids, 53;
+      motions of, about their centres and about the sun, 53.
+
+    Astronomers, the solar system and the early, 79.
+
+    Astronomy, 31-80;
+      growth of, since the time of Galileo, 33, 34;
+      the first science, 10.
+
+    Atmosphere, 97-206;
+      along the tropical belt, 102;
+      as a medium of communication between different regions, 99;
+      deprived of water, containing little heat, 105;
+      beginning of the science of the, 117;
+      counter-trade movements of the, 105;
+      envelope of the earth, 98;
+      expansion of, in a hollow wall during the passage of a storm, 114;
+      heat-carrying power of the, 105;
+      heights to which it extends, 99;
+      in water, 99;
+      movements no direct influence on the surface of the earth, 122;
+      movements of the, qualified by the condition which
+            it encounters, 118;
+      of mountains, 98;
+      of the seashore, 98;
+      of the earth, 98;
+      of the sun, 73;
+      snow as an evidence of, 65;
+      supplying needs of underground creatures, 331;
+      uprushes of, 101, 102;
+      upward strain of the, next the earth, 107;
+      weight and motion of the, 120, 121.
+
+    Atmospheric circulation of the soil, 330, 331;
+      envelopes, 97.
+
+    Aurora borealis, 168.
+
+    Avalanches, 210-213;
+      dreaded, in the Alpine regions, 212;
+      great, in the Swiss Oberland, 211, 212;
+      rocky, 175-177.
+
+    Axis,
+      imaginary changes in the earth's, 59;
+      of the earth's rotation, 58;
+      polar, inclined position of, 58;
+      polar, nodding movement of the axes, 54;
+      rotations of the planetary spheres on their axes, 56.
+
+
+    Barometer, causes of changes in the, 117, 118.
+
+    Basalts, 309.
+
+    Beaches, 93, 142, 144;
+      boulder, 142, 143;
+      pebbly, 142;
+      sand, 144.
+
+    Beetles, work of, on the soil, 318, 319.
+
+    Belief of the early astronomers about the solar system, 79.
+
+    _Bergschrund_, the, 214.
+
+    Birds and mammals contributing to the fertility of the soil, 319.
+
+    "Blanketing," 269.
+
+    Bogs,
+      climbing, 331-334;
+      lake, 331-333;
+      peat, 334, 335;
+      quaking, 334.
+
+    Botany, rapid advance in, 14, 15.
+
+    Boulders, 217, 220.
+
+    Breakers, 135, 137, 139.
+
+    Bridges, natural, 257, 258.
+
+
+    Canals of Mars, 67.
+
+    Canon, newly formed river cutting a, 195.
+
+    Cataracts, 193.
+
+    Caves, 253-258, 261;
+      architecture of, 255-258;
+      hot-water, 261;
+      mammoth cave, 258;
+      stalactites and stalagmites on the roof and floor of, 257.
+
+    Chasms, 140, 141.
+
+    Chemistry, 6, 12, 14;
+      advance of, 12;
+      modern, evolving from the studies of alchemists, 13, 14.
+
+    Chromosphere, 73.
+
+    Civilization of the Icelanders, 384.
+
+    Cliffs, sea-beaten, 132, 141, 142.
+
+    Climate,
+      changes of, due to modifications of the ocean streams, 153;
+      effect of the ocean on the, 147;
+      of the Gulf Stream, 149, 150.
+
+    Clouds, 159;
+      formation of, 162, 163;
+      shape of, 163;
+      water of, usually frozen, 207;
+      cloud-making, laws of, 161, 162.
+
+    Coast,
+      changes on the Scandinavian, 96;
+      line, effect of tide on the, 145;
+      of Greenland, 226;
+      of New Jersey sinking, 95;
+      marine, changes in, 95.
+
+    Cold in Siberia, 243.
+
+    Comets, 47, 50;
+      collisions of, 50;
+      kinship of meteorites and, 48;
+      omens of calamity to the ancients, 50;
+      the great, of 1811, 49, 50.
+
+    Cones. See under VOLCANOES.
+
+    Conflict between religion and science, 20, 22;
+      between the Protestant countries and the followers of science, 20.
+
+    Continental shelves, 125.
+
+    Continents and oceans, 83;
+      changes in position of, 91;
+      cyclones of the, 111;
+      forms of, 90;
+      proofs that they have endured for many years, 92;
+      shape of, 84, 96.
+
+    Coral reefs, 153, 353.
+
+    Corona, realm of the, 73.
+
+    Craters. See under VOLCANOES.
+
+    Crevasse, a barrier to the explorer, 218.
+
+    Crevice water, 250.
+
+    Curds, 214.
+
+    Currents,
+      coral reefs in Florida affecting the velocity of, 153;
+      equatorial, 150;
+      of the Gulf Stream, 147-149;
+      hot and cold, of the sea, 102;
+      ocean, 145;
+      oceanic action of trade winds on, 145;
+      effect on migration of, 157;
+      icebergs indicating, 243;
+      surface, history of, 172;
+      uprushing, near the equator, 106.
+
+    Cyclones, 111;
+      cause of, 111;
+      of North America, 111;
+      secondary storms of, 112.
+
+
+    Deltas, 173, 187.
+
+    Deposits, vein, 260, 261.
+
+    Deserts, interior, 158.
+
+    Dew, 159, 160;
+      a concomitant of cloudless skies, 160,
+        and vegetation, 160;
+      formation of, 159-161.
+
+    Diablerets, 174.
+
+    Diagram of a vein, 260;
+      showing development of swamp, 335;
+      how a portion of the earth's surface may be sunk by faulting, 374;
+      growth of mangroves, 340;
+      the effect of the position of the fulcrum point
+            in the movement of the land masses, 94.
+
+    Diameter of our sphere at the equator, 62;
+       of the earth, 82.
+
+    Dikes, 192, 293; 305-310;
+      abounding in volcanic cones, 305;
+      cutting through coal, 306;
+      driven upward, 307;
+      formation of, 305, 310;
+      material of, 307, 308;
+      representing movements of softened rock, 309;
+      their relation to volcanic cones, 307;
+      variations of the materials of, 307, 308;
+      waterfalls produced by, 192;
+      zone of, 306.
+
+    Dismal Swamp, 95, 333.
+
+    Distances,
+      general idea of, 27;
+      good way to study, 27, 28;
+      training soldiers to measure, 28.
+
+    Doldrums, 104, 109;
+      doldrum of the equator, 109;
+      of the hurricane, 109.
+
+    Drainage, imperfect, of a country affected by glaciers, 242.
+
+    Dunes, 123, 124, 325, 326, 387;
+      moulded, 387.
+
+    Duration of geological time, 389.
+
+    Dust accumulations from wind, in China, 122.
+
+
+    Earth,
+      a flattened sphere, 82;
+      air envelope of the, 98;
+      amount of heat falling from the sun on the, 41;
+      antiquity of the, 391;
+      atmosphere of the, 98;
+      attracting power of the, 127;
+      axis of the rotation of the, 58;
+      composition of the atmosphere of the, 98;
+      crust of the, affected by weight, 93;
+      deviation of the path of the, varied, 61;
+      diameter of the, 82;
+        of the, affected by loss of heat, 131;
+      difference in altitude of the surface of the, 83;
+      discovery that it was globular, 31, 32;
+      effect of imaginary changes in the relations of sun and, 59;
+      effect of the interior heat of the, 309, 310;
+      effect of the sun on the, 60, 61;
+      formerly in a fluid state, 82;
+      imaginary view of the, from the moon, 81;
+      important feature of the surface of the, 83;
+      jarring caused by faults, 367;
+      surface of the, determined by heat and light from the sun, 57;
+      most important feature of the surface of the, 83;
+      motion of the, affecting the direction of trade winds, 103;
+      movements, 366;
+      natural architecture of the, 377;
+      no part of the, exempt from movement, 384;
+      parting of the moon and, 396;
+      path of the, around the sun, 55, 56, 59, 60;
+      revolving from east to west, 103;
+      shrinking of the, from daily escape of heat, 89;
+      soil-covering of the, 343;
+      study of the, 81-96;
+      swaying, 385;
+      tensions, problem of, 371;
+      tremors, caused by chemical changes in the rocks, 385;
+      tropical belt of the, 74;
+      viewed from the surface of the moon, 311, 312;
+      water store of the, 125.
+
+    Earthquakes, 277, 278, 280, 356, 358, 370-384, 388-390;
+      accidents of, 358;
+      action of, 356;
+      agents of degradation, 383, 384;
+      basis of, 367;
+      certain limitations to, 380, 381;
+      Charleston, of 1883, 374, 375;
+      countries, architecture in, 381;
+      echoes, 369, 370;
+      damages of, 377, 390;
+      effect of,
+        on the soil, 375;
+        the surface of the earth, 371;
+      formed by riving of fissures, 382;
+      great, occurring where rocks have been
+            disturbed by mountain-building, 381, 382;
+      Herculaneum and Pompeii destroyed by an, 277, 280;
+      Italian, in 1783, 371, 372;
+      important, not connected with volcanic explosions, 381;
+      Jamaica, in 1692, 372, 376;
+      Lisbon, in 1755, 368, 369, 373, 374, 381;
+      maximum swing of, 369;
+      measuring the liability to, 386, 387;
+      mechanism of, 370, 371;
+      method of the study of, followed by Mr. Charles Mallet, 382, 383;
+      Mississippi, in 1811, 373, 374, 380, 381;
+      movement of the earth during, 377;
+      originating from a fault plane, 367, 369, 370;
+      originating from the seas, 358, 375;
+      oscillation of, 376;
+      poised rocks indicating a long exemption from strong, 388;
+      Riobamba, in 1797, 375;
+      shocks of, and their effect upon people, 383;
+      the direct calamities of Nature, 386;
+      waves of, 389.
+
+    Earthworms, 317-319;
+      taking food underground, 319.
+
+    Eclipses, record of ancient, 130.
+
+    Electrical action in the formation of rain and snow, 164.
+
+    Elevations of seas and lands, 83.
+
+    Energy indestructible, 23.
+
+    Envelope, lower, of the sun, 74.
+
+    Equator,
+      diameter of our sphere at the, 62;
+      doldrum of the, 109;
+      updraught under the, 102;
+      uprushing current near the, 106.
+
+    Equinoxes, precession of the, 61, 62.
+
+    _Eskers_, 221.
+
+    Expansion of air contained in a hollow wall during the
+            passage of the storm, 114.
+
+    Experiment, illustrating consolidation of disseminated
+            materials of the sun and planets, 40.
+
+
+    Falls. See WATERFALLS.
+
+    Fault planes, 382.
+
+    Feldspar, 324.
+
+    Floods, 180, 197;
+      rarity of, in New England, 121;
+      river, frequent east of Rocky Mountains, 198.
+
+    Foehns, 121.
+
+    Forests, salicified, 124.
+
+    Fossilization, 354-356.
+
+    Fulcrum point, 95.
+
+
+    Galactic plane, 45.
+
+    Galongoon, eruption of, 294.
+
+    Geological work of water, 168-206.
+
+    Glacial action in the valleys of Switzerland, 224;
+      periods, 63, 243, 246;
+      in the northern hemisphere, 246;
+      waste, 324.
+
+    Glaciation,
+      effect of,
+        in North America, 241;
+        in Central America, 234;
+        South America, 234.
+
+    Glaciers, 207-249;
+      action of ice in forming, 230-232;
+      Alaskan, 216;
+      continental, 225, 239, 240;
+      discharge of, 220;
+      exploring, 220;
+      extensive, in Greenland and Scandinavia, 244;
+      former, of North America, 232, 234;
+      map of, and moraines near Mont Blanc, 217;
+      motions of, 213;
+      retreat of the, 228, 230, 235;
+      secrets of the under ice of, 221;
+      speed of a, 224;
+      study of, in the Swiss valleys, 222;
+      testimony of the rocks regarding, 228;
+      when covered with winter snows, 216;
+      valley, 216.
+
+    Gombridge, 1830, 74.
+
+    Gravitation, law of, 4.
+
+    Greeks' idea of the heavens, 31;
+      not mechanically inventive, 22.
+
+    Gulf Stream, current of the, 147.
+
+
+    Heat,
+      amount of, daily escaping from the earth, 89;
+      amount of, falling from the sun on the earth, 41;
+      belief of the ancients regarding, 42;
+      dominating effect on air currents of tropical, 104;
+      energy with which it leaves the sun, 41;
+      internal,
+        of the earth, 88, 89;
+        of the earth's interior, 309, 310;
+      sun, effect on the atmosphere of the, 100;
+      Prof. Newcomb's belief regarding the, of the sun, 52;
+      radiation of the earth's, causing winds, 101;
+      solar, 41;
+      tropical, and air currents, 104.
+
+    Hills, sand, 123.
+
+    Horizontal pendulum, 384.
+
+    Horse latitudes, 104.
+
+    "Horses," 261.
+
+    Hurricanes, 107, 110, 317;
+      commencement of, 107;
+      doldrum of, 109;
+      felt near the sea, 110;
+      in the tropics, 110.
+
+    Hypothesis,
+      nebular, 34, 35, 39, 52, 56;
+      working, 4, 5.
+
+
+    Ice action,
+      effect of intense, 222, 223;
+      in forming glaciers, 230, 232;
+      recent studies in Greenland of, 239;
+      depth of, in Greenland, 227;
+      effect of, on river channels, 196;
+      effect of, on stream beds, 196;
+      expanding when freezing, 237;
+      epoch, 92, 93, 246;
+      floating, 242;
+      made soils rarely fertile, 241;
+      mass, greatest, in Greenland, 226, 227;
+      moulded by pressure, 215;
+      streams,
+        continental, 225, 226;
+        of the mountains, 225;
+        of the Himalayan Mountains, 234.
+
+    Icebergs, 242, 243;
+      indicating oceanic currents, 243.
+
+    Iceland, volcanic eruptions in, 297, 298.
+
+    Instruments, first, astronomical, 10, 11.
+
+    Inventions, mechanical, aiding science, 22.
+
+    Islands, 84, 272;
+      continental, 84;
+      in the deeper seas made up of volcanic ejections, 272;
+      volcanic, 272.
+
+
+    Jack-o'-lantern, 167.
+
+    Jupiter,
+      gaseous wraps of, 97;
+      path of the earth affected by, 59, 60;
+      the largest planet of the sun, 69.
+
+
+    Kames, 325.
+
+    Kant, Immanuel, and nebular hypothesis, 34.
+
+    Kaolin, 324.
+
+    Klondike district, cold in, 243, 244.
+
+    Krakatoa,
+      eruption of, 298-300;
+        effect of, on the sea, 299;
+        effect of, on the sun, 300.
+
+
+    Lacolites, 306.
+
+    Lacustrine beds, 351.
+
+    Lagoons, salt deposits found in, 200.
+
+    Lake basins,
+      formation of, 200, 201;
+      bogs, 331, 333, 334;
+      deposits, 350, 351.
+
+    Lakes, 199-206;
+      effect of, on the river system, 205;
+      fresh-water, 145;
+      formed from caverns, 202;
+      great, changing their outlets, 205;
+      of extinct volcanoes, 203;
+      temporary features of the land, 203;
+      volcanic, 203.
+
+    Lands,
+      great, relatively unchangeable, 96;
+      table, 91;
+      movements resulting in change of coast line, 351, 352;
+      shape of the seas and, 83, 84;
+      accounting for the changes in the attitude of the, 95;
+      and water, divisions of, 84;
+      dry, surface of, 85;
+      general statement as to the division of the, 83, 84;
+      surface, shape of the, 85;
+      triangular forms of great, 90.
+
+    Latitudes, horse, troublesome to mariners, 104.
+
+    Laplace and nebular hypothesis, 34.
+
+    Lava, 266-268, 270, 271, 292, 293, 295, 296, 303, 304;
+      flow of, invading a forest, 268;
+      from Vesuvius, 293;
+      of 1669, 295, 296;
+      temperature of, 295, 296;
+      incipient, 304;
+      outbreaks of, 292, 303;
+      stream eaves, 292, 293.
+
+    Law, natural,
+      Aristotle and, 3;
+      of gravitation, 4;
+      of the conservation of energy, 23.
+
+    Leaves, radiation of, 160.
+
+    Length of days affected by tidal action, 131.
+
+    Level surfaces, 91.
+
+    Life, organic, evolution of, 15, 16.
+
+    Light, belief of the ancients regarding, 42.
+
+    Lightning, 24, 164-168;
+      noise from, 166;
+      proceeding from the earth to the clouds, 165;
+      protection of buildings from, 165;
+      stroke, wearing-out effect of, 165.
+
+    Limestones, 353, 357, 358, 360, 364;
+      formation of, 357, 360.
+
+    Lisbon, earthquake of, 1755, 368, 369.
+
+    Lowell, Mr. Percival, observations on Venus, 64.
+
+    Lunar mountains near the Gulf of Iris, 397.
+
+
+    Mackerel sky, 35.
+
+    Mallet, Mr. Charles, and the study of earthquakes, 382, 383.
+
+    Man as an inventor of tools, 10.
+
+    Mangroves, 340;
+      diagram showing mode of growth, 340;
+      marshes of, 339.
+
+    Map of glaciers and moraines near Mont Blanc, 217;
+      of Ipswich marshes, 338.
+
+    Mapping with contour lines, 27.
+
+    Maps,
+      desirable, for the study of celestial geography, 77;
+      geographic sketch, 26, 27.
+
+    Marching sands jeopardizing agriculture, 123.
+
+    Marine animals, sustenance of, 361-363;
+      deposits, 325-327, 349, 356;
+      marshes, 336-340;
+      waves caused by earthquakes, 387.
+
+    Mars, 65-67, 84, 97;
+      belief that it has an atmosphere, 65;
+      canals of, 67;
+      gaseous wraps of, 97;
+      more efficient telescopes required for the study of, 67;
+      nearer to the earth than other planets, 65.
+
+    Marshes,
+      mangrove, 339;
+      map of Ipswich, 338;
+      marine, 336-340;
+      deposits found in, 336;
+      of North America, 337;
+      on the coast of New England, 339;
+      phenomena of, 167, 168;
+      tidal, good earth for tillage, 337;
+      tidal, of North America, 340.
+
+    Mercury, 55, 63, 78;
+      nearest to the sun, 63;
+      time in which it completes the circle of its year, 55.
+
+    Meteorites, 47, 48;
+      kinship of comets and, 48.
+
+    Meteors, 47;
+      falling, 47;
+      composition of, 48;
+      flashing, 39, 40, 47;
+      speed of, 47;
+      inflamed by friction with air, 99.
+
+    Methods in studying geology, 400.
+
+    Milky Way, 45;
+      voyage along the path of the, 44, 45.
+
+    Mineral crusts, 328, 329;
+      deposits, 308.
+
+    Moon, 38, 395-400;
+      absence of air and water on the, 399;
+      attended by satellites, 57;
+      attraction which it exercises on the earth, 62;
+      curious feature of the, 397;
+      destitute of gaseous or aqueous envelope, 397;
+      diameter of the, 399;
+      imaginary view of the earth from the, 81;
+      "libration" of the, 398;
+      made up of circular depressions, 396, 397;
+      movements of the, 78;
+      no atmosphere in the, 97;
+      parting of the earth and, 396;
+      position of the, in relation to the earth, 62;
+      tidal action and the, 131;
+      tides of the, 126, 127;
+      why does the sun not act in the same manner as the, 78.
+
+    Moraines, 216, 218, 229, 230;
+      map of glaciers and, near Mont Blanc, 217;
+      movements of the, 216-218;
+      terminal, 228.
+
+    _Moulin_, 219.
+
+    Mount AEtna, 288-310;
+      lava yielding, 290, 293, 294;
+      lava stream caves of, 292, 293;
+      more powerful than Vesuvius, 297;
+      peculiarities of, 291, 292;
+      size of, 289-291;
+      turning of the torrents of, 295.
+
+    Mountain-building, 90-93, 304;
+      folding, 86, 87, 90, 365;
+        attributed to cooling of the earth, 88;
+      growth, 392;
+      Swiss falls, 174;
+      torrents, energy of, 177.
+
+    Mountains, 85, 86, 89, 90-93; 174-178;
+      form and structure of, 86;
+      partly caused by escape of heat from the earth, 89;
+      sections of, 87.
+
+    Mount Nuova, formation of, 284.
+
+    Mount Vesuvius, 263-285, 288, 289, 293, 302, 381;
+      description of the eruption of, in A.D. 79, 277-280;
+      diagrammatic sections through, showing changes in the form
+            of the cone, 283;
+      eruption of, in 1056, 281;
+      in 1882-'83, 264, 266;
+      eruption of, in 1872, 282;
+      eruptions of, increased since 1636, 282;
+      flow of lava from, 285;
+      likely to enter on a period of inaction, 282, 283;
+      outbreak of, in 1882-'83, 264, 266.
+
+
+    Naples, prosperity of the city, 289.
+
+    Nebular hypothesis, 34, 35, 39, 52.
+
+    Neptune, 70.
+
+    _Neve_, the, 214;
+      no ice-cutting in the region of the, 224.
+
+    Newcomb's (Prof.) belief regarding the heat of the sun, 52.
+
+    Niagara Falls, 191, 192, 204;
+      cutting back of, 204.
+
+    North America,
+      changes in the form of, 91, 92;
+      triangular form of, 90.
+
+
+    Ocean,
+      average depth of the, 89;
+      climatal effect of the, 147;
+      currents, 145;
+      effect of, on migration, 156;
+      effect of, on organic life, 154;
+      floor, 85, 93;
+      hot and cold currents of the, 102;
+      sinking of the, 93, 94;
+      the laboratory of sedimentary deposits, 351;
+      depth of the, 89, 126.
+
+    Oceanic circulation, effect of, on the temperature, 152.
+
+    Oceans and continents, 83.
+
+    Orbit,
+      alterations of the, and the seasons, 60, 61;
+      changing of the, 59-63;
+      shape of the, 61-63.
+
+    Organic life, 315, 317, 321, 352, 353, 363;
+      action of, on the soil, 317, 321;
+      advantages of the shore belt to, 363;
+      development of in the sea, 352, 353;
+      effect of ocean currents on, 154;
+      processes of, in the soil, 315;
+      decay of, in the earth, 321.
+
+    Orion, 46.
+
+    Oscillations of the shores of the Bay of Naples, 287.
+
+    Oxbow of a river, 182, 183.
+
+    Oxbows and cut-off, 182.
+
+
+    Pebbles,
+      action of seaweeds on, 143;
+      action of the waves on, 142, 144.
+
+    Photosphere, 74.
+
+    Plains, 86;
+      alluvial, 91, 179, 182, 184-186, 325;
+      history of, 91;
+      sand, 325.
+
+    Planets, 38;
+      attended by satellites, 57;
+      comparative sizes of the, 68;
+      experiments illustrating consolidation of disseminated
+            materials of the sun and, 40;
+      gaseous wraps of, 97;
+      important observations by the ancients of fixed stars
+            and planets, 43;
+      movements of, 57-61;
+      outer, 78;
+      table of relative masses of sun and, 77.
+
+    Plant life in the Sargassum basins, 156.
+
+    Plants and animals,
+      protection of,
+        by mechanical contrivances, 364;
+        and trees, work of the roots of, on the soil, 316, 317;
+      water-loving, 181;
+      forming climbing bogs, 332.
+
+    Polar axes, nodding movement of, 54.
+
+    Polar snow cap, 66.
+
+    Polyps, 155, 353.
+
+    Pools, circular, 203.
+
+    Prairies, 340, 342.
+
+
+    Radiation of heat, 159.
+
+    Rain, 152, 156, 164, 168, 170, 328, 330;
+      circuit of the, 156-168;
+      drops, force of, 169, 170;
+      spheroidal form of, 170;
+      electrical action in the formation of snow and, 164;
+      work of the, 171.
+
+    Realm, unseen solar, 75.
+
+    Reeds, 332.
+
+    Religion,
+      conflict between science and, 20, 22;
+      struggle between paganism and, 21.
+
+    Rivers and _debris_, 183;
+      changes in the course of, in alluvial plain, 182;
+      deposition of, accelerated by tree-planting, 181;
+      great, always clear, 205;
+      inundation of the Mississippi, eating away land, 182;
+      muds, 222;
+      newly formed, cutting a canon, 195;
+      of snow-ice, 211;
+      origin of a normal, 173;
+      oxbow of a, 182,183;
+      sinking of, 199;
+      swinging movement of, 179-181;
+      river-valleys, 193, 194;
+      diversity in the form of 188-191.
+
+    Rocks, 145;
+      accidents from falling, 174;
+      cut away by sandstones, 188;
+      divided by crevices, 252;
+      duration of events recorded in, 389, 390,
+      ejection of, material, 311;
+      falling of, 174-176;
+      formation of, 262, 263;
+      from the present day to the strata of the Laurentian, 390;
+      migration of, 291;
+      poised, indicating a long exemption from strong earthquakes, 388;
+      rents in, 252, 253;
+      stratification of, 349, 350, 352, 365, 390;
+      testimony of the, in regard to glaciers, 228;
+      under volcanoes, 303;
+      variable elasticity of, 366;
+      vibration of, 367, 368;
+      rock-waste, march of the, 343;
+      water, 250, 267.
+
+    Rotation of the earth affected by tides, 130;
+      of the planetary spheres on their axes, 56.
+
+
+    Salicified forests, 124.
+
+    Salt deposits formed in lagoons, 200;
+      found in lakes, 199-200.
+
+    Sand bars, 183;
+      endurance of, against the waves, 145;
+      hills, travelling of, 123;
+      marching, 123;
+      silicious stones cutting away rooks, 188.
+
+    Satellites, 53, 54;
+      motions of, about their centres and about the sun, 53, 54.
+
+    Saturn, 38, 53, 57, 396;
+      cloud bands of, 70;
+      gaseous wraps of, 97;
+      path of the earth affected by, 59, 60.
+
+    Savages, primitive, students of Nature, 1.
+
+    Scandinavia, changes on the coasts of, 96.
+
+    Science,
+      advance of, due to mechanical inventions, 22;
+      astronomy beginning with, 10;
+      chemical, characteristics of, 14;
+      conflict between religion and, 20, 22;
+      conflict between the Roman faith and, 20;
+      mechanical inventions as aids to, 22, 23;
+      modern and ancient, 4;
+      natural, 5, 6;
+      of botany in Aristotle's time, 14;
+      of physiology, 15;
+      of zooelogy in Aristotle's time, 14;
+      resting practically on sight, 10.
+
+    Scientific development,
+      historic outlines of, 17;
+      tools used in measuring and weighing, as an aid to vision, 12.
+
+    Sea,
+      battering action of the, 140;
+      coast ever changing, 385, 386;
+      effect of volcanic eruptions on the, 299;
+      floor deposits of the, affected by volcanoes, 360, 361;
+      in receipt of organic and mineral matter, 359;
+      hot and cold currents of the, 102;
+      littoral zone of the, 351, 352;
+      puss, 142;
+      rich in organic life, 352, 353;
+      solvent action of the, 361;
+      strata, formation of, 354;
+      water, minerals in, 185;
+      weeds, 155, 156.
+
+    Seas, dead,
+      originally living lakes, 200;
+      water of, buoyant, 199;
+      eventually the seat of salt deposits, 199-201;
+      general statement as to division of, 83, 84;
+      shape of the, 83, 84.
+
+    Seashore, air of the, 98.
+
+    Seasons, changing the character of the, 61, 62.
+
+    Sense of hearing, 9,10;
+      of sight, 10;
+      of smell, 9, 10;
+      of taste, 9, 10;
+      of touch, 9, 10.
+
+    _Seracs_, 214.
+
+    Shocks, earthquake. See under EARTHQUAKES.
+
+    Shore lines, variation of, 83, 84.
+
+    Shores, cliff, 138-142.
+
+    Sink holes, 202;
+      in limestone districts, 253, 254.
+
+    Skaptar,
+      eruption of, 297, 298;
+      lava from the eruption of, 298.
+
+    Sky, mackerel, 35.
+
+    Snow, 207-225, 244;
+      as an evidence of atmosphere, 65;
+      blankets, early flowers beginning to blossom under, 208;
+      covering, difference between an annual and perennial, 210;
+      effect of, on plants, 208;
+      electrical action in the formation of rain and, 164;
+      flakes, formation of, 164;
+      red, 210;
+      slides, 210;
+      slides, phenomena of, 210, 211.
+
+    Soil,
+      alluvial, 321, 322;
+      atmospheric circulation of, 330, 331;
+      conditions leading to formation of, 313, 331;
+      continuous motion of the, 314;
+      covering of the earth, 343;
+      decay of the, 314, 315;
+      degradation of the, 344-348;
+      means for correcting, 346-348;
+      destruction in grain fields greater than the accumulation, 344;
+      developing on lava and ashes an interesting study, 343;
+      development of, in desert regions, 340;
+      effect of animals and plants on the, 317-320;
+      effect of earthquakes on the, 375;
+      fertility of the, distinguished from the coating, 344, 345;
+      fertility of, affected by rain, 327;
+      formation of, 314-321;
+      glacial, characteristics of, 324;
+      glaciated, 323, 324;
+      irrigation of the, 328-330;
+      local variation of, 327;
+      mineral, 321;
+      of arid regions fertile when subjected to irrigation, 341;
+      of dust or blown sand, 321;
+      of immediate derivation, 321, 322;
+      phenomena, 313;
+      processes of organic life in the, 315;
+      variation in, 321-331;
+      vegetation protecting the, 316, 317;
+      washing away of the, 346, 347;
+      winning, from the sea, 337;
+      work of ants on the, 318;
+      tiller, duty of the, 348.
+
+    Solar bodies,
+      general conditions of the, 63-71;
+      forces, action of, on the earth, 349;
+      system, 52, 56;
+      independent from the fixed stars system, 43;
+      original vapour of, 52, 53;
+      singular features of our, 68;
+      tide, 127.
+
+    Spheres,
+      difference in magnitude of, 51;
+      motions of the, 50, 51;
+      planetary, rotation of, on their axes, 56.
+
+    Spots, sun, 72.
+
+    Spouting horn, 141.
+
+    Springs, formation of small, 252.
+
+    Stalactitization, 256.
+
+    Stalagmites and stalactites on the roof and floor of a cavern, 257.
+
+    Stars as dark bodies in the heavens, 47;
+      discovery of Fraunhofer and others on, 23, 38;
+      double, 39;
+      and tidal action, 131;
+      earliest study of, 10;
+      fixed, important observations by the ancients of planets and, 43;
+      not isolated suns, 38, 39;
+      variation in the light of, 46;
+      limit of, seen by the naked eye, 11;
+      revolution of one star about another, 46, 47;
+      shooting, 47;
+      speed of certain, 51;
+      study of, 31-80;
+      sudden flashing forth of, due to catastrophe, 46;
+      voyage through the, 44, 45;
+      star, wandering, 74.
+
+    Stellar realm, 31-80.
+
+    Storms,
+      circular, 111;
+      desert, 121, 122;
+      expansion of air contained in a hollow wall during
+            the passage of, 114;
+      great principle of, 105, 106;
+      in the Sahara, 121;
+      lightning, more frequent in summer, 167;
+      paths of, 115;
+      secondary, of cyclones, 112;
+      spinning, 115;
+      thunder, 165-167;
+      whirling, 106, 124;
+      whirling peculiarity of, 108, 109.
+
+    Strabo, writings of, 18.
+
+    Sun,
+      atmosphere of the, 73;
+      constitution of the, 72;
+      distance of the earth from the, 29;
+      effect from changes in the, and earth, 59;
+      envelope of the, 73, 74, 97;
+      experiments illustrating consolidation of disseminated
+            materials of planets and, 40;
+      finally, dark and cold, 42;
+      formation of the eight planets of the, 53;
+      heat leaving the, 41;
+      heat of the, 76;
+      imaginary journey from the, into space, 44;
+      mass of the, 76, 77;
+      path of the earth around the, 55;
+      physical condition of the, 71;
+      Prof. Newcomb's belief regarding the heat of the, 52;
+      spots, 75;
+        abundant at certain intervals, 72;
+        difficulty in revealing cause of, 75;
+      structure of the, a problem before the use of the telescope, 72;
+      table of relative masses of, and planets, 77;
+      three stages in the history of the, 71;
+      tides, 126;
+      why does it not act in the same manner as the moon? 78.
+
+    Surfaces, level, 90.
+
+    Surf belt, swayings of the, 137.
+
+    Swamps,
+      diagram showing remains of, 335;
+      Dismal Swamp, 95, 333;
+      drainage of, 334, 335;
+      fresh-water, 334, 335;
+      phenomena of, 167, 168.
+
+
+    Table-lands, 91.
+
+    Table of relative masses of sun and planets, 77.
+
+    Telescopes, 11, 12, 45;
+      first results of, 72;
+      power of, 11;
+      revelations of, 45.
+
+    Temperature,
+      effects of, produced by vibration, 42;
+      in the doldrum belt, 118;
+      of North America, 118;
+      of the Atlantic Ocean, 118.
+
+    Tempests, rate of, 99, 100.
+
+    Thunder, 166;
+      more pronounced in the mountains, 166.
+
+    Thunderstorms, 165, 166;
+      distribution of, 166, 167.
+
+    Tidal action,
+      recent studies of, 131, 132;
+      marshes of North America, 340.
+
+    Tides,
+      carving channels, 129;
+      effecting the earth's rotation, 130;
+      effect of, on marine life, 130;
+      height of, 128, 129;
+      moon and sun, 126, 127;
+      normal run of the, 127;
+      production of, 131;
+      of the trade winds, 150;
+      solar, 127;
+      travelling of, 127, 128.
+
+    Tillage introducing air into the pores of the soil, 331.
+
+    Tornadoes, 112, 113, 317;
+      development of, 113;
+      effect of, on buildings, 113;
+      fiercest in North America, 113;
+      length of, 115;
+      resemblance of, to hurricanes, 115;
+      upsucking action of, 114, 115.
+
+    Torrents, 177-179, 204.
+
+    Trade winds. See under WINDS.
+
+    Training in language,
+      diminishing visual memory, 401;
+      soldiers to measure distances, 28;
+        to measure intervals of time, 28;
+      for a naturalist, 25-29.
+
+    Tunnels, natural, 257.
+
+
+    Uranus, 70.
+
+
+    Valley of Val del Bove formed from disturbances of Mount AEtna, 294.
+
+    Valleys,
+      diversity in the form of river, 188-191;
+      river, 193.
+
+    Vapour, 156, 157, 159, 163;
+      gravitative attraction of, 34, 35;
+      nebular theory of, 52, 53;
+      original, of the solar system, 52, 53.
+
+    Vegetation,
+      and dew, 160;
+      in a measure, independent of rain, 160;
+      protecting the soil, 316, 317.
+
+    Vein, diagram of a, 260.
+
+    Venus, 64, 78;
+      recent observations of, by Mr. Percival Lowell, 64.
+
+    Vesuvian system, study of the, 285.
+
+    Vesuvius. See MOUNT VESUVIUS.
+
+    Visualizing memories, 402, 403.
+
+    Volcanic action, 268-276.
+
+    Volcanic eruption of A.D. 79, 288;
+      important facts concerning, 276-279;
+      islands, 272;
+      lava a primary feature in, 266;
+      observations of, made from a balloon, 301;
+      peaks along the floor of the sea, 272, 273;
+      possibility of throwing matter beyond control of gravitative
+            energy, 300.
+
+    Volcanoes, 125, 203, 263;
+      abounding on the sea floor, 302;
+      accidents from eruptions of, 288;
+      along the Pacific coast, 271;
+      ash showers of, maintaining fertility of the soil, 289;
+      distribution of, 271;
+      eruption of, 286-294, 368;
+      explosions from, coming from a supposed liquid interior
+            of the earth, 275;
+      exporting earth material, 310;
+      little water, 375;
+      Italian, considered collectively, 296, 297;
+      Neapolitan eruptions of and the history of civilization, 288;
+      subsidence of the earth after eruption of, 287, 291;
+      origin of, 263-274;
+      phenomena of, 263-267;
+      submarine, 301;
+      travelling of ejections from, 287, 288.
+
+
+    Waters,
+      crevice, 250;
+        of the earth, 250, 251;
+      cutting action of, 117, 192;
+      drift, from the poles, 151;
+      journey of, from the Arctic Circle to the tropics, 151, 152;
+      dynamic value of, 171;
+      expansion of, in rocks, 270;
+      geological work of, 168-206;
+      in air, 99;
+      of the clouds usually frozen, 207;
+      pure, no power for cutting rocks, 204;
+      rock, 250, 263;
+      sea, minerals in, 185;
+      store of the earth, 125;
+      system of, 125, 156;
+      tropical, 151;
+      velocity of the, under the equator, 150;
+      wearing away rocks, 178, 179;
+      underground, carrying mineral matter to the sea, 193;
+      chemical changes of, leading to changes in rock material, 262, 263;
+      effect of carbonic-acid gas on, 251;
+      operations of the, 126;
+      wearing away rocks, 178, 179;
+      work of, 250.
+
+    Waterfalls, 189-193;
+      cause of, 191;
+      the Yosemite, 192;
+      Niagara, 191, 192;
+      numerous in the torrent district of rivers, 192;
+      produced by dikes, 192;
+      valuable to manufactures, 192, 193.
+
+    Waterspouts, 115, 116;
+      atmospheric cause of, 116;
+      firing at, 116;
+      life of a, 116;
+      picturesqueness of, 116;
+      the water of fresh, 117.
+
+    Waves, 128, 129, 132, 145;
+      action of friction on, 135, 136;
+      break of the, 136;
+      endurance of sand against the, 145;
+      force of, 133, 136, 139;
+      marine, caused by earthquakes, 387;
+      of earthquakes, 389;
+      peculiar features in the action of, 137;
+      size of, 137, 138;
+      stroke of the, 144;
+      surf, 135;
+      tidal height of, 132;
+      undulations of, 132;
+      wind, 132;
+      wind influence of, on the sea, 134, 135;
+      wind-made, 128.
+
+    Ways and means of studying Nature, 9.
+
+    Weeds of the sea, 155.
+
+    Well, artesian, 258, 259.
+
+    Whirling of fluids and gas, 36, 37.
+
+    Whirlwinds in Sahara, 121.
+
+    Will-o'-the-wisp, 167.
+
+    Winds, 101, 110, 122, 317;
+      effect of sand, 122;
+      hurricane, 110;
+      illustration of how they are produced, 101;
+      in Martha's Vineyard, 120;
+      of the forests, work of the, 317;
+      of tornadoes, effect of, 113;
+      on the island of Jamaica, 119, 120;
+      regimen of the, 119;
+      variable falling away in the nighttime, 100;
+      trade, 102-105; 145, 146, 150;
+      action of, on ocean currents, 145:
+      affected by motion of the earth, 103;
+      belt, motion of the ocean in, 146;
+      flow and counter-flow of the, 150;
+      tide of the, 150;
+      uniform condition of the, 102;
+      waves, work of, 132, 134, 135.
+
+    Witchcraft, belief of, in the early ages, 21.
+
+
+    Zooelogy, rapid advance in, 14, 15.
+
+
+
+
+
+
+End of the Project Gutenberg EBook of Outlines of the Earth's History, by
+Nathaniel Southgate Shaler
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