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+The Project Gutenberg Etext of The Elements of Geology, by W. H. Norton
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+Title: The Elements of Geology
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+Author: William Harmon Norton
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+Release Date: July, 2003 [Etext #4204]
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+
+THE ELEMENTS OF GEOLOGY
+
+BY WILLIAM HARMON NORTON
+
+PROFESSOR OF GEOLOGY IN CORNELL COLLEGE
+
+PREFACE
+
+Geology is a science of such rapid growth that no apology is
+expected when from time to time a new text-book is added to those
+already in the field. The present work, however, is the outcome of
+the need of a text-book of very simple outline, in which causes
+and their consequences should be knit together as closely as
+possible,--a need long felt by the author in his teaching, and
+perhaps by other teachers also. The author has ventured,
+therefore, to depart from the common usage which subdivides
+geology into a number of departments,--dynamical, structural,
+physiographic, and historical,--and to treat in immediate
+connection with each geological process the land forms and the
+rock structures which it has produced.
+
+It is hoped that the facts of geology and the inferences drawn
+from them have been so presented as to afford an efficient
+discipline in inductive reasoning. Typical examples have been used
+to introduce many topics, and it has been the author's aim to give
+due proportion to both the wide generalizations of our science and
+to the concrete facts on which they rest.
+
+There have been added a number of practical exercises such as the
+author has used for several years in the class room. These are not
+made so numerous as to displace the problems which no doubt many
+teachers prefer to have their pupils solve impromptu during the
+recitation, but may, it is hoped, suggest their use.
+
+In historical geology a broad view is given of the development of
+the North American continent and the evolution of life upon the
+planet. Only the leading types of plants and animals are
+mentioned, and special attention is given to those which mark the
+lines of descent of forms now living.
+
+By omitting much technical detail of a mineralogical and
+paleontological nature, and by confining the field of view almost
+wholly to our own continent, space has been obtained to give to
+what are deemed for beginners the essentials of the science a
+fuller treatment than perhaps is common.
+
+It is assumed that field work will be introduced with the
+commencement of the study. The common rocks are therefore briefly
+described in the opening chapters. The drift also receives early
+mention, and teachers in the northern states who begin geology in
+the fall may prefer to take up the chapter on the Pleistocene
+immediately after the chapter on glaciers.
+
+Simple diagrams have been used freely, not only because they are
+often clearer than any verbal statement, but also because they
+readily lend themselves to reproduction on the blackboard by the
+pupil. The text will suggest others which the pupil may invent. It
+is hoped that the photographic views may also be used for
+exercises in the class room.
+
+The generous aid of many friends is recognized with special
+pleasure. To Professor W. M. Davis of Harvard University there is
+owing a large obligation for the broad conceptions and luminous
+statements of geologic facts and principles with which he has
+enriched the literature of our science, and for his stimulating
+influence in education. It is hoped that both in subject-matter
+and in method the book itself makes evident this debt. But besides
+a general obligation shared by geologists everywhere, and in
+varying degrees by perhaps all authors of recent American text-
+books in earth science, there is owing a debt direct and personal.
+The plan of the book, with its use of problems and treatment of
+land forms and rock structures in immediate connection with the
+processes which produce them, was submitted to Professor Davis,
+and, receiving his approval, was carried into effect, although
+without the sanction of precedent at the time. Professor Davis
+also kindly consented to read the manuscript throughout, and his
+many helpful criticisms and suggestions are acknowledged with
+sincere gratitude.
+
+Parts of the manuscript have been reviewed by Dr. Samuel Calvin
+and Dr. Frank M. Wilder of the State University of Iowa; Dr. S. W.
+Beyer of the Iowa College of Agriculture and Mechanic Arts; Dr. U.
+S. Grant of Northwestern University; Professor J. A. Udden of
+Augustana College, Illinois; Dr. C. H. Gordon of the New Mexico
+State School of Mines; Principal Maurice Ricker of the High
+School, Burlington, Iowa; and the following former students of the
+author who are engaged in the earth sciences: Dr. W. C. Alden of
+the United States Geological Survey and the University of Chicago;
+Mr. Joseph Sniffen, instructor in the Academy of the University of
+Chicago, Morgan Park; Professor Martin Iorns, Fort Worth
+University, Texas; Professor A. M. Jayne, Dakota University;
+Professor G. H. Bretnall, Monmouth College, Illinois; Professor
+Howard E. Simpson, Colby College, Maine; Mr. E. J. Cable,
+instructor in the Iowa State Normal College; Principal C. C. Gray
+of the High School, Fargo, North Dakota; and Mr. Charles Persons
+of the High School, Hannibal, Missouri. A large number of the
+diagrams of the book were drawn by Mr. W. W. White of the Art
+School of Cornell College. To all these friends, and to the many
+who have kindly supplied the illustrations of the text, whose
+names are mentioned in an appended list, the writer returns his
+heartfelt thanks.
+
+WILLIAM HARMON NORTON
+
+CORNELL COLLEGE, MOUNT VERNON, IOWA
+
+JULY, 1905
+
+
+
+
+
+INTRODUCTORY NOTE
+
+During the preparation of this book Professor Norton has
+frequently discussed its plan with me by correspondence, and we
+have considered together the matters of scope, arrangement, and
+presentation.
+
+As to scope, the needs of the young student and not of the expert
+have been our guide; the book is therefore a text-book, not a
+reference volume.
+
+In arrangement, the twofold division of the subject was chosen
+because of its simplicity and effectiveness. The principles of
+physical geology come first; the several chapters are arranged in
+what is believed to be a natural order, appropriate to the
+greatest part of our country, so that from a simple beginning a
+logical sequence of topics leads through the whole subject. The
+historical view of the science comes second, with many specific
+illustrations of the physical processes previously studied, but
+now set forth as part of the story of the earth, with its many
+changes of aspect and its succession of inhabitants. Special
+attention is here given to North America, and care is taken to
+avoid overloading with details.
+
+With respect to method of presentation, it must not be forgotten
+that the text-book is only one factor in good teaching, and that
+in geology, as in other sciences, the teacher, the laboratory, and
+the local field are other factors, each of which should play an
+appropriate part. The text suggests observational methods, but it
+cannot replace observation in field or laboratory; it offers
+certain exercises, but space cannot be taken to make it a
+laboratory manual as well as a book for study; it explains many
+problems, but its statements are necessarily more terse than the
+illustrative descriptions that a good and experienced teacher
+should supply. Frequent use is made of induction and inference in
+order that the student may come to see how reasonable a science is
+geology, and that he may avoid the too common error of thinking
+that the opinions of "authorities" are reached by a private road
+that is closed to him. The further extension of this method of
+presentation is urged upon the teacher, so that the young
+geologist may always learn the evidence that leads to a
+conclusion, and not only the conclusion itself.
+
+W. M. DAVIS
+
+HARVARD UNIVERSITY, CAMBRIDGE, MASS.
+
+JULY, 1905
+
+
+
+
+
+CONTENTS
+
+INTRODUCTION.--THE SCOPE AND AIM OF GEOLOGY
+
+PART I
+
+EXTERNAL GEOLOGICAL AGENCIES
+
+     I. THE WORK OF THE WEATHER
+    II. THE WORK OF GROUND WATER
+   III. RIVERS AND VALLEYS
+    IV. RIVER DEPOSITS
+     V. THE WORK OF GLACIERS
+    VI. THE WORK OF THE WIND
+   VII. THE SEA AND ITS SHORES
+  VIII. OFFSHORE AND DEEP-SEA DEPOSITS
+
+PART  II
+
+INTERNAL GEOLOGICAL AGENCIES
+
+    IX. MOVEMENTS OF THE EARTH'S CRUST
+     X. EARTHQUAKES
+    XI. VOLCANOES
+   XII. UNDERGROUND STRUCTURES OF IGNEOUS ORIGIN
+  XIII. METAMORPHISM AND MINERAL VEINS
+
+PART III
+
+HISTORICAL GEOLOGY
+
+   XIV. THE GEOLOGICAL RECORD
+    XV. THE PRE-CAMBRIAN SYSTEMS
+   XVI. THE CAMBRIAN
+  XVII. THE ORDOVICIAN AND SILURIAN
+ XVIII. THE DEVONIAN
+   XIX. THE CARBONIFEROUS
+    XX. THE MESOZOIC
+   XXI. THE TERTIARY
+  XXII. THE QUATERNARY
+ INDEX
+
+
+
+
+
+THE ELEMENTS OF GEOLOGY
+
+
+
+
+
+INTRODUCTION
+
+THE SCOPE AND AIM OF GEOLOGY
+
+
+Geology deals with the rocks of the earth's crust. It learns from
+their composition and structure how the rocks were made and how
+they have been modified. It ascertains how they have been brought
+to their present places and wrought to their various topographic
+forms, such as hills and valleys, plains and mountains. It studies
+the vestiges which the rocks preserve of ancient organisms which
+once inhabited our planet. Geology is the history of the earth and
+its inhabitants, as read in the rocks of the earth's crust.
+
+To obtain a general idea of the nature and method of our science
+before beginning its study in detail, we may visit some valley,
+such as that illustrated in the frontispiece, on whose sides are
+rocky ledges. Here the rocks lie in horizontal layers. Although
+only their edges are exposed, we may infer that these layers run
+into the upland on either side and underlie the entire district;
+they are part of the foundation of solid rock which everywhere is
+found beneath the loose materials of the surface.
+
+The ledges of the valley of our illustration are of sandstone.
+Looking closely at the rock we see that it is composed of myriads
+of grains of sand cemented together. These grains have been worn
+and rounded. They are sorted also, those of each layer being about
+of a size. By some means they have been brought hither from some
+more ancient source. Surely these grains have had a history before
+they here found a resting place,--a history which we are to learn
+to read.
+
+The successive layers of the rock suggest that they were built one
+after another from the bottom upward. We may be as sure that each
+layer was formed before those above it as that the bottom courses
+of stone in a wall were laid before the courses which rest upon
+them.
+
+We have no reason to believe that the lowest layers which we see
+here were the earliest ever formed. Indeed, some deep boring in
+the vicinity may prove that the ledges rest upon other layers of
+rock which extend downward for many hundreds of feet below the
+valley floor. Nor may we conclude that the highest layers here
+were the latest ever laid; for elsewhere we may find still later
+layers lying upon them.
+
+A short search may find in the rock relics of animals, such as the
+imprints of shells, which lived when it was deposited; and as
+these are of kinds whose nearest living relatives now have their
+home in the sea, we infer that it was on the flat sea floor that
+the sandstone was laid. Its present position hundreds of feet
+above sea level proves that it has since emerged to form part of
+the land; while the flatness of the beds shows that the movement
+was so uniform and gentle as not to break or strongly bend them
+from their original attitude.
+
+The surface of some of these layers is ripple-marked. Hence the
+sand must once have been as loose as that of shallow sea bottoms
+and sea beaches to-day, which is thrown into similar ripples by
+movements of the water. In some way the grains have since become
+cemented into firm rock.
+
+Note that the layers on one side of the valley agree with those on
+the other, each matching the one opposite at the same level. Once
+they were continuous across the valley. Where the valley now is
+was once a continuous upland built of horizontal layers; the
+layers now show their edges, or OUTCROP, on the valley sides
+because they have been cut by the valley trench.
+
+The rock of the ledges is crumbling away. At the foot of each step
+of rock lie fragments which have fallen. Thus the valley is slowly
+widening. It has been narrower in the past; it will be wider in
+the future.
+
+Through the valley runs a stream. The waters of rains which have
+fallen on the upper parts of the stream's basin are now on their
+way to the river and the sea. Rock fragments and grains of sand
+creeping down the valley slopes come within reach of the stream
+and are washed along by the running water. Here and there they
+lodge for a time in banks of sand and gravel, but sooner or later
+they are taken up again and carried on. The grains of sand which
+were brought from some ancient source to form these rocks are on
+their way to some new goal. As they are washed along the rocky bed
+of the stream they slowly rasp and wear it deeper. The valley will
+be deeper in the future; it has been less deep in the past.
+
+In this little valley we see slow changes now in progress. We find
+also in the composition, the structure, and the attitude of the
+rocks, and the land forms to which they have been sculptured, the
+record of a long succession of past changes involving the origin
+of sand grains and their gathering and deposit upon the bottom of
+some ancient sea, the cementation of their layers into solid rock,
+the uplift of the rocks to form a land surface, and, last of all,
+the carving of a valley in the upland. Everywhere, in the fields,
+along the river, among the mountains, by the seashore, and in the
+desert, we may discover slow changes now in progress and the
+record of similar changes in the past. Everywhere we may catch
+glimpses of a process of gradual change, which stretches backward
+into the past and forward into the future, by which the forms and
+structures of the face of the earth are continually built and
+continually destroyed. The science which deals with this long
+process is geology. Geology treats of the natural changes now
+taking place upon the earth and within it, the agencies which
+produce them, and the land forms and rock structures which result.
+It studies the changes of the present in order to be able to read
+the history of the earth's changes in the past.
+
+The various agencies which have fashioned the face of the earth
+may. be divided into two general classes. In Part I we shall
+consider those which work upon the earth from without, such as the
+weather, running water, glaciers, the wind, and the sea. In Part
+II we shall treat of those agencies whose sources are within the
+earth, and among whose manifestations are volcanoes and
+earthquakes and the various movements of the earth's crust. As we
+study each agency we shall notice not only how it does its work,
+but also the records which it leaves in the rock structures and
+the land forms which it produces. With this preparation we shall
+be able in Part III to read in the records of the rocks the
+history of our planet and the successive forms of life which have
+dwelt upon it.
+
+
+
+
+
+PART I
+
+EXTERNAL GEOLOGICAL AGENCIES
+
+CHAPTER I
+
+THE WORK OF THE WEATHER
+
+
+In our excursion to the valley with sandstone ledges we witnessed
+a process which is going forward in all lands. Everywhere the
+rocks are crumbling away; their fragments are creeping down
+hillsides to the stream ways and are carried by the streams to the
+sea, where they are rebuilt into rocky layers. When again the
+rocks are lifted to form land the process will begin anew; again
+they will crumble and creep down slopes and be washed by streams
+to the sea. Let us begin our study of this long cycle of change at
+the point where rocks disintegrate and decay under the action of
+the weather. In studying now a few outcrops and quarries we shall
+learn a little of some common rocks and how they weather away.
+
+STRATIFICATION AND JOINTING. At the sandstone ledges we saw that
+the rock was divided into parallel layers. The thicker layers are
+known as STRATA, and the thin leaves into which each stratum may
+sometimes be split are termed LAMINAE. To a greater or less degree
+these layers differ from each other in fineness of grain, showing
+that the material has been sorted. The planes which divide them
+are called BEDDING PLANES.
+
+Besides the bedding planes there are other division planes, which
+cut across the strata from top to bottom. These are found in all
+rocks and are known as joints. Two sets of joints,
+running at about right angles to each other, together with the
+bedding planes, divide the sandstone into quadrangular blocks.
+
+SANDSTONE. Examining a piece of sandstone we find it composed of
+grains quite like those of river sand or of sea beaches. Most of
+the grains are of a clear glassy mineral called quartz. These
+quartz grains are very hard and will scratch the steel of a knife
+blade. They are not affected by acid, and their broken surfaces
+are irregular like those of broken glass.
+
+The grains of sandstone are held together by some cement. This may
+be calcareous, consisting of soluble carbonate of lime. In brown
+sandstones the cement is commonly ferruginous,--hydrated iron
+oxide, or iron rust, forming the bond, somewhat as in the case of
+iron nails which have rusted together. The strongest and most
+lasting cement is siliceous, and sand rocks whose grains are
+closely cemented by silica, the chemical substance of which quartz
+is made, are known as quartzites.
+
+We are now prepared to understand how sandstone is affected by the
+action of the weather. On ledges where the rock is exposed to view
+its surface is more or less discolored and the grains are loose
+and may be rubbed off with the finger. On gentle slopes the rock
+is covered with a soil composed of sand, which evidently is
+crumbled sandstone, and dark carbonaceous matter derived from the
+decay of vegetation. Clearly it is by the dissolving of the cement
+that the rock thus breaks down to loose sand. A piece of sandstone
+with calcareous cement, or a bit of old mortar, which is really an
+artificial stone also made of sand cemented by lime, may be
+treated in a test tube with hydrochloric acid to illustrate the
+process.
+
+A LIMESTONE QUARRY. Here also we find the rock stratified and
+jointed (Fig. 2). On the quarry face the rock is distinctly seen
+to be altered for some distance from its upper surface. Below the
+altered zone the rock is sound and is quarried for building; but
+the altered upper layers are too soft and broken to be used for
+this purpose. If the limestone is laminated, the laminae here have
+split apart, although below they hold fast together. Near the
+surface the stone has become rotten and crumbles at the touch,
+while on the top it has completely broken down to a thin layer of
+limestone meal, on which rests a fine reddish clay.
+
+Limestone is made of minute grains of carbonate of lime all firmly
+held together by a calcareous cement. A piece of the stone placed
+in a test tube with hydrochloric acid dissolves with brisk
+effervescence, leaving the insoluble impurities, which were
+disseminated through it, at the bottom of the tube as a little
+clay.
+
+We can now understand the changes in the upper layers of the
+quarry. At the surface of the rock the limestone has completely
+dissolved, leaving the insoluble residue as a layer of reddish
+clay. Immediately below the clay the rock has disintegrated into
+meal where the cement between the limestone grains has been
+removed, while beneath this the laminae are split apart where the
+cement has been dissolved only along the planes of lamination
+where the stone is more porous. As these changes in the rock are
+greatest at the surface and diminish downward, we infer that they
+have been caused by agents working downward from the surface.
+
+At certain points these agencies have been more effective than
+elsewhere. The upper rock surface is pitted. Joints are widened as
+they approach the surface, and along these seams we may find that
+the rock is altered even down to the quarry floor.
+
+A SHALE PIT. Let us now visit some pit where shale--a laminated
+and somewhat hardened clay--is quarried for the manufacture of
+brick. The laminae of this fine-grained rock may be as thin as
+cardboard in places, and close joints may break the rock into
+small rhombic blocks. On the upper surface we note that the shale
+has weathered to a clayey soil in which all traces of structure
+have been destroyed. The clay and the upper layers of the shale
+beneath it are reddish or yellow, while in many cases the color of
+the unaltered rock beneath is blue.
+
+THE SEDIMENTARY ROCKS. The three kinds of layered rocks whose
+acquaintance we have made--sandstone, limestone, and shale--are
+the leading types of the great group of stratified, or
+sedimentary, rocks. This group includes all rocks made of
+sediments, their materials having settled either in water upon the
+bottoms of rivers, lakes, or seas, or on dry land, as in the case
+of deposits made by the wind and by glaciers. Sedimentary rocks
+are divided into the fragmental rocks--which are made of
+fragments, either coarse or fine--and the far less common rocks
+which are constituted of chemical precipitates.
+
+The sedimentary rocks are divided according to their composition
+into the following classes:
+
+1. The arenaceous, or quartz rocks, including beds of loose sand
+and gravel, sandstone, quartzite, and conglomerate (a rock made of
+cemented rounded gravel or pebbles).
+
+2. The calcareous, or lime rocks, including limestone and a soft
+white rock formed of calcareous powder known as chalk.
+
+3. The argillaceous, or clay rocks, including muds, clays, and
+shales. These three classes pass by mixture into one another. Thus
+there are limy and clayey sandstones, sandy and clayey limestones,
+and sandy and limy shales.
+
+GRANITE. This familiar rock may be studied as an example of the
+second great group of rocks,--the unstratified, or igneous rocks.
+These are not made of cemented sedimentary grains, but of
+interlocking crystals which have crystallized from a molten mass.
+Examining a piece of granite, the most conspicuous crystals which
+meet the eye are those of feldspar. They are commonly pink, white,
+or yellow, and break along smooth cleavage planes which reflect
+the light like tiny panes of glass. Mica may be recognized by its
+glittering plates, which split into thin elastic scales. A third
+mineral, harder than steel, breaking along irregular surfaces like
+broken glass, we identify as quartz.
+
+How granite alters under the action of the weather may be seen in
+outcrops where it forms the bed rock, or country rock, underlying
+the loose formations of the surface, and in many parts of the
+northern states where granite bowlders and pebbles more or less
+decayed may be found in a surface sheet of stony clay called the
+drift. Of the different minerals composing granite, quartz alone
+remains unaltered. Mica weathers to detached flakes which have
+lost their elasticity. The feldspar crystals have lost their
+luster and hardness, and even have decayed to clay. Where long-
+weathered granite forms the country rock, it often may be cut with
+spade or trowel for several feet from the surface, so rotten is
+the feldspar, and here the rock is seen to break down to a clayey
+soil containing grains of quartz and flakes of mica.
+
+These are a few simple illustrations of the surface changes which
+some of the common kinds of rocks undergo. The agencies by which
+these changes are brought about we will now take up under two
+divisions,--CHEMICAL AGENCIES producing rock decay and MECHANICAL
+AGENCIES producing rock disintegration.
+
+THE CHEMICAL WORK OF WATER
+
+As water falls on the earth in rain it has already absorbed from
+the air carbon dioxide (carbonic acid gas) and oxygen. As it sinks
+into the ground and becomes what is termed ground water, it takes
+into solution from the soil humus acids and carbon dioxide, both
+of which are constantly being generated there by the decay of
+organic matter. So both rain and ground water are charged with
+active chemical agents, by the help of which they corrode and rust
+and decompose all rocks to a greater or less degree. We notice now
+three of the chief chemical processes concerned in weathering,--
+solution, the formation of carbonates, and oxidation.
+
+SOLUTION. Limestone, although so little affected by pure water
+that five thousand gallons would be needed to dissolve a single
+pound, is easily dissolved in water charged with carbon dioxide.
+In limestone regions well water is therefore "hard." On boiling
+the water for some time the carbon dioxide gas is expelled, the
+whole of the lime carbonate can no longer be held in solution, and
+much of it is thrown down to form a crust or "scale" in the kettle
+or in the tubes of the steam boiler. All waters which flow over
+limestone rocks or soak through them are constantly engaged in
+dissolving them away, and in the course of time destroy beds of
+vast extent and great thickness.
+
+The upper surface of limestone rocks becomes deeply pitted, as we
+saw in the limestone quarry, and where the mantle of waste has
+been removed it may be found so intricately furrowed that it is
+difficult to traverse.
+
+Beds of rock salt buried among the strata are dissolved by seeping
+water, which issues in salt springs. Gypsum, a mineral composed of
+hydrated sulphate of lime, and so soft that it may be scratched
+with the finger nail, is readily taken up by water, giving to the
+water of wells and springs a peculiar hardness difficult to
+remove.
+
+The dissolving action of moisture may be noted on marble
+tombstones of some age, marble being a limestone altered by heat
+and pressure and composed of crystalline grains. By assuming that
+the date on each monument marks the year of its erection, one may
+estimate how many years on the average it has taken for weathering
+to loosen fine grains on the polished surface, so that they may be
+rubbed off with the finger, to destroy the polish, to round the
+sharp edges of tool marks in the lettering, and at last to open
+cracks and seams and break down the stone. We may notice also
+whether the gravestones weather more rapidly on the sunny or the
+shady side, and on the sides or on the top.
+
+The weathered surface of granular limestone containing shells
+shows them standing in relief. As the shells are made of
+crystalline carbonate of lime, we may infer whether the carbonate
+of lime is less soluble in its granular or in its crystalline
+condition.
+
+THE FORMATION OF CARBONATES. In attacking minerals water does more
+than merely take them into solution. It decomposes them, forming
+new chemical compounds of which the carbonates are among the most
+important. Thus feldspar consists of the insoluble silicate of
+alumina, together with certain alkaline silicates which are broken
+up by the action of water containing carbon dioxide, forming
+alkaline carbonates. These carbonates are freely soluble and
+contribute potash and soda to soils and river waters. By the
+removal of the soluble ingredients of feldspar there is left the
+silicate of alumina, united with water or hydrated, in the
+condition of a fine plastic clay which, when white and pure, is
+known as KAOLIN and is used in the manufacture of porcelain.
+Feldspathic rocks which contain no iron compounds thus weather to
+whitish crusts, and even apparently sound crystals of feldspar,
+when ground to thin slices and placed under the microscope, may be
+seen to be milky in color throughout because an internal change to
+kaolin has begun.
+
+OXIDATION. Rocks containing compounds of iron weather to reddish
+crusts, and the seams of these rocks are often lined with rusty
+films. Oxygen and water have here united with the iron, forming
+hydrated iron oxide. The effects of oxidation may be seen in the
+alteration of many kinds of rocks and in red and yellow colors of
+soils and subsoils.
+
+Pyrite is a very hard mineral of a pale brass color, found in
+scattered crystals in many rocks, and is composed of iron and
+sulphur (iron sulphide). Under the attack of the weather it takes
+up oxygen, forming iron sulphate (green vitriol), a soluble
+compound, and insoluble hydrated iron oxide, which as a mineral is
+known as limonite. Several large masses of iron sulphide were
+placed some years ago on the lawn in front of the National Museum
+at Washington. The mineral changed so rapidly to green vitriol
+that enough of this poisonous compound was washed into the ground
+to kill the roots of the surrounding grass.
+
+AGENTS OF MECHANICAL DISINTEGRATION
+
+HEAT AND COLD. Rocks exposed to the direct rays of the sun become
+strongly heated by day and expand. After sunset they rapidly cool
+and contract. When the difference in temperature between day and
+night is considerable, the repeated strains of sudden expansion
+and contraction at last become greater than the rocks can bear,
+and they break, for the same reason that a glass cracks when
+plunged into boiling water (Fig. 5).
+
+Rocks are poor conductors of heat, and hence their surfaces may
+become painfully hot under the full blaze of the sun, while the
+interior remains comparatively cool. By day the surface shell
+expands and tends to break loose from the mass of the stone. In
+cooling in the evening the surface shell suddenly contracts on the
+unyielding interior and in time is forced off in scales.
+
+Many rocks, such as granite, are made up of grains of various
+minerals which differ in color and in their capacity to absorb
+heat, and which therefore contract and expand in different ratios.
+In heating and cooling these grains crowd against their neighbors
+and tear loose from them, so that finally the rock disintegrates
+into sand.
+
+The conditions for the destructive action of heat and cold are
+most fully met in arid regions when vegetation is wanting for lack
+of sufficient rain. The soil not being held together by the roots
+of plants is blown away over large areas, leaving the rocks bare
+to the blazing sun in a cloudless sky. The air is dry, and the
+heat received by the earth by day is therefore rapidly radiated at
+night into space. There is a sharp and sudden fall of temperature
+after sunset, and the rocks, strongly heated by day, are now
+chilled perhaps even to the freezing point.
+
+In the Sahara the thermometer has been known to fall 131 degrees
+F. within a few hours. In the light air of the Pamir plateau in
+central Asia a rise of 90 degrees F. has been recorded from seven
+o'clock in the morning to one o'clock in the afternoon. On the
+mountains of southwestern Texas there are frequently heard
+crackling noises as the rocks of that arid region throw off scales
+from a fraction of an inch to four inches in thickness, and loud
+reports are made as huge bowlders split apart. Desert pebbles
+weakened by long exposure to heat and cold have been shivered to
+fine sharp-pointed fragments on being placed in sand heated to 180
+degrees F. Beds half a foot thick, forming the floor of limestone
+quarries in Wisconsin, have been known to buckle and arch and
+break to fragments under the heat of the summer sun.
+
+FROST. By this term is meant the freezing and thawing of water
+contained in the pores and crevices of rocks. All rocks are more
+or less porous and all contain more or less water in their pores.
+Workers in stone call this "quarry water," and speak of a stone as
+"green" before the quarry water has dried out. Water also seeps
+along joints and bedding planes and gathers in all seams and
+crevices. Water expands in freezing, ten cubic inches of water
+freezing to about eleven cubic inches of ice. As water freezes in
+the rifts and pores of rocks it expands with the irresistible
+force illustrated in the freezing and breaking of water pipes in
+winter. The first rift in the rock, perhaps too narrow to be seen,
+is widened little by little by the wedges of successive frosts,
+and finally the rock is broken into detached blocks, and these
+into angular chip-stone by the same process.
+
+It is on mountain tops and in high latitudes that the effects of
+frost are most plainly seen. "Every summit" says Whymper, "amongst
+the rock summits upon which I have stood has been nothing but a
+piled-up heap of fragments" (Fig. 7). In Iceland, in Spitsbergen,
+in Kamchatka, and in other frigid lands large areas are thickly
+strewn with sharp-edged fragments into which the rock has been
+shattered by frost.
+
+ORGANIC AGENTS
+
+We must reckon the roots of plants and trees among the agents
+which break rocks into pieces. The tiny rootlet in its search for
+food and moisture inserts itself into some minute rift, and as it
+grows slowly wedges the rock apart. Moreover, the acids of the
+root corrode the rocks with which they are in contact. One may
+sometimes find in the soil a block of limestone wrapped in a mesh
+of roots, each of which lies in a little furrow where it has eaten
+into the stone.
+
+Rootless plants called lichens often cover and corrode rocks as
+yet bare of soil; but where lichens are destroying the rock less
+rapidly than does the weather, they serve in a way as a
+protection.
+
+CONDITIONS FAVORING DISINTEGRATION AND DECAY. The
+disintegration of rocks under frost and temperature changes
+goes on most rapidly in cold and arid climates, and where
+vegetation is scant or absent. On the contrary, the decay of rocks
+under the chemical action of water is favored by a warm, moist
+climate and abundant vegetation. Frost and heat and cold can only
+act within the few feet from the surface to which the necessary
+temperature changes are limited, while water penetrates and alters
+the rocks to great depths.
+
+The pupil may explain.
+
+In what ways the presence of joints and bedding planes assists in
+the breaking up and decay of rocks under the action of the
+weather.
+
+Why it is a good rule of stone masons never to lay stones on edge,
+but always on their natural bedding planes.
+
+Why stones fresh from the quarry sometimes go to pieces in early
+winter, when stones which have been quarried for some months
+remain uninjured.
+
+Why quarrymen in the northern states often keep their quarry
+floors flooded during winter.
+
+Why laminated limestone should not be used for curbstone.
+
+Why rocks composed of layers differing in fineness of grain and in
+ratios of expansion do not make good building stone.
+
+Fine-grained rocks with pores so small that capillary attraction
+keeps the water which they contain from readily draining away are
+more apt to hold their pores ten elevenths full of water than are
+rocks whose pores are larger. Which, therefore, are more likely to
+be injured by frost?
+
+Which is subject to greater temperature changes, a dark rock or
+one of a light color? the north side or the south side of a
+valley?
+
+THE MANTLE OF ROCK WASTE
+
+We have seen that rocks are everywhere slowly wasting away. They
+are broken in pieces by frost, by tree roots, and by heat and
+cold. They dissolve and decompose under the chemical action of
+water and the various corrosive substances which it contains,
+leaving their insoluble residues as residual clays and sands upon
+the surface. As a result there is everywhere forming a mantle of
+rock waste which covers the land. It is well to imagine how the
+country would appear were this mantle with its soil and vegetation
+all scraped away or had it never been formed. The surface of the
+land would then be everywhere of bare rock as unbroken as a quarry
+floor.
+
+THE THICKNESS OF THE MANTLE. In any locality the thickness of the
+mantle of rock waste depends as much on the rate at which it is
+constantly being removed as on the rate at which it is forming. On
+the face of cliffs it is absent, for here waste is removed as fast
+as it is made. Where waste is carried away more slowly than it is
+produced, it accumulates in time to great depth.
+
+The granite of Pikes Peak is disintegrated to a depth of twenty
+feet. In the city of Washington granite rock is so softened to a
+depth of eighty feet that it can be removed with pick and shovel.
+About Atlanta, Georgia, the rocks are completely rotted for one
+hundred feet from the surface, while the beginnings of decay may
+be noticed at thrice that depth. In places in southern Brazil the
+rock is decomposed to a depth of four hundred feet.
+
+In southwestern Wisconsin a reddish residual clay has an average
+depth of thirteen feet on broad uplands, where it has been removed
+to the least extent. The country rock on which it rests is a
+limestone with about ten per cent of insoluble impurities. At
+least how thick, then, was that portion of the limestone which has
+rotted down to the clay?
+
+DISTINGUISHING CHARACTERISTICS OF RESIDUAL WASTE. We must learn to
+distinguish waste formed in place by the action of the weather
+from the products of other geological agencies. Residual waste is
+unstratified. It contains no substances which have not been
+derived from the weathering of the parent rock. There is a gradual
+transition from residual waste into the unweathered rock beneath.
+Waste resting on sound rock evidently has been shifted and was not
+formed in place.
+
+In certain regions of southern Missouri the land is covered with a
+layer of broken flints and red clay, while the country rock is
+limestone. The limestone contains nodules of flint, and we may
+infer that it has been by the decay and removal of thick masses of
+limestone that the residual layer of clay and flints has been left
+upon the surface. Flint is a form of quartz, dull-lustered,
+usually gray or blackish in color, and opaque except on thinnest
+edges, where it is translucent.
+
+Over much of the northern states there is spread an unstratified
+stony clay called the drift. It often rests on sound rocks. It
+contains grains of sand, pebbles, and bowlders composed of many
+different minerals and rocks that the country rock cannot furnish.
+Hence the drift cannot have been formed by the decay of the rock
+of the region. A shale or limestone, for example, cannot waste to
+a clay containing granite pebbles. The origin of the drift will be
+explained in subsequent chapters.
+
+The differences in rocks are due more to their soluble than to
+their insoluble constituents. The latter are few in number and are
+much the same in rocks of widely different nature, being chiefly
+quartz, silicate of alumina, and iron oxide. By the removal of
+their soluble parts very many and widely different rocks rot down
+to a residual clay gritty with particles of quartz and colored red
+or yellow with iron oxide.
+
+In a broad way the changes which rocks undergo in weathering are
+an adaptation to the environment in which they find themselves at
+the earth's surface,--an environment different from that in which
+they were formed under sea or under ground. In open air, where
+they are attacked by various destructive agents, few of the rock-
+making minerals are stable compounds except quartz, the iron
+oxides, and the silicate of alumina; and so it is to one or more
+of these comparatively insoluble substances that most rocks are
+reduced by long decay.
+
+Which produces a mantle of finer waste, frost or chemical decay?
+which a thicker mantle? In what respects would you expect that the
+mantle of waste would differ in warm humid lands like India, in
+frozen countries like Alaska, and in deserts such as the Sahara?
+
+THE SOIL. The same agencies which produce the mantle of waste are
+continually at work upon it, breaking it up into finer and finer
+particles and causing its more complete decay. Thus on the
+surface, where the waste has weathered longest, it is gradually
+made fine enough to support the growth of plants, and is then
+known as soil. The coarser waste beneath is sometimes spoken of as
+subsoil. Soil usually contains more or less dark, carbonaceous,
+decaying organic matter, called humus, and is then often termed
+the humus layer. Soil forms not only on waste produced in place
+from the rock beneath, but also on materials which have been
+transported, such as sheets of glacial drift and river deposits.
+Until rocks are reduced to residual clays the work of the weather
+is more rapid and effective on the fragments of the mantle of
+waste than on the rocks from which waste is being formed. Why?
+
+Any fresh excavation of cellar or cistern, or cut for road or
+railway, will show the characteristics of the humus layer. It may
+form only a gray film on the surface, or we may find it a layer a
+foot or more thick, dark, or even black, above, and growing
+gradually lighter in color as it passes by insensible gradations
+into the subsoil. In some way the decaying vegetable matter
+continually forming on the surface has become mingled with the
+material beneath it.
+
+HOW HUMUS AND THE SUBSOIL ARE MINGLED. The mingling of humus and
+the subsoil is brought about by several means. The roots of plants
+penetrate the waste, and when they die leave their decaying
+substance to fertilize it. Leaves and stems falling on the surface
+are turned under by several agents. Earthworms and other animals
+whose home is in the waste drag them into their burrows either for
+food or to line their nests. Trees overthrown by the wind, roots
+and all, turn over the soil and subsoil and mingle them together.
+Bacteria also work in the waste and contribute to its enrichment.
+The animals living in the mantle do much in other ways toward the
+making of soil. They bring the coarser fragments from beneath to
+the surface, where the waste weathers more rapidly. Their burrows
+allow air and water to penetrate the waste more freely and to
+affect it to greater depths.
+
+ANTS. In the tropics the mantle of waste is worked over chiefly by
+ants. They excavate underground galleries and chambers, extending
+sometimes as much as fourteen feet below the surface, and build
+mounds which may reach as high above it. In some parts of Paraguay
+and southern Brazil these mounds, like gigantic potato hills,
+cover tracts of considerable area.
+
+In search for its food--the dead wood of trees--the so-called
+white ant constructs runways of earth about the size of gas pipes,
+reaching from the base of the tree to the topmost branches. On the
+plateaus of central Africa explorers have walked for miles through
+forests every tree of which was plastered with these galleries of
+mud. Each grain of earth used in their construction is moistened
+and cemented by slime as it is laid in place by the ant, and is
+thus acted on by organic chemical agents. Sooner or later these
+galleries are beaten down by heavy rains, and their fertilizing
+substances are scattered widely by the winds.
+
+EARTHWORMS. In temperate regions the waste is worked over largely
+by earthworms. In making their burrows worms swallow earth in
+order to extract from it any nutritive organic matter which it may
+contain. They treat it with their digestive acids, grind it in
+their stony gizzards, and void it in castings on the surface of
+the ground. It was estimated by Darwin that in many parts of
+England each year, on every acre, more than ten tons of earth pass
+through the bodies of earthworms and are brought to the surface,
+and that every few years the entire soil layer is thus worked over
+by them.
+
+In all these ways the waste is made fine and stirred and enriched.
+Grain by grain the subsoil with its fresh mineral ingredients is
+brought to the surface, and the rich organic matter which plants
+and animals have taken from the atmosphere is plowed under. Thus
+Nature plows and harrows on "the great world's farm" to make ready
+and ever to renew a soil fit for the endless succession of her
+crops.
+
+The world processes by which rocks are continually wasting away
+are thus indispensable to the life of plants and animals. The
+organic world is built on the ruins of the inorganic, and because
+the solid rocks have been broken down into soil men are able to
+live upon the earth.
+
+SOLAR ENERGY. The source of the energy which accomplishes all this
+necessary work is the sun. It is the radiant energy of the sun
+which causes the disintegration of rocks, which lifts vapor into
+the atmosphere to fall as rain, which gives life to plants and
+animals. Considering the earth in a broad way, we may view it as a
+globe of solid rock,--the lithosphere,--surrounded by two mobile
+envelopes: the envelope of air,--THE ATMOSPHERE, and the envelope
+of water,--THE HYDROSPHERE. Under the action of solar energy these
+envelopes are in constant motion. Water from the hydrosphere is
+continually rising in vapor into the atmosphere, the air of the
+atmosphere penetrates the hydrosphere,--for its gases are
+dissolved in all waters,--and both air and water enter and work
+upon the solid earth. By their action upon the lithosphere they
+have produced a third envelope,--the mantle of rock waste.
+
+This envelope also is in movement, not indeed as a whole, but
+particle by particle. The causes which set its particles in
+motion, and the different forms which the mantle comes to assume,
+we will now proceed to study.
+
+MOVEMENTS OF THE MANTLE OF ROCK WASTE
+
+At the sandstone ledges which we first visited we saw not only
+that the rocks were crumbling away, but also that grains and
+fragments of them were creeping down the slopes of the valley to
+the stream and were carried by it onward toward the sea. This
+process is going on everywhere. Slowly it may be, and with many
+interruptions, but surely, the waste of the land moves downward to
+the sea. We may divide its course into two parts,--the path to the
+stream, which we will now consider, and its carriage onward by the
+stream, which we will defer to a later chapter.
+
+GRAVITY. The chief agent concerned in the movement of waste is
+gravity. Each particle of waste feels the unceasing downward pull
+of the earth's mass and follows it when free to do so. All
+agencies which produce waste tend to set its particles free and in
+motion, and therefore cooperate with gravity. On cliffs, rocks
+fall when wedged off by frost or by roots of trees, and when
+detached by any other agency. On slopes of waste, water freezes in
+chinks between stones, and in pores between particles of soil, and
+wedges them apart. Animals and plants stir the waste, heat expands
+it, cold contracts it, the strokes of the raindrops drive loose
+particles down the slope and the wind lifts and lets them fall. Of
+all these movements, gravity assists those which are downhill and
+retards those which are uphill. On the whole, therefore, the
+downhill movements prevail, and the mantle of waste, block by
+block and grain by grain, creeps along the downhill path.
+
+A slab of sandstone laid on another of the same kind at an angle
+of 17 degrees and left in the open air was found to creep down the
+slope at the rate of a little more than a millimeter a month.
+Explain why it did so.
+
+RAIN. The most efficient agent in the carriage of waste to the
+streams is the rain. It moves particles of soil by the force of
+the blows of the falling drops, and washes them down all slopes to
+within reach of permanent streams. On surfaces unprotected by
+vegetation, as on plowed fields and in arid regions, the rain
+wears furrows and gullies both in the mantle of waste and in
+exposures of unaltered rock (Fig. 17).
+
+At the foot of a hill we may find that the soil has accumulated by
+creep and wash to the depth of several feet; while where the
+hillside is steepest the soil may be exceedingly thin, or quite
+absent, because removed about as fast as formed. Against the walls
+of an abbey built on a slope in Wales seven hundred years ago, the
+creeping waste has gathered on the uphill side to a depth of seven
+feet. The slow-flowing sheet of waste is often dammed by fences
+and walls, whose uphill side gathers waste in a few years so as to
+show a distinctly higher surface than the downhill side,
+especially in plowed fields where the movement is least checked by
+vegetation.
+
+TALUS. At the foot of cliffs there is usually to be found a slope
+of rock fragments which clearly have fallen from above. Such a
+heap of waste is known as talus. The amount of talus in any place
+depends both on the rate of its formation and the rate of its
+removal. Talus forms rapidly in climates where mechanical
+disintegration is most effective, where rocks are readily broken
+into blocks because closely jointed and thinly bedded rather than
+massive, and where they are firm enough to be detached in
+fragments of some size instead of in fine grains. Talus is removed
+slowly where it decays slowly, either because of the climate or
+the resistance of the rock. It may be rapidly removed by a stream
+flowing along its base.
+
+In a moist climate a soluble rock, such as massive limestone, may
+form talus little if any faster than the talus weathers away. A
+loose-textured sandstone breaks down into incoherent sand grains,
+which in dry climates, where unprotected by vegetation, may be
+blown away as fast as they fall, leaving the cliff bare to the
+base. Cliffs of such slow-decaying rocks as quartzite and granite
+when closely jointed accumulate talus in large amounts.
+
+Talus slopes may be so steep as to reach THE ANGLE OF REPOSE, i.e.
+the steepest angle at which the material will lie. This angle
+varies with different materials, being greater with coarse and
+angular fragments than with fine rounded grains. Sooner or later a
+talus reaches that equilibrium where the amount removed from its
+surface just equals that supplied from the cliff above. As the
+talus is removed and weathers away its slope retreats together
+with the retreat of the cliff, as seen in Figure 9.
+
+GRADED SLOPES. Where rocks weather faster than their waste is
+carried away, the waste comes at last to cover all rocky ledges.
+On the steeper slopes it is coarser and in more rapid movement
+than on slopes more gentle, but mountain sides and hills and
+plains alike come to be mantled with sheets of waste which
+everywhere is creeping toward the streams. Such unbroken slopes,
+worn or built to the least inclination at which the waste supplied
+by weathering can be urged onward, are known as GRADED SLOPES.
+
+Of far less importance than the silent, gradual creep of waste,
+which is going on at all times everywhere about us, are the
+startling local and spasmodic movements which we are now to
+describe.
+
+AVALANCHES. On steep mountain sides the accumulated snows of
+winter often slip and slide in avalanches to the valleys below.
+These rushing torrents of snow sweep their tracks clean of waste
+and are one of Nature's normal methods of moving it along the
+downhill path.
+
+LANDSLIDES. Another common and abrupt method of delivering waste
+to streams is by slips of the waste mantle in large masses. After
+long rains and after winter frosts the cohesion between the waste
+and the sound rock beneath is loosened by seeping water
+underground. The waste slips on the rock surface thus lubricated
+and plunges down the mountain side in a swift roaring torrent of
+mud and stones.
+
+We may conveniently mention here a second type of landslide, where
+masses of solid rock as well as the mantle of waste are involved
+in the sudden movement. Such slips occur when valleys have been
+rapidly deepened by streams or glaciers and their sides have not
+yet been graded. A favorable condition is where the strata dip
+(i.e. incline downwards) towards the valley (Fig. 11), or are
+broken by joint planes dipping in the same direction. The upper
+layers, including perhaps the entire mountain side, have been cut
+across by the valley trench and are left supported only on the
+inclined surface of the underlying rocks. Water may percolate
+underground along this surface and loosen the cohesion between the
+upper and the underlying strata by converting the upper surface of
+a shale to soft wet clay, by dissolving layers of a limestone, or
+by removing the cement of a sandstone and converting it into loose
+sand. When the inclined surface is thus lubricated the overlying
+masses may be launched into the valley below. The solid rocks are
+broken and crushed in sliding and converted into waste consisting,
+like that of talus, of angular unsorted fragments, blocks of all
+sizes being mingled pellmell with rock meal and dust. The
+principal effects of landslides may be gathered from the following
+examples.
+
+At Gohna, India, in 1893, the face of a spur four thousand feet
+high, of the lower ranges of the Himalayas, slipped into the gorge
+of the headwaters of the Ganges River in successive rock falls
+which lasted for three days. Blocks of stone were projected for a
+mile, and clouds of limestone dust were spread over the
+surrounding country. The debris formed a dam one thousand feet
+high, extending for two miles along the valley. A lake gathered
+behind this barrier, gradually rising until it overtopped it in a
+little less than a year. The upper portion of the dam then broke,
+and a terrific rush of water swept down the valley in a wave
+which, twenty miles away, rose one hundred and sixty feet in
+height. A narrow lake is still held by the strong base of the dam.
+
+In 1896, after forty days of incessant rain, a cliff of sandstone
+slipped into the Yangtse River in China, reducing the width of the
+channel to eighty yards and causing formidable rapids.
+
+At Flims, in Switzerland, a prehistoric landslip flung a dam
+eighteen hundred feet high across the headwaters of the Rhine. If
+spread evenly over a surface of twenty-eight square miles, the
+material would cover it to a depth of six hundred and sixty feet.
+The barrier is not yet entirely cut away, and several lakes are
+held in shallow basins on its hummocky surface.
+
+A slide from the precipitous river front of the citadel hill of
+Quebec, in 1889, dashed across Champlain Street, wrecking a number
+of houses and causing the death of forty-five persons. The strata
+here are composed of steeply dipping slate.
+
+In lofty mountain ranges there may not be a single valley without
+its traces of landslides, so common there is this method of the
+movement of waste, and of building to grade over-steepened slopes.
+
+ROCK SCULPTURE BY WEATHERING
+
+We are now to consider a few of the forms into which rock masses
+are carved by the weather.
+
+BOWLDERS OF WEATHERING. In many quarries and outcrops we may see
+that the blocks into which one or more of the uppermost layers
+have been broken along their joints and bedding planes are no
+longer angular, as are those of the layers below. The edges and
+corners of these blocks have been worn away by the weather. Such
+rounded cores, known as bowlders of weathering, are often left to
+strew the surface.
+
+DIFFERENTIAL WEATHERING. This term covers all cases in which a
+rock mass weathers differently in different portions. Any weaker
+spots or layers are etched out on the surface, leaving the more
+resistant in relief. Thus massive limestones become pitted where
+the weather drills out the weaker portions. In these pits, when
+once they are formed, moisture gathers, a little soil collects,
+vegetation takes root, and thus they are further enlarged until
+the limestone may be deeply honeycombed.
+
+On the sides of canyons, and elsewhere where the edges of strata
+are exposed, the harder layers project as cliffs, while the softer
+weather back to slopes covered with the talus of the harder layers
+above them. It is convenient to call the former cliff makers and
+the latter slope makers.
+
+Differential weathering plays a large part in the sculpture of the
+land. Areas of weak rock are wasted to plains, while areas of hard
+rock adjacent are still left as hills and mountain ridges, as in
+the valleys and mountains of eastern Pennsylvania. But in such
+instances the lowering of the surface of the weaker rock is also
+due to the wear of streams, and especially to the removal by them
+from the land of the waste which covers and protects the rocks
+beneath.
+
+Rocks owe their weakness to several different causes. Some, such
+as beds of loose sand, are soft and easily worn by rains; some, as
+limestone and gypsum for example, are soluble. Even hard insoluble
+rocks are weak under the attack of the weather when they are
+closely divided by joints and bedding planes and are thus readily
+broken up into blocks by mechanical agencies.
+
+OUTLIERS AND MONUMENTS. As cliffs retreat under the attack of the
+weather, portions are left behind where the rock is more resistant
+or where the attack for any reason is less severe. Such remnant
+masses, if large, are known as outliers. When
+
+Note the rain furrows on the slope at the foot of the monuments.
+In the foreground are seen fragments of petrified trunks of trees,
+composed of silica and extremely resistant to the weather. On the
+removal of the rock layers in which these fragments were imbedded
+they are left to strew the surface in the same way as are the
+residual flints of southern Missouri. flat-topped, because of the
+protection of a resistant horizontal capping layer, they are
+termed mesas,--a term applied also to the flat-topped portions of
+dissected plateaus (Fig. 129). Retreating cliffs may fall back a
+number of miles behind their outliers before the latter are
+finally consumed.
+
+Monuments are smaller masses and may be but partially detached
+from the cliff face. In the breaking down of sheets of horizontal
+strata, outliers grow smaller and smaller and are reduced to
+massive rectangular monuments resembling castles (Fig. 17). The
+rock castle falls into ruin, leaving here and there an isolated
+tower; the tower crumbles to a lonely pillar, soon to be
+overthrown. The various and often picturesque shapes of monuments
+depend on the kind of rock, the attitude of the strata, and the
+agent by which they are chiefly carved. Thus pillars may have a
+capital formed of a resistant stratum. Monuments may be undercut
+and come to rest on narrow pedestals, wherever they weather more
+rapidly near the ground, either because of the greater moisture
+there, or--in arid climates--because worn at their base by
+drifting sands.
+
+Stony clays disintegrating under the rain often contain bowlders
+which protect the softer material beneath from the vertical blows
+of raindrops, and thus come to stand on pedestals of some height.
+One may sometimes see on the ground beneath dripping eaves pebbles
+left in the same way, protecting tiny pedestals of sand.
+
+MOUNTAIN PEAKS AND RIDGES. Most mountains have been carved out of
+great broadly uplifted folds and blocks of the earth's crust.
+Running water and glacier ice have cut these folds and blocks into
+masses divided by deep valleys; but it is by the weather, for the
+most part, that the masses thus separated have been sculptured to
+the present forms of the individual peaks and ridges.
+
+Frost and heat and cold sculpture high mountains to sharp,
+tusklike peaks and ragged, serrate crests, where their waste is
+readily removed.
+
+The Matterhorn of the Alps is a famous example of a mountain peak
+whose carving by the frost and other agents is in active progress.
+On its face "scarcely a rock anywhere is firmly attached," and the
+fall of loosened stones is incessant. Mountain climbers who have
+camped at its base tell how huge rocks from time to time come
+leaping down its precipices, followed by trains of dislodged
+smaller fragments and rock dust; and how at night one may trace
+the course of the bowlders by the sparks which they strike from
+the mountain walls. Mount Assiniboine, Canada (Fig. 20), resembles
+the Matterhorn in form and has been carved by the same agencies.
+
+"The Needles" of Arizona are examples of sharp mountain peaks in a
+warm arid region sculptured chiefly by temperature changes.
+
+Chemical decay, especially when carried on beneath a cover of
+waste and vegetation, favors the production of rounded knobs and
+dome-shaped mountains.
+
+THE WEATHER CURVE. We have seen that weathering reduces the
+angular block quarried by the frost to a rounded bowlder by
+chipping off its corners and smoothing away its edges. In much the
+same way weathering at last reduces to rounded hills the earth
+blocks cut by streams or formed in any other way. High mountains
+may at first be sculptured by the weather to savage peaks (Fig.
+181), but toward the end of their life history they wear down to
+rounded hills (Fig. 182). The weather curve, which may be seen on
+the summits of low hills (Fig. 21), is convex upward.
+
+In Figure 22, representing a cubic block of stone whose faces are
+a yard square, how many square feet of surface are exposed to the
+weather by a cubic foot at a corner a; by one situated in the
+middle of an edge b; by one in the center of a side c? How much
+faster will a and b weather than c, and what will be the effect on
+the shape of the block?
+
+THE COOPERATION OF VARIOUS AGENCIES IN ROCK SCULPTURE. For the
+sake of clearness it is necessary to describe the work of each
+geological agent separately. We must not forget, however, that in
+Nature no agent works independently and alone; that every result
+is the outcome of a long chain of causes. Thus, in order that the
+mountain peak may be carved by the agents of disintegration, the
+waste must be rapidly removed,--a work done by many agents,
+including some which we are yet to study; and in order that the
+waste may be removed as fast as formed, the region must first have
+been raised well above the level of the sea, so that the agents of
+transportation could do their work effectively. The sculpture of
+the rocks is accomplished only by the cooperation of many forces.
+
+The constant removal of waste from the surface by creep and wash
+and carriage by streams is of the highest importance, because it
+allows the destruction of the land by means of weathering to go on
+as long as any land remains above sea level. If waste were not
+removed, it would grow to be so thick as to protect the rock
+beneath from further weathering, and the processes of destruction
+which we have studied would be brought to an end. The very
+presence of the mantle of waste over the land proves that on the
+whole rocks weather more rapidly than their waste is removed. The
+destruction of the land is going on as fast as the waste can be
+carried away.
+
+We have now learned to see in the mantle of waste the record of
+the destructive action of the agencies of weathering on the rocks
+of the land surface. Similar records we shall find buried deeply
+among the rocks of the crust in old soils and in rocks pitted and
+decayed, telling of old land surfaces long wasted by the weather.
+Ever since the dry land appeared these agencies have been as now
+quietly and unceasingly at work upon it, and have ever been the
+chief means of the destruction of its rocks. The vast bulk of the
+stratified rocks of the earth's crust is made up almost wholly of
+the waste thus worn from ancient lands.
+
+In studying the various geological agencies we must remember the
+almost inconceivable times in which they work. The slowest process
+when multiplied by the immense time in which it is carried on
+produces great results. The geologist looks upon the land forms of
+the earth's surface as monuments which record the slow action of
+weathering and other agents during the ages of the past. The
+mountain peak, the rounded hill, the wide plain which lies where
+hills and mountains once stood, tell clearly of the great results
+which slow processes will reach when given long time in which to
+do their work. We should accustom ourselves also to think of the
+results which weathering will sooner or later bring to pass. The
+tombstone and the bowlder of the field, which each year lose from
+their surfaces a few crystalline grains, must in time be wholly
+destroyed. The hill whose rocks are slowly rotting underneath a
+cover of waste must become lower and lower as the centuries and
+millenniums come and go, and will finally disappear. Even the
+mountains are crumbling away continually, and therefore are but
+fleeting features of the landscape.
+
+
+
+
+
+CHAPTER II
+
+THE WORK OF GROUND WATER
+
+
+LAND WATERS. We have seen how large is the part that water plays
+at and near the surface of the land in the processes of weathering
+and in the slow movement of waste down all slopes to the stream
+ways. We now take up the work of water as it descends beneath the
+ground,--a corrosive agent still, and carrying in solution as its
+load the invisible waste of rocks derived from their soluble
+parts.
+
+Land waters have their immediate source in the rainfall. By the
+heat of the sun water is evaporated from the reservoir of the
+ocean and from moist surfaces everywhere. Mingled as vapor with
+the air, it is carried by the winds over sea and land, and
+condensed it returns to the earth as rain or snow. That part of
+the rainfall which descends on the ocean does not concern us, but
+that which falls on the land accomplishes, as it returns to the
+sea, the most important work of all surface geological agencies.
+
+The rainfall may be divided into three parts: the first DRIES UP,
+being discharged into the air by evaporation either directly from
+the soil or through vegetation; the second RUNS OFF over the
+surface to flood the streams; the third SOAKS IN the ground and is
+henceforth known as GROUND or UNDERGROUND WATER.
+
+THE DESCENT OF GROUND WATER. Seeping through the mantle of waste,
+ground water soaks into the pores and crevices of the underlying
+rock. All rocks of the upper crust of the earth are more or less
+porous, and all drink in water. IMPERVIOUS ROCKS, such as granite,
+clay, and shale, have pores so minute that the water which they
+take in is held fast within them by capillary attraction, and none
+drains through. PERVIOUS ROCKS, on the other hand, such as many
+sandstones, have pore spaces so large that water filters through
+them more or less freely. Besides its seepage through the pores of
+pervious rocks, water passes to lower levels through the joints
+and cracks by which all rocks, near the surface are broken.
+
+Even the closest-grained granite has a pore space of 1 in 400,
+while sandstone may have a pore space of 1 in 4. Sand is so porous
+that it may absorb a third of its volume of water, and a loose
+loam even as much as one half.
+
+THE GROUND-WATER SURFACE is the name given the upper surface of
+ground water, the level below which all rocks are saturated. In
+dry seasons the ground-water surface sinks. For ground water is
+constantly seeping downward under gravity, it is evaporated in the
+waste and its moisture is carried upward by capillarity and the
+roots of plants to the surface to be evaporated in the air. In wet
+seasons these constant losses are more than made good by fresh
+supplies from that part of the rainfall which soaks into the
+ground, and the ground-water surface rises.
+
+In moist climates the ground-water surface (Fig. 24) lies, as a
+rule, within a few feet of the land surface and conforms to it in
+a general way, although with slopes of less inclination than those
+of the hills and valleys. In dry climates permanent ground water
+may be found only at depths of hundreds of feet. Ground water is
+held at its height by the fact that its circulation is constantly
+impeded by capillarity and friction. If it were as free to drain
+away as are surface streams, it would sink soon after a rain to
+the level of the deepest valleys of the region.
+
+WELLS AND SPRINGS. Excavations made in permeable rocks below the
+ground-water surface fill to its level and are known as wells.
+Where valleys cut this surface permanent streams are formed, the
+water either oozing forth along ill-defined areas or issuing at
+definite points called springs, where it is concentrated by the
+structure of the rocks. A level tract where the ground-water
+surface coincides with the surface of the ground is a swamp or
+marsh.
+
+By studying a spring one may learn much of the ways and work of
+ground water. Spring water differs from that of the stream into
+which it flows in several respects. If we test the spring with a
+thermometer during successive months, we shall find that its
+temperature remains much the same the year round. In summer it is
+markedly cooler than the stream; in winter it is warmer and
+remains unfrozen while the latter perhaps is locked in ice. This
+means that its underground path must lie at such a distance from
+the surface that it is little affected by summer's heat and
+winter's cold.
+
+While the stream is often turbid with surface waste washed into it
+by rains, the spring remains clear; its water has been filtered
+during its slow movement through many small underground passages
+and the pores of rocks. Commonly the spring differs from the
+stream in that it carries a far larger load of dissolved rock.
+Chemical analysis proves that streams contain various minerals in
+solution, but these are usually in quantities so small that they
+are not perceptible to the taste or feel. But the water of springs
+is often well charged with soluble minerals; in its slow, long
+journey underground it has searched out the soluble parts of the
+rocks through which it seeps and has dissolved as much of them as
+it could. When spring water is boiled away, the invisible load
+which it has carried is left behind, and in composition is found
+to be practically identical with that of the soluble ingredients
+of the country rock. Although to some extent the soluble waste of
+rocks is washed down surface slopes by the rain, by far the larger
+part is carried downward by ground water and is delivered to
+streams by springs.
+
+In limestone regions springs are charged with calcium carbonate
+(the carbonate of lime), and where the limestone is magnesian they
+contain magnesium carbonate also. Such waters are "hard"; when
+used in washing, the minerals which they contain combine with the
+fatty acids of soap to form insoluble curdy compounds. When
+springs rise from rocks containing gypsum they are hard with
+calcium sulphate. In granite regions they contain more or less
+soda and potash from the decay of feldspar.
+
+The flow of springs varies much less during the different seasons
+of the year than does that of surface streams. So slow is the
+movement of ground water through the rocks that even during long
+droughts large amounts remain stored above the levels of surface
+drainage.
+
+MOVEMENTS OF GROUND WATER. Ground water is in constant movement
+toward its outlets. Its rate varies according to many conditions,
+but always is extremely slow. Even through loose sands beneath the
+beds of rivers it sometimes does not exceed a fifth of a mile a
+year.
+
+In any region two zones of flow may be distinguished. The UPPER
+ZONE OF FLOW extends from the ground-water surface downward
+through the waste mantle and any permeable rocks on which the
+mantle rests, as far as the first impermeable layer, where the
+descending movement of the water is stopped. The DEEP ZONES OF
+FLOW occupy any pervious rocks which may be found below the
+impervious layer which lies nearest to the surface. The upper zone
+is a vast sheet of water saturating the soil and rocks and slowly
+seeping downward through their pores and interstices along the
+slopes to the valleys, where in part it discharges in springs and
+often unites also in a wide underflowing stream which supports and
+feeds the river (Fig. 24).
+
+A city in a region of copious rains, built on the narrow flood
+plain of a river, overlooked by hills, depends for its water
+supply on driven wells, within the city limits, sunk in the sand a
+few yards from the edge of the stream. Are these wells fed by
+water from the river percolating through the sand, or by ground
+water on its way to the stream and possibly contaminated with the
+sewage of the town?
+
+At what height does underground water stand in the wells of your
+region? Does it vary with the season? Have you ever known wells to
+go dry? It may be possible to get data from different wells and to
+draw a diagram showing the ground-water surface as compared with
+the surface of the ground.
+
+FISSURE SPRINGS AND ARTESIAN WELLS. The DEEPER ZONES OF FLOW lie in
+pervious strata which are overlain by some impervious stratum.
+Such layers are often carried by their dip to great depths, and
+water may circulate in them to far below the level of the surface
+streams and even of the sea. When a fissure crosses a water-
+bearing stratum, or AQUIFIER, water is forced upward by the
+pressure of the weight of the water contained in the higher parts
+of the stratum, and may reach the surface as a fissure spring. A
+boring which taps such an aquifer is known as an artesian well, a
+name derived from a province in France where wells of this kind
+have been long in use. The rise of the water in artesian wells,
+and in fissure springs also, depends on the following conditions
+illustrated in Figure 29. The aquifer dips toward the region of
+the wells from higher ground, where it outcrops and receives its
+water. It is inclosed between an impervious layer above and water-
+tight or water-logged layers beneath. The weight of the column of
+water thus inclosed in the aquifer causes water to rise in the
+well, precisely as the weight of the water in a standpipe forces
+it in connected pipes to the upper stories of buildings.
+
+Which will supply the larger region with artesian wells, an
+aquifer whose dip is steep or one whose dip is gentle? Which of
+the two aquifers, their thickness being equal, will have the
+larger outcrop and therefore be able to draw upon the larger
+amount of water from the rainfall? Illustrate with diagrams.
+
+THE ZONE OF SOLUTION. Near the surface, where the circulation of
+ground water is most active, it oxidizes, corrodes, and dissolves
+the rocks through which it passes. It leaches soils and subsoils
+of their lime and other soluble minerals upon which plants depend
+for their food. It takes away the soluble cements of rocks; it
+widens fissures and joints and opens winding passages along the
+bedding planes; it may even remove whole beds of soluble rocks,
+such as rock salt, limestone, or gypsum. The work of ground water
+in producing landslides has already been noticed. The zone in
+which the work of ground water is thus for the most part
+destructive we may call the zone of solution.
+
+CAVES. In massive limestone rocks, ground water dissolves channels
+which sometimes form large caves (Fig. 30). The necessary
+conditions for the excavation of caves of great size are well
+shown in central Kentucky, where an upland is built throughout of
+thick horizontal beds of limestone. The absence of layers of
+insoluble or impervious rock in its structure allows a free
+circulation of ground water within it by the way of all natural
+openings in the rock. These water ways have been gradually
+enlarged by solution and wear until the upland is honeycombed with
+caves. Five hundred open caverns are known in one county.
+
+Mammoth Cave, the largest of these caverns, consists of a
+labyrinth of chambers and winding galleries whose total length is
+said to be as much as thirty miles. One passage four miles long
+has an average width of about sixty feet and an average height of
+forty feet. One of the great halls is three hundred feet in width
+and is overhung by a solid arch of limestone one hundred feet
+above the floor. Galleries at different levels are connected by
+well-like pits, some of which measure two hundred and twenty-five
+feet from top to bottom. Through some of the lowest of these
+tunnels flows Echo River, still at work dissolving and wearing
+away the rock while on its dark way to appear at the surface as a
+great spring.
+
+NATURAL BRIDGES. As a cavern enlarges and the surface of the land
+above it is lowered by weathering, the roof at last breaks down
+and the cave becomes an open ravine. A portion of the roof may for
+a while remain, forming a "natural bridge."
+
+SINK HOLES. In limestone regions channels under ground may become
+so well developed that the water of rains rapidly drains away
+through them. Ground water stands low and wells must be sunk deep
+to find it. Little or no surface water is left to form brooks.
+
+Thus across the limestone upland of central Kentucky one meets but
+three surface streams in a hundred miles. Between their valleys
+surface water finds its way underground by means of sink holes.
+These are pits, commonly funnel shaped, formed by the enlargement
+of crevice or joint by percolating water, or by the breakdown of
+some portion of the roof of a cave. By clogging of the outlet a
+sink hole may come to be filled by a pond.
+
+Central Florida is a limestone region with its drainage largely
+subterranean and in part below the level even of the sea. Sink
+holes are common, and many of them are occupied by lakelets. Great
+springs mark the point of issue of underground streams, while some
+rise from beneath the sea. Silver Spring, one of the largest,
+discharges from a basin eight hundred feet wide and thirty feet
+deep a little river navigable for small steamers to its source.
+About the spring there are no surface streams for sixty miles.
+
+THE KARST. Along the eastern coast of the Adriatic, as far south
+as Montenegro, lies a belt of limestone mountains singularly worn
+and honeycombed by the solvent action of water. Where forests have
+been cut from the mountain sides and the red soil has washed away,
+the surface of the white limestone forms a pathless desert of rock
+where each square rod has been corroded into an intricate branch
+work of shallow furrows and sharp ridges. Great sink holes, some
+of them six hundred feet deep and more, pockmark the surface of
+the land. The drainage is chiefly subterranean. Surface streams
+are rare and a portion of their courses is often under ground.
+Fragmentary valleys come suddenly to an end at walls of rock where
+the rivers which occupy the valleys plunge into dark tunnels to
+reappear some miles away. Ground water stands so far below the
+surface that it cannot be reached by wells, and the inhabitants
+depend on rain water stored for household uses. The finest cavern
+of Europe, the Adelsberg Grotto, is in this region. Karst, the
+name of a part of this country, is now used to designate any
+region or landscape thus sculptured by the chemical action of
+surface and ground water. We must remember that Karst regions are
+rare, and striking as is the work of their subterranean streams,
+it is far less important than the work done by the sheets of
+underground water slowly seeping through all subsoils and porous
+rocks in other regions.
+
+Even when gathered into definite channels, ground water does not
+have the erosive power of surface streams, since it carries with
+it little or no rock waste. Regions whose underground drainage is
+so perfect that the development of surface streams has been
+retarded or prevented escape to a large extent the leveling action
+of surface running waters, and may therefore stand higher than the
+surrounding country. The hill honeycombed by Luray Cavern,
+Virginia, has been attributed to this cause.
+
+CAVERN DEPOSITS. Even in the zone of solution water may under
+certain circumstances deposit as well as erode. As it trickles
+from the roof of caverns, the lime carbonate which it has taken
+into solution from the layers of limestone above is deposited by
+evaporation in the air in icicle-like pendants called STALACTITES.
+As the drops splash on the floor there are built up in the same
+way thicker masses called STALAGMITES, which may grow to join the
+stalactites above, forming pillars. A stalagmitic crust often
+seals with rock the earth which accumulates in caverns, together
+with whatever relics of cave dwellers, either animals or men, it
+may contain.
+
+Can you explain why slender stalactites formed by the drip of
+single drops are often hollow pipes?
+
+THE ZONE OF CEMENTATION. With increasing depth subterranean water
+becomes more and more sluggish in its movements and more and more
+highly charged with minerals dissolved from the rocks above. At
+such depths it deposits these minerals in the pores of rocks,
+cementing their grains together, and in crevices and fissures,
+forming mineral veins. Thus below the zone of solution where the
+work of water is to dissolve, lies the zone of cementation where
+its work is chemical deposit. A part of the invisible load of
+waste is thus transferred from rocks near the surface to those at
+greater depths.
+
+As the land surface is gradually lowered by weathering and the
+work of rain and streams, rocks which have lain deep within the
+zone of cementation are brought within the zone of solution. Thus
+there are exposed to view limestones, whose cracks were filled
+with calcite (crystallized carbonate of lime), with quartz or
+other minerals, and sandstones whose grains were well cemented
+many feet below the surface.
+
+CAVITY FILLING. Small cavities in the rocks are often found more
+or less completely filled with minerals deposited from solution by
+water in its constant circulation underground. The process may be
+illustrated by the deposit of salt crystals in a cup of
+evaporating brine, but in the latter instance the solution is not
+renewed as in the case of cavities in the rocks. A cavity thus
+lined with inward-pointing crystals is called a GEODE.
+
+CONCRETIONS. Ground water seeping through the pores of rocks may
+gather minerals disseminated throughout them into nodular masses
+called concretions. Thus silica disseminated through limestone is
+gathered into nodules of flint. While geodes grow from the outside
+inwards, concretions grow outwards from the center. Nor are they
+formed in already existing cavities as are geodes. In soft clays
+concretions may, as they grow, press the clay aside. In many other
+rocks concretions are made by the process of REPLACEMENT. Molecule
+by molecule the rock is removed and the mineral of the concretion
+substituted in its place. The concretion may in this way preserve
+intact the lamination lines or other structures of the rock. Clays
+and shales often contain concretions of lime carbonate, of iron
+carbonate, or of iron sulphide. Some fossil, such as a leaf or
+shell, frequently forms the nucleus around which the concretion
+grows.
+
+Why are building stones more easily worked when "green" than after
+their quarry water has dried out?
+
+DEPOSITS OF GROUND WATER IN ARID REGIONS. In arid lands where
+ground water is drawn by capillarity to the surface and there
+evaporates, it leaves as surface incrustations the minerals held
+in solution. White limy incrustations of this nature cover
+considerable tracts in northern Mexico. Evaporating beneath the
+surface, ground water may deposit a limy cement in beds of loose
+sand and gravel. Such firmly cemented layers are not uncommon in
+western Kansas and Nebraska, where they are known as "mortar
+beds."
+
+THERMAL SPRINGS. While the lower limit of surface drainage is sea
+level, subterranean water circulates much below that depth, and is
+brought again to the surface by hydrostatic pressure. In many
+instances springs have a higher temperature than the average
+annual temperature of the region, and are then known as thermal
+springs. In regions of present or recent volcanic activity, such
+as the Yellowstone National Park, we may believe that the heat of
+thermal springs is derived from uncooled lavas, perhaps not far
+below the surface. But when hot springs occur at a distance of
+hundreds of miles from any volcano, as in the case of the hot
+springs of Bath, England, it is probable that their waters have
+risen from the heated rocks of the earth's interior. The springs
+of Bath have a temperature of 120 degrees F., 70 degrees above the
+average annual temperature of the place. If we assume that the
+rate of increase in the earth's internal heat is here the average
+rate, 1 degree F. to every sixty feet of descent, we may conclude
+that the springs of Bath rise from at least a depth of forty-two
+hundred feet.
+
+Water may descend to depths from which it can never be brought
+back by hydrostatic pressure. It is absorbed by highly heated
+rocks deep below the surface. From time to time some of this deep-
+seated water may be returned to open air in the steam of volcanic
+eruptions.
+
+SURFACE DEPOSITS OF SPRINGS. Where subterranean water returns to
+the surface highly charged with minerals in solution, on exposure
+to the air it is commonly compelled to lay down much of its
+invisible load in chemical deposits about the spring. These are
+thrown down from solution either because of cooling, evaporation,
+the loss of carbon dioxide, or the work of algae.
+
+Many springs have been charged under pressure with carbon dioxide
+from subterranean sources and are able therefore to take up large
+quantities of lime carbonate from the limestone rocks through
+which they pass. On reaching the surface the pressure is relieved,
+the gas escapes, and the lime carbonate is thrown down in deposits
+called TRAVERTINE. The gas is sometimes withdrawn and the deposit
+produced in large part by the action of algae and other humble
+forms of plant life.
+
+At the Mammoth Hot Springs in the valley of the Gardiner River,
+Yellowstone National Park, beautiful terraces and basins of
+travertine are now building, chiefly by means of algae which cover
+the bottoms, rims, and sides of the basins and deposit lime
+carbonate upon them in successive sheets. The rock, snow-white
+where dry, is coated with red and orange gelatinous mats where the
+algae thrive in the over-flowing waters.
+
+Similar terraces of travertine are found to a height of fourteen
+hundred feet up the valley side. We may infer that the springs
+which formed these ancient deposits discharged near what was then
+the bottom of the valley, and that as the valley has been deepened
+by the river the ground water of the region has found lower and
+lower points of issue.
+
+In many parts of the country calcareous springs occur which coat
+with lime carbonate mosses, twigs, and other objects over which
+their waters flow. Such are popularly known as petrifying springs,
+although they merely incrust the objects and do not convert them
+into stone.
+
+Silica is soluble in alkaline waters, especially when these are
+hot. Hot springs rising through alkaline siliceous rocks, such as
+lavas, often deposit silica in a white spongy formation known as
+SILICEOUS SINTER, both by evaporation and by the action of algae
+which secrete silica from the waters. It is in this way that the
+cones and mounds of the geysers in the Yellowstone National Park
+and in Iceland have been formed.
+
+Where water oozes from the earth one may sometimes see a rusty
+deposit on the ground, and perhaps an iridescent scum upon the
+water. The scum is often mistaken for oil, but at a touch it
+cracks and breaks, as oil would not do. It is a film of hydrated
+iron oxide, or LIMONITE, and the spring is an iron, or chalybeate,
+spring. Compounds of iron have been taken into solution by ground
+water from soil and rocks, and are now changed to the insoluble
+oxide on exposure to the oxygen of the air.
+
+In wet ground iron compounds leached by ground water from the soil
+often collect in reddish deposits a few feet below the surface,
+where their downward progress is arrested by some impervious clay.
+At the bottom of bogs and shallow lakes iron ores sometimes
+accumulate to a depth of several feet.
+
+Decaying organic matter plays a large part in these changes. In
+its presence the insoluble iron oxides which give color to most
+red and yellow rocks are decomposed, leaving the rocks of a gray
+or bluish color, and the soluble iron compounds which result are
+readily leached out,--effects seen where red or yellow clays have
+been bleached about some decaying tree root.
+
+The iron thus dissolved is laid down as limonite when oxidized, as
+about a chalybeate spring; but out of contact with the air and in
+the presence of carbon dioxide supplied by decaying vegetation, as
+in a peat bog, it may be deposited as iron carbonate, or SIDERITE.
+
+TOTAL AMOUNT OF UNDERGROUND WATERS. In order to realize the vast
+work in solution and cementation which underground waters are now
+doing and have done in all geological ages, we must gain some
+conception of their amount. At a certain depth, estimated at about
+six miles, the weight of the crust becomes greater than the rocks
+can bear, and all cavities and pores in them must be completely
+closed by the enormous pressure which they sustain. Below a depth
+of even three or four miles it is believed that ground water
+cannot circulate. Estimating the average pore spaces of the
+different rocks of the earth's crust above this depth, and the
+average per cents of their pore spaces occupied by water, it has
+been recently computed that the total amount of ground water is
+equal to a sheet of water one hundred feet deep, covering the
+entire surface of the earth.
+
+
+
+
+
+CHAPTER III
+
+RIVERS AND VALLEYS
+
+
+THE RUN-OFF. We have traced the history of that portion of the
+rainfall which soaks into the ground; let us now return to that
+part which washes along the surface and is known as the RUN-OFF.
+Fed by rains and melting snows, the run-off gathers into courses,
+perhaps but faintly marked at first, which join more definite and
+deeply cut channels, as twigs their stems. In a humid climate the
+larger ravines through which the run-off flows soon descend below
+the ground-water surface. Here springs discharge along the sides
+of the little valleys and permanent streams begin. The water
+supplied by the run-off here joins that part of the rainfall which
+had soaked into the soil, and both now proceed together by way of
+the stream to the sea.
+
+RIVER FLOODS. Streams vary greatly in volume during the year. At
+stages of flood they fill their immediate banks, or overrun them
+and inundate any low lands adjacent to the channel; at stages of
+low water they diminish to but a fraction of their volume when at
+flood.
+
+At times of flood, rivers are fed chiefly by the run-off; at times
+of low water, largely or even wholly by springs.
+
+How, then, will the water of streams differ at these times in
+turbidity and in the relative amount of solids carried in
+solution?
+
+In parts of England streams have been known to continue flowing
+after eighteen months of local drought, so great is the volume of
+water which in humid climates is stored in the rocks above the
+drainage level, and so slowly is it given off in springs.
+
+In Illinois and the states adjacent, rivers remain low in winter
+and a "spring freshet" follows the melting of the winter's snows.
+A "June rise" is produced by the heavy rains of early summer. Low
+water follows in July and August, and streams are again swollen to
+a moderate degree under the rains of autumn.
+
+THE DISCHARGE OF STREAMS. The per cent of rainfall discharged by
+rivers varies with the amount of rainfall, the slope of the
+drainage area, the texture of the rocks, and other factors. With
+an annual rainfall of fifty inches in an open country, about fifty
+per cent is discharged; while with a rainfall of twenty inches
+only fifteen per cent is discharged, part of the remainder being
+evaporated and part passing underground beyond the drainage area.
+Thus the Ohio discharges thirty per cent of the rainfall of its
+basin, while the Missouri carries away but fifteen per cent. A
+number of the streams of the semi-arid lands of the West do not
+discharge more than five per cent of the rainfall.
+
+Other things being equal, which will afford the larger proportion
+of run-off, a region underlain with granite rock or with coarse
+sandstone? grass land or forest? steep slopes or level land? a
+well-drained region or one abounding in marshes and ponds? frozen
+or unfrozen ground? Will there be a larger proportion of run-off
+after long rains or after a season of drought? after long and
+gentle rains, or after the same amount of precipitation in a
+violent rain? during the months of growing vegetation, from June
+to August, or during the autumn months?
+
+DESERT STREAMS. In arid regions the ground-water surface lies so
+low that for the most part stream ways do not intersect it.
+Streams therefore are not fed by springs, but instead lose volume
+as their waters soak into the thirsty rocks over which they flow.
+They contribute to the ground water of the region instead of being
+increased by it. Being supplied chiefly by the run-off, they
+wither at times of drought to a mere trickle of water, to a chain
+of pools, or go wholly dry, while at long intervals rains fill
+their dusty beds with sudden raging torrents. Desert rivers
+therefore periodically shorten and lengthen their courses,
+withering back at times of drought for scores of miles, or even
+for a hundred miles from the point reached by their waters during
+seasons of rain.
+
+THE GEOLOGICAL WORK OF STREAMS. The work of streams is of three
+kinds,--transportation, erosion, and deposition. Streams TRANSPORT
+the waste of the land; they wear, or ERODE, their channels both on
+bed and banks; and they DEPOSIT portions of their load from time
+to time along their courses, finally laying it down in the sea.
+Most of the work of streams is done at times of flood.
+
+TRANSPORTATION
+
+THE INVISIBLE LOAD OF STREAMS. Of the waste which a river
+transports we may consider first the invisible load which it
+carries in solution, supplied chiefly by springs but also in part
+by the run-off and from the solution of the rocks of its bed. More
+than half the dissolved solids in the water of the average river
+consists of the carbonates of lime and magnesia; other substances
+are gypsum, sodium sulphate (Glauber's salts), magnesium sulphate
+(Epsom salts), sodium chloride (common salt), and even silica, the
+least soluble of the common rock-making minerals. The amount of
+this invisible load is surprisingly large. The Mississippi, for
+example, transports each year 113,000,000 tons of dissolved rock
+to the Gulf.
+
+THE VISIBLE LOAD OF STREAMS. This consists of the silt which the
+stream carries in suspension, and the sand and gravel and larger
+stones which it pushes along its bed. Especially in times of flood
+one may note the muddy water, its silt being kept from settling by
+the rolling, eddying currents; and often by placing his ear close
+to the bottom of a boat one may hear the clatter of pebbles as
+they are hurried along. In mountain torrents the rumble of
+bowlders as they clash together may be heard some distance away.
+The amount of the load which a stream can transport depends on its
+velocity. A current of two thirds of a mile per hour can move fine
+sand, while one of four miles per hour sweeps along pebbles as
+large as hen's eggs. The transporting power of a stream varies as
+the sixth power of its velocity. If its velocity is multiplied by
+two, its transporting power is multiplied by the sixth power of
+two: it can now move stones sixty-four times as large as it could
+before.
+
+Stones weigh from two to three times as much as water, and in
+water lose the weight of the volume of water which they displace.
+What proportion, then, of their weight in air do stones lose when
+submerged?
+
+MEASUREMENT OF STREAM LOADS. To obtain the total amount of waste
+transported by a river is an important but difficult matter. The
+amount of water discharged must first be found by multiplying the
+number of square feet in the average cross section of the stream
+by its velocity per second, giving the discharge per second in
+cubic feet. The amount of silt to a cubic foot of water is found
+by filtering samples of the water taken from different parts of
+the stream and at different times in the year, and drying and
+weighing the residues. The average amount of silt to the cubic
+foot of water, multiplied by the number of cubic feet of water
+discharged per year, gives the total load carried in suspension
+during that time. Adding to this the estimated amount of sand and
+gravel rolled along the bed, which in many swift rivers greatly
+exceeds the lighter material held in suspension, and adding also
+the total amount of dissolved solids, we reach the exceedingly
+important result of the total load of waste discharged by the
+river. Dividing the volume of this load by the area of the river
+basin gives another result of the greatest geological interest,--
+the rate at which the region is being lowered by the combined
+action of weathering and erosion, or the rate of denudation.
+
+THE RATE OF DENUDATION OF RIVER BASINS. This rate varies widely.
+The Mississippi basin may be taken as a representative land
+surface because of the varieties of surface, altitude and slope,
+climate, and underlying rocks which are included in its great
+extent. Careful measurements show that the Mississippi basin is
+now being lowered at a rate of one four-thousandth of a foot a
+year, or one foot in four thousand years. Taking this as the
+average rate of denudation for the land surfaces of the globe,
+estimates have been made of the length of time required at this
+rate to wash and wear the continents to the level of the sea. As
+the average elevation of the lands of the globe is reckoned at
+2411 feet, this result would occur in nine or ten million years,
+if the present rate of denudation should remain unchanged. But
+even if no movements of the earth's crust should lift or depress
+the continents, the rate of wear and the removal of waste from
+their surfaces will not remain the same. It must constantly
+decrease as the lands are worn nearer to sea level and their
+slopes become more gentle. The length of time required to wear
+them away is therefore far in excess of that just stated.
+
+The drainage area of the Potomac is 11,000 square miles. The silt
+brought down in suspension in a year would cover a square mile to
+the depth of four feet. At what rate is the Potomac basin being
+lowered from this cause alone?
+
+It is estimated that the Upper Ganges is lowering its basin at the
+rate of one foot in 823 years, and the Po one foot in 720 years.
+Why so much faster than the Potomac and the Mississippi?
+
+HOW STREAMS GET THEIR LOADS. The load of streams is derived from a
+number of sources, the larger part being supplied by the
+weathering of valley slopes. We have noticed how the mantle of
+waste creeps and washes to the stream ways. Watching the run-off
+during a rain, as it hurries muddy with waste along the gutter or
+washes down the hillside, we may see the beginning of the route by
+which the larger part of their load is delivered to rivers.
+Streams also secure some of their load by wearing it from their
+beds and banks,--a process called erosion.
+
+EROSION
+
+Streams erode their beds chiefly by means of their bottom load,--
+the stones of various sizes and the sand and even the fine mud
+which they sweep along. With these tools they smooth, grind, and
+rasp the rock of their beds, using them in much the fashion of
+sandpaper or a file.
+
+WEATHERING OF RIVER BEDS. The erosion of stream beds is greatly
+helped by the work of the weather. Especially at low water more or
+less of the bed is exposed to the action of frost and heat and
+cold, joints are opened, rocks are pried loose and broken up and
+made ready to be swept away by the stream at time of flood.
+
+POTHOLES. In rapids streams also drill out their rocky beds. Where
+some slight depression gives rise to an eddy, the pebbles which
+gather in it are whirled round and round, and, acting like the bit
+of an auger, bore out a cylindrical pit called a pothole. Potholes
+sometimes reach a depth of a score of feet. Where they are
+numerous they aid materially in deepening the channel, as the
+walls between them are worn away and they coalesce.
+
+WATERFALLS. One of the most effective means of erosion which the
+river possesses is the waterfall. The plunging water dislodges
+stones from the face of the ledge over which it pours, and often
+undermines it by excavating a deep pit at its base. Slice after
+slice is thus thrown down from the front of the cliff, and the
+cataract cuts its way upstream leaving a gorge behind it.
+
+NIAGARA FALLS. The Niagara River flows from Lake Erie at Buffalo in
+a broad channel which it has cut but a few feet below the level of
+the region. Some thirteen miles from the outlet it plunges over a
+ledge one hundred and seventy feet high into the head of a narrow
+gorge which extends for seven miles to the escarpment of the
+upland in which the gorge is cut. The strata which compose the
+upland dip gently upstream and consist at top of a massive
+limestone, at the Falls about eighty feet thick, and below of soft
+and easily weathered shale. Beneath the Falls the underlying shale
+is cut and washed away by the descending water and retreats also
+because of weathering, while the overhanging limestone breaks down
+in huge blocks from time to time.
+
+Niagara is divided by Goat Island into the Horseshoe Falls and the
+American Falls. The former is supplied by the main current of the
+river, and from the semicircular sweep of its rim a sheet of water
+in places at least fifteen or twenty feet deep plunges into a pool
+a little less than two hundred feet in depth. Here the force of
+the falling water is sufficient to move about the fallen blocks of
+limestone and use them in the excavation of the shale of the bed.
+At the American Falls the lesser branch of the river, which flows
+along the American side of Goat Island, pours over the side of the
+gorge and breaks upon a high talus of limestone blocks which its
+smaller volume of water is unable to grind to pieces and remove.
+
+A series of surveys have determined that from 1842 to 1890 the
+Horseshoe Falls retreated at the rate of 2.18 feet per year, while
+the American Falls retreated at the rate of 0.64 feet in the same
+period. We cannot doubt that the same agency which is now
+lengthening the gorge at this rapid rate has cut it back its
+entire length of seven miles.
+
+While Niagara Falls have been cutting back a gorge seven miles
+long and from two hundred to three hundred feet deep, the river
+above the Falls has eroded its bed scarcely below the level of the
+upland on which it flows. Like all streams which are the outlets
+of lakes, the Niagara flows out of Lake Erie clear of sediment, as
+from a settling basin, and carries no tools with which to abrade
+its bed. We may infer from this instance how slight is the erosive
+power of clear water on hard rock.
+
+Assuming that the rate of recession of the combined volumes of the
+American and Horseshoe Falls was three feet a year below Goat
+Island, and ASSUMING THAT THIS RATE HAS BEEN UNIFORM IN THE PAST,
+how long is it since the Niagara River fell over the edge of the
+escarpment where now is the mouth of the present gorge?
+
+The profile of the bed of the Niagara along the gorge (Fig. 39)
+shows alternating deeps and shallows which cannot be accounted
+for, except in a single instance, by the relative hardness of the
+rocks of the river bed. The deeps do not exceed that at the foot
+of the Horseshoe Falls at the present time. When the gorge was
+being cut along the shallows, how did the Falls compare in
+excavating power, in force, and volume with the Niagara of to-day?
+How did the rate of recession at those times compare with the
+present rate? Is the assumption made above that the rate of
+recession has been uniform correct?
+
+The first stretch of shallows below the Falls causes a tumultuous
+rapid impossible to sound. Its depth has been estimated at thirty-
+five feet. From what data could such an estimate be made?
+
+Suggest a reason why the Horseshoe Falls are convex upstream.
+
+At the present rate of recession which will reach the head of Goat
+Island the sooner, the American or the Horseshoe Falls? What will
+be the fate of the Falls left behind when the other has passed
+beyond the head of the island?
+
+The rate at which a stream erodes its bed depends in part upon the
+nature of the rocks over which it flows. Will a stream deepen its
+channel more rapidly on massive or on thin-bedded and close-
+jointed rocks? on horizontal strata or on strata steeply inclined?
+
+DEPOSITION
+
+While the river carries its invisible load of dissolved rock on
+without stop to the sea, its load of visible waste is subject to
+many delays en route. Now and again it is laid aside, to be picked
+up later and carried some distance farther on its way. One of the
+most striking features of the river therefore is the waste
+accumulated along its course, in bars and islands in the channel,
+beneath its bed, and in flood plains along its banks. All this
+alluvium, to use a general term for river deposits, with which the
+valley is cumbered is really en route to the sea; it is only
+temporarily laid aside to resume its journey later on. Constantly
+the river is destroying and rebuilding its alluvial deposits, here
+cutting and there depositing along its banks, here eroding and
+there building a bar, here excavating its bed and there filling it
+up, and at all times carrying the material picked up at one point
+some distance on downstream before depositing it at another.
+
+These deposits are laid down by slackening currents where the
+velocity of the stream is checked, as on the inner side of curves,
+and where the slope of the bed is diminished, and in the lee of
+islands, bridge piers and projecting points of land. How slight is
+the check required to cause a current to drop a large part of its
+load may be inferred from the law of the relation of the
+transporting power to the velocity. If the velocity is decreased
+one half, the current can move fragments but one sixty-fourth the
+size of those which it could move before, and must drop all those
+of larger size.
+
+Will a river deposit more at low water or at flood? when rising or
+when falling?
+
+STRATIFICATION. River deposits are stratified, as may be seen in
+any fresh cut in banks or bars. The waste of which they are built
+has been sorted and deposited in layers, one above another; some
+of finer and some of coarser material. The sorting action of
+running water depends on the fact that its transporting power
+varies with the velocity. A current whose diminishing velocity
+compels it to drop coarse gravel, for example, is still able to
+move all the finer waste of its load, and separating it from the
+gravel, carries it on downstream; while at a later time slower
+currents may deposit on the gravel bed layers of sand, and, still
+later, slack water may leave on these a layer of mud. In case of
+materials lighter than water the transporting power does not
+depend on the velocity, and logs of wood, for instance, are
+floated on to the sea on the slowest as well as on the most rapid
+currents.
+
+CROSS BEDDING. A section of a bar exposed at low water may show
+that it is formed of layers of sand, or coarser stuff, inclined
+downstream as steeply often as the angle of repose of the
+material. From a boat anchored over the lower end of a submerged
+sand bar we may observe the way in which this structure, called
+cross bedding, is produced. Sand is continually pushed over the
+edge of the bar at b (Fig. 42) and comes to rest in successive
+layers on the sloping surface. At the same time the bar may be
+worn away at the upper end, a, and thus slowly advance down
+stream. While the deposit is thus cross bedded, it constitutes as
+a whole a stratum whose upper and lower surfaces are about
+horizontal. In sections of river banks one may often see a
+vertical succession of cross-bedded strata, each built in the way
+described.
+
+WATER WEAR. The coarser material of river deposits, such as
+cobblestones, gravel, and the larger grains of sand, are WATER
+WORN, or rounded, except when near their source. Rolling along the
+bottom they have been worn round by impact and friction as they
+rubbed against one another and the rocky bed of the stream.
+
+Experiments have shown that angular fragments of granite lose
+nearly half their weight and become well rounded after traveling
+fifteen miles in rotating cylinders partly filled with water.
+Marbles are cheaply made in Germany out of small limestone cubes
+set revolving in a current of water between a rotating bed of
+stone and a block of oak, the process requiring but about fifteen
+minutes. It has been found that in the upper reaches of mountain
+streams a descent of less than a mile is sufficient to round
+pebbles of granite.
+
+LAND FORMS DUE TO RIVER EROSION
+
+RIVER VALLEYS. In their courses to the sea, rivers follow valleys
+of various forms, some shallow and some deep, some narrow and some
+wide. Since rivers are known to erode their beds and banks, it is
+a fair presumption that, aided by the weather, they have excavated
+the valleys in which they flow.
+
+Moreover, a bird's-eye view or a map of a region shows the
+significant fact that the valleys of a system unite with one
+another in a branch work, as twigs meet their stems and the
+branches of a tree its trunk. Each valley, from that of the
+smallest rivulet to that of the master stream, is proportionate to
+the size of the stream which occupies it. With a few explainable
+exceptions the valleys of tributaries join that of the trunk
+stream at a level; there is no sudden descent or break in the bed
+at the point of juncture. These are the natural consequences which
+must follow if the land has long been worked upon by streams, and
+no other process has ever been suggested which is competent to
+produce them. We must conclude that valley systems have been
+formed by the river systems which drain them, aided by the work of
+the weather; they are not gaping fissures in the earth's crust, as
+early observers imagined, but are the furrows which running water
+has drawn upon the land.
+
+As valleys are made by the slow wear of streams and the action of
+the weather, they pass in their development through successive
+stages, each of which has its own characteristic features. We may
+therefore classify rivers and valleys according to the stage which
+they have reached in their life history from infancy to old age.
+
+YOUNG RIVER VALLEYS
+
+INFANCY. The Red River of the North. A region in northwestern
+Minnesota and the adjacent portions of North Dakota and Manitoba
+was so recently covered by the waters of an extinct lake, known as
+Lake Agassiz, that the surface remains much as it was left when
+the lake was drained away. The flat floor, spread smooth with
+lake-laid silts, is still a plain, to the eye as level as the sea.
+Across it the Red River of the North and its branches run in
+narrow, ditch-like channels, steep-sided and shallow, not
+exceeding sixty feet in depth, their gradients differing little
+from the general slopes of the region. The trunk streams have but
+few tributaries; the river system, like a sapling with few limbs,
+is still undeveloped. Along the banks of the trunk streams short
+gullies are slowly lengthening headwards, like growing twigs which
+are sometime to become large branches.
+
+The flat interstream areas are as yet but little scored by
+drainage lines, and in wet weather water lingers in ponds in any
+initial depressions on the plain.
+
+CONTOURS. In order to read the topographic maps of the text-book
+and the laboratory the student should know that contours are lines
+drawn on maps to represent relief, all points on any given contour
+being of equal height above sea level. The CONTOUR INTERVAL is the
+uniform vertical distance between two adjacent contours and varies
+on different maps.
+
+To express regions of faint relief a contour interval of ten or
+twenty feet is commonly selected; while in mountainous regions a
+contour interval of two hundred and fifty, five hundred, or even
+one thousand feet may be necessary in order that the contours may
+not be too crowded for easy reading.
+
+Whether a river begins its life on a lake plain, as in the example
+just cited, or upon a coastal plain lifted from beneath the sea or
+on a spread of glacial drift left by the retreat of continental
+ice sheets, such as covers much of Canada and the northeastern
+parts of the United States, its infantile stage presents the same
+characteristic features,--a narrow and shallow valley, with
+undeveloped tributaries and undrained interstream areas. Ground
+water stands high, and, exuding in the undrained initial
+depressions, forms marshes and lakes.
+
+LAKES. Lakes are perhaps the most obvious of these fleeting
+features of infancy. They are short-lived, for their destruction
+is soon accomplished by several means. As a river system advances
+toward maturity the deepening and extending valleys of the
+tributaries lower the ground-water surface and invade the
+undrained depressions of the region. Lakes having outlets are
+drained away as their basin rims are cut down by the outflowing
+streams,--a slow process where the rim is of hard rock, but a
+rapid one where it is of soft material such as glacial drift.
+
+Lakes are effaced also by the filling of their basins. Inflowing
+streams and the wash of rains bring in waste. Waves abrade the
+shore and strew the debris worn from it over the lake bed. Shallow
+lakes are often filled with organic matter from decaying
+vegetation.
+
+Does the outflowing stream, from a lake carry sediment? How does
+this fact affect its erosive power on hard rock? on loose
+material?
+
+Lake Geneva is a well-known example of a lake in process of
+obliteration. The inflowing Rhone has already displaced the waters
+of the lake for a length of twenty miles with the waste brought
+down from the high Alps. For this distance there extends up the
+Rhone Valley an alluvial plain, which has grown lakeward at the
+rate of a mile and a half since Roman times, as proved by the
+distance inland at which a Roman port now stands.
+
+How rapidly a lake may be silted up under exceptionally favorable
+conditions is illustrated by the fact that over the bottom of the
+artificial lake, of thirty-five square miles, formed behind the
+great dam across the Colorado River at Austin, Texas, sediments
+thirty-nine feet deep gathered in seven years.
+
+Lake Mendota, one of the many beautiful lakes of southern
+Wisconsin, is rapidly cutting back the soft glacial drift of its
+shores by means of the abrasion of its waves. While the shallow
+basin is thus broadened, it is also being filled with the waste;
+and the time is brought nearer when it will be so shoaled that
+vegetation can complete the work of its effacement.
+
+Along the margin of a shallow lake mosses, water lilies, grasses,
+and other water-loving plants grow luxuriantly. As their decaying
+remains accumulate on the bottom, the ring of marsh broadens
+inwards, the lake narrows gradually to a small pond set in the
+midst of a wide bog, and finally disappears. All stages in this
+process of extinction may be seen among the countless lakelets
+which occupy sags in the recent sheets of glacial drift in the
+northern states; and more numerous than the lakes which still
+remain are those already thus filled with carbonaceous matter
+derived from the carbon dioxide of the atmosphere. Such fossil
+lakes are marked by swamps or level meadows underlain with muck.
+
+THE ADVANCE TO MATURITY. The infantile stage is brief. As a river
+advances toward maturity the initial depressions, the lake basins
+of its area, are gradually effaced. By the furrowing action of the
+rain wash and the head ward lengthening, of tributaries a
+branchwork of drainage channels grows until it covers the entire
+area, and not an acre is left on which the fallen raindrop does
+not find already cut for it an uninterrupted downward path which
+leads it on by way of gully, brook, and river to the sea. The
+initial surface of the land, by whatever agency it was modeled, is
+now wholly destroyed; the region is all reduced to valley slopes.
+
+THE LONGITUDINAL PROFILE OF A STREAM. This at first corresponds
+with the initial surface of the region on which the stream begins
+to flow, although its way may lead through basins and down steep
+descents. The successive profiles to which it reduces its bed are
+illustrated in Figure 51. As the gradient, or rate of descent of
+its bed, is lowered, the velocity of the river is decreased until
+its lessening energy is wholly consumed in carrying its load and
+it can no longer erode its bed. The river is now AT GRADE, and its
+capacity is just equal to its load. If now its load is increased
+the stream deposits, and thus builds up, or AGGRADES, its bed. On
+the other hand, if its load is diminished it has energy to spare,
+and resuming its work of erosion, DEGRADES its bed. In either case
+the stream continues aggrading or degrading until a new gradient
+is found where the velocity is just sufficient to move the load,
+and here again it reaches grade.
+
+V-VALLEYS. Vigorous rivers well armed with waste make short work
+of cutting their beds to grade, and thus erode narrow, steep-sided
+gorges only wide enough at the base to accommodate the stream. The
+steepness of the valley slopes depends on the relative rates at
+which the bed is cut down by the stream and the sides are worn
+back by the weather. In resistant rock a swift, well-laden stream
+may saw out a gorge whose sides are nearly or even quite vertical,
+but as a rule young valleys whose streams have not yet reached
+grade are V-shaped; their sides flare at the top because here the
+rocks have longest been opened up to the action of the weather.
+Some of the deepest canyons may be found where a rising land mass,
+either mountain range or plateau, has long maintained by its
+continued uplift the rivers of the region above grade.
+
+In the northern hemisphere the north sides of river valleys are
+sometimes of more gentle slope than the south sides. Can you
+suggest a reason?
+
+THE GRAND CANYON OF THE COLORADO RIVER IN ARIZONA. The Colorado
+River trenches the high plateau of northern Arizona with a
+colossal canyon two hundred and eighteen miles long and more than
+a mile in greatest depth. The rocks in which the canyon is cut are
+for the most part flat-lying, massive beds of limestones and
+sandstones, with some shales, beneath which in places harder
+crystalline rocks are disclosed. Where the canyon is deepest its
+walls have been profoundly dissected. Lateral ravines have widened
+into immense amphitheaters, leaving between them long ridges of
+mountain height, buttressed and rebuttressed with flanking spurs
+and carved into majestic architectural forms. From the extremity
+of one of these promontories it is two miles or more across the
+gulf to the point of the one opposite, and the heads of the
+amphitheaters are thirteen miles apart.
+
+The lower portion of the canyon is much narrower (Fig. 54) and its
+walls of dark crystalline rock sink steeply to the edge of the
+river, a swift, powerful stream a few hundred feet wide, turbid
+with reddish silt, by means of which it continually rasps its
+rocky bed as it hurries on. The Colorado is still deepening its
+gorge. In the Grand Canyon its gradient is seven and one half feet
+to the mile, but, as in all ungraded rivers, the descent is far
+from uniform. Graded reaches in soft rock alternate with steeper
+declivities in hard rock, forming rapids such as, for example, a
+stretch of ten miles where the fall averages twenty-one feet to
+the mile. Because of these dangerous rapids the few exploring
+parties who have traversed the Colorado canyon have done so at the
+hazard of their lives.
+
+The canyon has been shaped by several agencies. Its depth is due
+to the river which has sawed its way far toward the base of a
+lofty rising plateau. Acting alone this would have produced a
+slitlike gorge little wider than the breadth of the stream. The
+impressive width of the canyon and the magnificent architectural
+masses which fill it are owing to two causes.: Running water has
+gulched the walls and weathering has everywhere attacked and
+driven them back. The horizontal harder beds stand out in long
+lines of vertical cliffs, often hundreds of feet in height, at
+whose feet talus slopes conceal the outcrop of the weaker strata.
+As the upper cliffs have been sapped and driven back by the
+weather, broad platforms are left at their bases and the sides of
+the canyon descend to the river by gigantic steps. Far up and down
+the canyon the eye traces these horizontal layers, like the
+flutings of an elaborate molding, distinguishing each by its
+contour as well as by its color and thickness.
+
+The Grand Canyon of the Colorado is often and rightly cited as an
+example of the stupendous erosion which may be accomplished by a
+river. And yet the Colorado is a young stream and its work is no
+more than well begun. It has not yet wholly reached grade, and the
+great task of the river and its tributaries--the task of leveling
+the lofty plateau to a low plain and of transporting it grain by
+grain to the sea--still lies almost entirely in the future.
+
+WATERFALLS AND RAPIDS. Before the bed of a stream is reduced to
+grade it may be broken by abrupt descents which give rise to
+waterfalls and rapids. Such breaks in a river's bed may belong to
+the initial surface over which it began its course; still more
+commonly are they developed in the rock mass through which it is
+cutting its valley. Thus, wherever a stream leaves harder rocks to
+flow over softer ones the latter are quickly worn below the level
+of the former, and a sharp change in slope, with a waterfall or
+rapid, results.
+
+At time of flood young tributaries with steeper courses than that
+of the trunk stream may bring down stones and finer waste, which
+the gentler current cannot move along, and throw them as a dam
+across its way. The rapids thus formed are also ephemeral, for as
+the gradient of the tributaries is lowered the main stream becomes
+able to handle the smaller and finer load which they discharge.
+
+A rare class of falls is produced where the minor tributaries of a
+young river are not able to keep pace with their master stream in
+the erosion of their beds because of their smaller volume, and
+thus join it by plunging over the side of its gorge. But as the
+river approaches grade and slackens its down cutting, the
+tributaries sooner or later overtake it, and effacing their falls,
+unite with it on a level.
+
+Waterfalls and rapids of all kinds are evanescent features of a
+river's youth. Like lakes they are soon destroyed, and if any long
+time had already elapsed since their formation they would have
+been obliterated already.
+
+LOCAL BASELEVELS. That balanced condition called grade, where a
+river neither degrades its bed by erosion nor aggrades it by
+deposition, is first attained along reaches of soft rocks,
+ungraded outcrops of hard rocks remaining as barriers which give
+rise to rapids or falls. Until these barriers are worn away they
+constitute local baselevels, below which level the stream, up
+valley from them, cannot cut. They are eroded to grade one after
+another, beginning with the least strong, or the one nearest the
+mouth of the stream. In a similar way the surface of a lake in a
+river's course constitutes for all inflowing streams a local
+baselevel, which disappears when the basin is filled or drained.
+
+MATURE AND OLD RIVERS
+
+Maturity is the stage of a river's complete development and most
+effective work. The river system now has well under way its great
+task of wearing down the land mass which it drains and carrying it
+particle by particle to the sea. The relief of the land is now at
+its greatest; for the main channels have been sunk to grade, while
+the divides remain but little worn below their initial altitudes.
+Ground water now stands low. The run-off washes directly to the
+streams, with the least delay and loss by evaporation in ponds and
+marches; the discharge of the river is therefore at its height.
+The entire region is dissected by stream ways. The area of valley
+slopes is now largest and sheds to the streams a heavier load of
+waste than ever before. At maturity the river system is doing its
+greatest amount of work both in erosion and in the carriage of
+water and of waste to the sea.
+
+LATERAL EROSION. On reaching grade a river ceases to scour its
+bed, and it does not again begin to do so until some change in
+load or volume enables it to find grade at a lower level. On the
+other hand, a stream erodes its banks at all stages in its
+history, and with graded rivers this process, called lateral
+erosion, or PLANATION, is specially important. The current of a
+stream follows the outer side of all curves or bends in the
+channel, and on this side it excavates its bed the deepest and
+continually wears and saps its banks. On the inner side deposition
+takes place in the more shallow and slower-moving water. The inner
+bank of bends is thus built out while the outer bank is worn away.
+By swinging its curves against the valley sides a graded river
+continually cuts a wider and wider floor. The V-valley of youth is
+thus changed by planation to a flat-floored valley with flaring
+sides which gradually become subdued by the weather to gentle
+slopes. While widening their valleys streams maintain a constant
+width of channel, so that a wide-floored valley does not signify
+that it ever was occupied by a river of equal width.
+
+THE GRADIENT. The gradients of graded rivers differ widely. A
+large river with a light load reaches grade on a faint slope,
+while a smaller stream heavily burdened with waste requires a
+steep slope to give it velocity sufficient to move the load.
+
+The Platte, a graded river of Nebraska with its headwaters in the
+Rocky Mountains, is enfeebled by the semi-arid climate of the
+Great Plains and surcharged with the waste brought down both by
+its branches in the mountains and by those whose tracks lie over
+the soft rocks of the plains. It is compelled to maintain a
+gradient of eight feet to the mile in western Nebraska. The Ohio
+reaches grade with a slope of less than four inches to the mile
+from Cincinnati to its mouth, and the powerful Mississippi washes
+along its load with a fall of but three inches per mile from Cairo
+to the Gulf.
+
+Other things being equal, which of graded streams will have the
+steeper gradient, a trunk stream or its tributaries? a stream
+supplied with gravel or one with silt?
+
+Other factors remaining the same, what changes would occur if the
+Platte should increase in volume? What changes would occur if the
+load should be increased in amount or in coarseness?
+
+THE OLD AGE OF RIVERS. As rivers pass their prime, as denudation
+lowers the relief of the region, less waste and finer is washed
+over the gentler slopes of the lowering hills. With smaller loads
+to carry, the rivers now deepen their valleys and find grade with
+fainter declivities nearer the level of the sea. This limit of the
+level of the sea beneath which they cannot erode is known as
+baselevel. [Footnote: The term "baselevel" is also used to
+designate the close approximation to sea level to which streams
+are able to subdue the land.] As streams grow old they approach
+more and more closely to baselevel, although they are never able
+to attain it. Some slight slope is needed that water may flow and
+waste be transported over the land. Meanwhile the relief of the
+land has ever lessened. The master streams and their main
+tributaries now wander with sluggish currents over the broad
+valley floors which they have planed away; while under the erosion
+of their innumerable branches and the wear of the weather the
+divides everywhere are lowered and subdued to more and more gentle
+slopes. Mountains and high plateaus are thus reduced to rolling
+hills, and at last to plains, surmounted only by such hills as may
+still be unreduced to the common level, because of the harder
+rocks of which they are composed or because of their distance from
+the main erosion channels. Such regions of faint relief, worn down
+to near base level by subaerial agencies, are known as PENEPLAINS
+(almost plains). Any residual masses which rise above them are
+called MONADNOCKS, from the name of a conical peak of New
+Hampshire which overlooks the now uplifted peneplain of southern
+New England.
+
+In its old age a region becomes mantled with thick sheets of fine
+and weathered waste, slowly moving over the faint slopes toward
+the water ways and unbroken by ledges of bare rock. In other
+words, the waste mantle also is now graded, and as waterfalls have
+been effaced in the river beds, so now any ledges in the wide
+streams of waste are worn away and covered beneath smooth slopes
+of fine soil. Ground water stands high and may exude in areas of
+swamp. In youth the land mass was roughhewn and cut deep by stream
+erosion. In old age the faint reliefs of the land dissolve away,
+chiefly under the action of the weather, beneath their cloak of
+waste.
+
+THE CYCLE OF EROSION. The successive stages through which a land
+mass passes while it is being leveled to the sea constitute
+together a cycle of erosion. Each stage of the cycle from infancy
+to old age leaves, as we have seen, its characteristic records in
+the forms sculptured on the land, such as the shapes of valleys
+and the contours of hills and plains. The geologist is thus able
+to determine by the land forms of any region the stage in the
+erosion cycle to which it now belongs, and knowing what are the
+earlier stages of the cycle, to read something of the geological
+history of the region.
+
+INTERRUPTED CYCLES. So long a time is needed to reduce a land mass
+to baselevel that the process is seldom if ever completed during a
+single uninterrupted cycle of erosion. Of all the various
+interruptions which may occur the most important are gradual
+movements of the earth's crust, by which a region is either
+depressed or elevated relative to sea level.
+
+The DEPRESSION of a region hastens its old age by decreasing the
+gradient of streams, by destroying their power to excavate their
+beds and carry their loads to a degree corresponding to the amount
+of the depression, and by lessening the amount of work they have
+to do. The slackened river currents deposit their waste in Hood
+plains which increase in height as the subsidence continues. The
+lower courses of the rivers are invaded by the sea and become
+estuaries, while the lower tributaries are cut off from the trunk
+stream.
+
+ELEVATION, on the other hand, increases the activity of all
+agencies of weathering, erosion, and transportation, restores the
+region to its youth, and inaugurates a new cycle of erosion.
+Streams are given a steeper gradient, greater velocity, and
+increased energy to carry their loads and wear their beds. They
+cut through the alluvium of their flood plains, leaving it on
+either bank as successive terraces, and intrench themselves in the
+underlying rock. In their older and wider valleys they cut narrow,
+steep-walled inner gorges, in which they flow swiftly over rocky
+floors, broken here and there by falls and rapids where a harder
+layer of rock has been discovered. Winding streams on plains may
+thus incise their meanders in solid rock as the plains are
+gradually uplifted. Streams which are thus restored to their youth
+are said to be REVIVED.
+
+As streams cut deeper and the valley slopes are steepened, the
+mantle of waste of the region undergoing elevation is set in more
+rapid movement. It is now removed particle by particle faster than
+it forms. As the waste mantle thins, weathering attacks the rocks
+of the region more energetically until an equilibrium is reached
+again; the rocks waste rapidly and their waste is as rapidly
+removed.
+
+DISSECTED PENEPLAINS. When a rise of the land brings one cycle to
+an end and begins another, the characteristic land forms of each
+cycle are found together and the topography of the region is
+composite until the second cycle is so far advanced that the land
+forms of the first cycle are entirely destroyed. The contrast
+between the land surfaces of the later and the earlier cycles is
+most striking when the earlier had advanced to age and the later
+is still in youth. Thus many peneplains which have been elevated
+and dissected have been recognized by the remnants of their
+ancient erosion surfaces, and the length of time which has elapsed
+since their uplift has been measured by the stage to which the new
+cycle has advanced.
+
+THE PIEDMONT BELT. As an example of an ancient peneplain uplifted
+and dissected we may cite the Piedmont Belt, a broad upland lying
+between the Appalachian Mountains and the Atlantic coastal plain.
+The surface of the Piedmont is gently rolling. The divides, which
+are often smooth areas of considerable width, rise to a common
+plane, and from them one sees in every direction an even sky line
+except where in places some lone hill or ridge may lift itself
+above the general level (Fig. 62). The surface is an ancient one,
+for the mantle of residual waste lies deep upon it, soils are
+reddened by long oxidation, and the rocks are rotted to a depth of
+scores of feet.
+
+At present, however, the waste mantle is not forming so rapidly as
+it is being removed. The streams of the upland are actively
+engaged in its destruction. They flow swiftly in narrow, rock-
+walled valleys over rocky beds. This contrast between the young
+streams and the aged surface which they are now so vigorously
+dissecting can only be explained by the theory that the region
+once stood lower than at present and has recently been upraised.
+If now we imagine the valleys refilled with the waste which the
+streams have swept away, and the upland lowered, we restore the
+Piedmont region to the condition in which it stood before its
+uplift and dissection,--a gently rolling plain, surmounted here
+and there by isolated hills and ridges.
+
+The surface of the ancient Piedmont plain, as it may be restored
+from the remnants of it found on the divides, is not in accordance
+with the structures of the country rocks. Where these are exposed
+to view they are seen to be far from horizontal. On the walls of
+river gorges they dip steeply and in various directions and the
+streams flow over their upturned edges. As shown in Figure 67, the
+rocks of the Piedmont have been folded and broken and tilted.
+
+It is not reasonable to believe that when the rocks of the
+Piedmont were thus folded and otherwise deformed the surface of
+the region was a plain. The upturned layers have not always
+stopped abruptly at the even surface of the Piedmont plain which
+now cuts across them. They are the bases of great folds and tilted
+blocks which must once have risen high in air. The complex and
+disorderly structures of the Piedmont rocks are those seen in
+great mountain ranges, and there is every reason to believe that
+these rocks after their deformation rose to mountain height.
+
+The ancient Piedmont plain cuts across these upturned rocks as
+independently of their structure as the even surface of the sawed
+stump of some great tree is independent of the direction of its
+fibers. Hence the Piedmont plain as it was before its uplift was
+not a coastal plain formed of strata spread in horizontal sheets
+beneath the sea and then uplifted; nor was it a structural plain,
+due to the resistance to erosion of some hard, flat-lying layer of
+rock. Even surfaces developed on rocks of discordant structure,
+such as the Piedmont shows, are produced by long denudation, and
+we may consider the Piedmont as a peneplain formed by the wearing
+down of mountain ranges, and recently uplifted.
+
+THE LAURENTIAN PENEPLAIN. This is the name given to a denuded
+surface on very ancient rocks which extends from the Arctic Ocean
+to the St. Lawrence River and Lake Superior, with small areas also
+in northern Wisconsin and New York. Throughout this U-shaped area,
+which incloses Hudson Bay within its arms, the country rocks have
+the complicated and contorted structures which characterize
+mountain ranges. But the surface of the area is by no means
+mountainous. The sky line when viewed from the divides is unbroken
+by mountain peaks or rugged hills. The surface of the arm west of
+Hudson Bay is gently undulating and that of the eastern arm has
+been roughened to low-rolling hills and dissected in places by
+such deep river gorges as those of the Ottawa and Saguenay. This
+immense area may be regarded as an ancient peneplain truncating
+the bases of long-vanished mountains and dissected after
+elevation.
+
+In the examples cited the uplift has been a broad one and to
+comparatively little height. Where peneplains have been uplifted
+to great height and have since been well dissected, and where they
+have been upfolded and broken and uptilted, their recognition
+becomes more difficult. Yet recent observers have found evidences
+of ancient lowland surfaces of erosion on the summits of the
+Allegheny ridges, the Cascade Mountains (Fig. 69), and the western
+slope of the Sierra Nevadas.
+
+THE SOUTHERN APPALACHIAN REGION. We have here an example of an
+area the latter part of whose geological history may be deciphered
+by means of its land forms. The generalized section of Figure 70,
+which passes from west to east across a portion of the region in
+eastern Tennessee, shows on the west a part of the broad
+Cumberland plateau. On the east is a roughened upland platform,
+from which rise in the distance the peaks of the Great Smoky
+Mountains. The plateau, consisting of strata but little changed
+from their original flat-lying attitude, and the platform,
+developed on rocks of disordered structure made crystalline by
+heat and pressure, both stand at the common level of the line AB.
+They are separated by the Appalachian valley, forty miles wide,
+cut in strata which have been folded and broken into long narrow
+blocks. The valley is traversed lengthwise by long, low ridges,
+the outcropping edges of the harder strata, which rise to about
+the same level,--that of the line cd. Between these ridges stretch
+valley lowlands at the level ef excavated in the weaker rocks,
+while somewhat below them lie the channels of the present streams
+now busily engaged in deepening their beds.
+
+THE VALLEY LOWLANDS. Were they planed by graded or ungraded
+streams? Have the present streams reached grade? Why did the
+streams cease widening the floors of the valley lowlands? How long
+since? When will they begin anew the work of lateral planation?
+What effect will this have on the ridges if the present cycle of
+erosion continues long uninterrupted?
+
+THE RIDGES OF THE APPALACHIAN VALLEY. Why do they stand above the
+valley lowlands? Why do their summits lie in about the same plane?
+Refilling the valleys intervening between these ridges with the
+material removed by the streams, what is the nature of the surface
+thus restored? Does this surface cd accord with the rock
+structures on which' it has been developed? How may it have been
+made? At what height did the land stand then, compared with its
+present height? What elevations stood above the surface cd? Why?
+What name may you use to designate them? How does the length of
+time needed to develop the surface cd compare with that needed to
+develop the valley lowlands?
+
+THE PLATFORM AND PLATEAU. Why do they stand at a common level ab?
+Of what surface may they be remnants? Is it accordant with the
+rock structure? How was it produced? What unconsumed masses
+overlooked it? Did the rocks of the Appalachian valley stand above
+this surface when it was produced? Did they then stand below it?
+Compare the time needed to develop this surface with that needed
+to develop cd. Which surface is the older?
+
+How many cycles of erosion are represented here? Give the erosion
+history of the region by cycles, beginning with the oldest, the
+work done in each and the work left undone, what brought each
+cycle to a close, and how long relatively it continued.
+
+
+
+
+
+CHAPTER IV
+
+RIVER DEPOSITS
+
+
+The characteristic features of river deposits and the forms which
+they assume may be treated under three heads: (1) valley deposits,
+(2) basin deposits, and (3) deltas.
+
+VALLEY DEPOSITS
+
+FLOOD PLAINS are the surfaces of the alluvial deposits which
+streams build along their courses at times of flood. A swift
+current then sweeps along the channel, while a shallow sheet of
+water moves slowly over the flood plain, spreading upon it a thin
+layer of sediment. It has been estimated that each inundation of
+the Nile leaves a layer of fertilizing silt three hundredths of an
+inch thick over the flood plain of Egypt.
+
+Flood plains may consist of a thin spread of alluvium over the
+flat rock floor of a valley which is being widened by the lateral
+erosion of a graded stream (Fig. 60). Flood-plain deposits of
+great thickness may be built by aggrading rivers even in valleys
+whose rock floors have never been thus widened.
+
+A cross section of a flood plain shows that it is highest next the
+river, sloping gradually thence to the valley sides. These wide
+natural embankments are due to the fact that the river deposit is
+heavier near the bank, where the velocity of the silt-laden
+channel current is first checked by contact with the slower-moving
+overflow.
+
+Thus banked off from the stream, the outer portions of a flood
+plain are often ill-drained and swampy, and here vegetal deposits,
+such as peat, may be interbedded with river silts.
+
+A map of a wide flood plain, such as that of the Mississippi or
+the Missouri (Fig. 77), shows that the courses of the tributaries
+on entering it are deflected downstream. Why?
+
+The aggrading streams by which flood plains are constructed
+gradually build their immediate banks and beds to higher and
+higher levels, and therefore find it easy at times of great floods
+to break their natural embankments and take new courses over the
+plain. In this way they aggrade each portion of it in turn by
+means of their shifting channels,
+
+BRAIDED CHANNELS. A river actively engaged in aggrading its valley
+with coarse waste builds a flood plain of comparatively steep
+gradient and often flows down it in a fairly direct course and
+through a network of braided channels. From time to time a channel
+becomes choked with waste, and the water no longer finding room in
+it breaks out and cuts and builds itself a new way which reunites
+down valley with the other channels. Thus there becomes
+established a network of ever-changing channels inclosing low
+islands of sand and gravel.
+
+TERRACES. While aggrading streams thus tend to shift their
+channels, degrading streams, on the contrary, become more and more
+deeply intrenched in their valleys. It often occurs that a stream,
+after having built a flood plain, ceases to aggrade its bed
+because of a lessened load or for other reasons, such as an uplift
+of the region, and begins instead to degrade it. It leaves the
+original flood plain out of reach of even the highest floods. When
+again it reaches grade at a lower level it produces a new flood
+plain by lateral erosion in the older deposits, remnants of which
+stand as terraces on one or both sides of the valley. In this way
+a valley may be lined with a succession of terraces at different
+levels, each level representing an abandoned flood plain.
+
+MEANDERS. Valleys aggraded with fine waste form well-nigh level
+plains over which streams wind from side to side of a direct
+course in symmetric bends known as meanders, from the name of a
+winding river of Asia Minor. The giant Mississippi has developed
+meanders with a radius of one and one half miles, but a little
+creek may display on its meadow as perfect curves only a rod or so
+in radius. On the flood plain of either river or creek we may find
+examples of the successive stages in the development of the
+meander, from its beginning in the slight initial bend sufficient
+to deflect the current against the outer side. Eroding here and
+depositing on the inner side of the bend, it gradually reaches
+first the open bend whose width and length are not far from equal,
+and later that of the horseshoe meander whose diameter transverse
+to the course of the stream is much greater than that parallel
+with it. Little by little the neck of land projecting into the
+bend is narrowed, until at last it is cut through and a "cut-off"
+is established. The old channel is now silted up at both ends and
+becomes a crescentic lagoon, or oxbow lake, which fills gradually
+to an arc-shaped shallow depression.
+
+FLOOD PLAINS CHARACTERISTIC OF MATURE RIVERS. On reaching grade a
+stream planes a flat floor for its continually widening valley.
+Ever cutting on the outer bank of its curves, it deposits on the
+inner bank scroll-like flood-plain patches. For a while the valley
+bluffs do not give its growing meanders room to develop to their
+normal size, but as planation goes on, the bluffs are driven back
+to the full width of the meander belt and still later to a width
+which gives room for broad stretches of flood plain on either
+side.
+
+Usually a river first attains grade near its mouth, and here first
+sinks its bed to near baselevel. Extending its graded course
+upstream by cutting away barrier after barrier, it comes to have a
+widened and mature valley over its lower course, while its young
+headwaters are still busily eroding their beds. Its ungraded
+branches may thus bring down to its lower course more waste than
+it is competent to carry on to the sea, and here it aggrades its
+bed and builds a flood plain in order to gain a steeper gradient
+and velocity enough to transport its load.
+
+As maturity is past and the relief of the land is lessened, a
+smaller and smaller load of waste is delivered to the river. It
+now has energy to spare and again degrades its valley, excavating
+its former flood plains and leaving them in terraces on either
+side, and at last in its old age sweeping them away.
+
+ALLUVIAL CONES AND FANS. In hilly and mountainous countries one
+often sees on a valley side a conical or fan-shaped deposit of
+waste at the mouth of a lateral stream. The cause is obvious: the
+young branch has not been able as yet to wear its bed to accordant
+level with the already deepened valley of the master stream. It
+therefore builds its bed to grade at the point of juncture by
+depositing here its load of waste,--a load too heavy to be carried
+along the more gentle profile of the trunk valley.
+
+Where rivers descend from a mountainous region upon the plain they
+may build alluvial fans of exceedingly gentle slope. Thus the
+rivers of the western side of the Sierra Nevada Mountains have
+spread fans with a radius of as much as forty miles and a slope
+too slight to be detected without instruments, where they leave
+the rock-cut canyons in the mountains and descend upon the broad
+central valley of California.
+
+As a river flows over its fan it commonly divides into a
+branchwork of shifting channels called DISTRIBUTARIES, since they
+lead off the water from the main stream. In this way each part of
+the fan is aggraded and its symmetric form is preserved.
+
+PIEDMONT PLAINS. Mountain streams may build their confluent fans
+into widespread piedmont (foot of the mountain) alluvial plains.
+These are especially characteristic of arid lands, where the
+streams wither as they flow out upon the thirsty lowlands and are
+therefore compelled to lay down a large portion of their load. In
+humid climates mountain-born streams are usually competent to
+carry their loads of waste on to the sea, and have energy to spare
+to cut the lower mountain slopes into foothills. In arid regions
+foothills are commonly absent and the ranges rise, as from
+pedestals, above broad, sloping plains of stream-laid waste.
+
+THE HIGH PLAINS. The rivers which flow eastward from the Rocky
+Mountains have united their fans in a continuous sheet of waste
+which stretches forward from the base of the mountains for
+hundreds of miles and in places is five hundred feet thick (Fig.
+80). That the deposit was made in ancient times on land and not in
+the sea is proved by the remains which it contains of land animals
+and plants of species now extinct. That it was laid by rivers and
+not by fresh-water lakes is shown by its structure. Wide stretches
+of flat-lying, clays and sands are interrupted by long, narrow
+belts of gravel which mark the channels of the ancient streams.
+Gravels, and sands are often cross bedded, and their well worn
+pebbles may be identified with the rocks of the mountains. After
+building this sheet of waste the streams ceased to aggrade and
+began the work of destruction. Large uneroded remnants, their
+surfaces flat as a floor, remain as the High Plains of western
+Kansas and Nebraska.
+
+RIVER DEPOSITS IN SUBSIDING TROUGHS. To a geologist the most
+important river deposits are those which gather in areas of
+gradual subsidence; they are often of vast extent and immense
+thickness, and such deposits of past geological ages have not
+infrequently been preserved, with all their records of the times
+in which they were built, by being carried below the level of the
+sea, to be brought to light by a later uplift. On the other hand,
+river deposits which remain above baselevels of erosion are swept
+away comparatively soon.
+
+THE GREAT VALLEY OF CALIFORNIA is a monotonously level plain of
+great fertility, four hundred miles in length and fifty miles in
+average width, built of waste swept down by streams from the
+mountain ranges which inclose it,--the Sierra Nevada on the east
+and the Coast Range on the west. On the waste slopes at the foot
+of the bordering hills coarse gravels and even bowlders are left,
+while over the interior the slow-flowing streams at times of
+flood spread wide sheets of silt. Organic deposits are now forming
+by the decay of vegetation in swampy tule (reed) lands and in
+shallow lakes which occupy depressions left by the aggrading
+streams.
+
+Deep borings show that this great trough is filled to a depth of
+at least two thousand feet below sea level with recent
+unconsolidated sands and silts containing logs of wood and fresh-
+water shells. These are land deposits, and the absence of any
+marine deposits among them proves that the region has not been
+invaded by the sea since the accumulation began. It has therefore
+been slowly subsiding and its streams, although continually
+carried below grade, have yet been able to aggrade the surface as
+rapidly as the region sank, and have maintained it, as at present,
+slightly above sea level.
+
+THE INDO-GANGETIC PLAIN, spread by the Brahmaputra, the Ganges,
+and the Indus river systems, stretches for sixteen hundred miles
+along the southern base of the Himalaya Mountains and occupies an
+area of three hundred thousand square miles (Fig.342). It consists
+of the flood plains of the master streams and the confluent fans
+of the tributaries which issue from the mountains on the north.
+Large areas are subject to overflow each season of flood, and
+still larger tracts mark abandoned flood plains below which the
+rivers have now cut their beds. The plain is built of far-
+stretching beds of clay, penetrated by streaks of sand, and also
+of gravel near the mountains. Beds of impure peat occur in it, and
+it contains fresh-water shells and the bones of land animals of
+species now living in northern India. At Lucknow an artesian well
+was sunk to one thousand feet below sea level without reaching the
+bottom of these river-laid sands and silts, proving a slow
+subsidence with which the aggrading rivers have kept pace.
+
+WARPED VALLEYS. It is not necessary that an area should sink below
+sea level in order to be filled with stream-swept waste. High
+valleys among growing mountain ranges may suffer warping, or may
+be blockaded by rising mountain folds athwart them. Where the
+deformation is rapid enough, the river may be ponded and the
+valley filled with lake-laid sediments. Even when the river is
+able to maintain its right of way it may yet have its declivity so
+lessened that it is compelled to aggrade its course continually,
+filling the valley with river deposits which may grow to an
+enormous thickness.
+
+Behind the outer ranges of the Himalaya Mountains lie several
+waste-filled valleys, the largest of which are Kashmir and Nepal,
+the former being an alluvial plain about as large as the state of
+Delaware. The rivers which drain these plains have already cut
+down their outlet gorges sufficiently to begin the task of the
+removal of the broad accumulations which they have brought in from
+the surrounding mountains. Their present flood plains lie as much
+as some hundreds of feet below wide alluvial terraces which mark
+their former levels. Indeed, the horizontal beds of the Hundes
+Valley have been trenched to the depth of nearly three thousand
+feet by the Sutlej River. These deposits are recent or subrecent,
+for there have been found at various levels the remains of land
+plants and land and fresh-water shells, and in some the bones of
+such animals as the hyena and the goat, of species or of genera
+now living. Such soft deposits cannot be expected to endure
+through any considerable length of future time the rapid erosion
+to which their great height above the level of the sea will
+subject them.
+
+CHARACTERISTICS OF RIVER DEPOSITS. The examples just cited teach
+clearly the characteristic features of extensive river deposits.
+These deposits consist of broad, flat-lying sheets of clay and
+fine sand left by the overflow at time of flood, and traversed
+here and there by long, narrow strips of coarse, cross-bedded
+sands and gravels thrown down by the swifter currents of the
+shifting channels. Occasional beds of muck mark the sites of
+shallow lakelets or fresh-water swamps. The various strata also
+contain some remains of the countless myriads of animals and
+plants which live upon the surface of the plain as it is in
+process of building. River shells such as the mussel, land shells
+such as those of snails, the bones of fishes and of such land
+animals as suffer drowning at times of flood or are mired in
+swampy places, logs of wood, and the stems and leaves of plants
+are examples of the variety of the remains of land and fresh-water
+organisms which are entombed in river deposits and sealed away as
+a record of the life of the time, and as proof that the deposits
+were laid by streams and not beneath the sea.
+
+BASIN DEPOSITS
+
+DEPOSITS IN DRY BASINS. On desert areas without outlet to the sea,
+as on the Great Basin of the United States and the deserts of
+central Asia, stream-swept waste accumulates indefinitely. The
+rivers of the surrounding mountains, fed by the rains and melting
+snows of these comparatively moist elevations, dry and soak away
+as they come down upon the arid plains. They are compelled to lay
+aside their entire load of waste eroded from the mountain valleys,
+in fans which grow to enormous size, reaching in some instances
+thousands of feet in thickness.
+
+The monotonous levels of Turkestan include vast alluvial tracts
+now in process of building by the floods of the frequently
+shifting channels of the Oxus and other rivers of the region. For
+about seven hundred miles from its mouth in Aral Lake the Oxus
+receives no tributaries, since even the larger branches of its
+system are lost in a network of distributaries and choked with
+desert sands before they reach their master stream. These
+aggrading rivers, which have channels but no valleys, spread their
+muddy floods--which in the case of the Oxus sometimes equal the
+average volume of the Mississippi--far and wide over the plain,
+washing the bases of the desert dunes.
+
+PLAYAS. In arid interior basins the central depressions may be
+occupied by playas,--plains of fine mud washed forward from the
+margins. In the wet season the playa is covered with a thin sheet
+of muddy water, a playa lake, supplied usually by some stream at
+flood. In the dry season the lake evaporates, the river which fed
+it retreats, and there is left to view a hard, smooth, level floor
+of sun-baked and sun-cracked yellow clay utterly devoid of
+vegetation.
+
+In the Black Rock desert of Nevada a playa lake spreads over an
+area fifty miles long and twenty miles wide. In summer it
+disappears; the Quinn River, which feeds it, shrinks back one
+hundred miles toward its source, leaving an absolutely barren
+floor of clay, level as the sea.
+
+LAKE DEPOSITS. Regarding lakes as parts of river systems, we may
+now notice the characteristic features of the deposits in lake
+basins. Soundings in lakes of considerable size and depth show
+that their bottoms are being covered with tine clays. Sand and
+gravel are found along; their margins, being brought in by streams
+and worn by waves from the shore, but there are no tidal or other
+strong currents to sweep coarse waste out from shore to any
+considerable distance. Where fine clays are now found on the land
+in even, horizontal layers containing the remains of fresh-water
+animals and plants, uncut by channels tilled with cross-bedded
+gravels and sands and bordered by beach deposits of coarse waste,
+we may safely infer the existence of ancient lakes.
+
+MARL. Marl is a soft, whitish deposit of carbonate of lime,
+mingled often with more or less of clay, accumulated in small
+lakes whose feeding springs are charged with carbonate of lime and
+into which little waste is washed from the land. Such lakelets are
+not infrequent on the surface of the younger drift sheets of
+Michigan and northern Indiana, where their beds of marl--sometimes
+as much as forty feet thick--are utilized in the manufacture of
+Portland cement. The deposit results from the decay of certain
+aquatic plants which secrete lime carbonate from the water, from
+the decomposition of the calcareous shells of tiny mollusks which
+live in countless numbers on the lake floor, and in some cases
+apparently from chemical precipitation.
+
+PEAT. We have seen how lakelets are extinguished by the decaying
+remains of the vegetation which they support. A section of such a
+fossil lake shows that below the growing mosses and other plants
+of the surface of the bog lies a spongy mass composed of dead
+vegetable tissue, which passes downward gradually into PEAT,--a
+dense, dark brown carbonaceous deposit in which, to the unaided
+eye, little or no trace of vegetable structure remains. When
+dried, peat forms a fuel of some value and is used either cut into
+slabs and dried or pressed into bricks by machinery.
+
+When vegetation decays in open air the carbon of its tissues,
+taken from the atmosphere by the leaves, is oxidized and returned
+to it in its original form of carbon dioxide. But decomposing in
+the presence of water, as in a bog, where the oxygen of the air is
+excluded, the carbonaceous matter of plants accumulates in
+deposits of peat.
+
+Peat bogs are numerous in regions lately abandoned by glacier ice,
+where river systems are so immature that the initial depressions
+left in the sheet of drift spread over the country have not yet
+been drained. One tenth of the surface of Ireland is said to be
+covered with peat, and small bogs abound in the drift-covered area
+of New England and the states lying as far west as the Missouri
+River. In Massachusetts alone it has been reckoned that there are
+fifteen billion cubic feet of peat, the largest bog occupying
+several thousand acres.
+
+Much larger swamps occur on the young coastal plain of the
+Atlantic from New Jersey to Florida. The Dismal Swamp, for
+example, in Virginia and North Carolina is forty miles across. It
+is covered with a dense growth of water-loving trees such as the
+cypress and black gum. The center of the swamp is occupied by Lake
+Drummond, a shallow lake seven miles in diameter, with banks of
+pure-peat, and still narrowing from the encroachment of vegetation
+along its borders.
+
+SALT LAKES. In arid climates a lake rarely receives sufficient
+inflow to enable it to rise to the basin rim and find an outlet.
+Before this height is reached its surface becomes large enough to
+discharge by evaporation into the dry air the amount of water that
+is supplied by streams. As such a lake has no outlet, the minerals
+in solution brought into it by its streams cannot escape from the
+basin. The lake water becomes more and more heavily charged with
+such substances as common salt and the sulphates and carbonates of
+lime, of soda, and of potash, and these are thrown down from
+solution one after another as the point of saturation for each
+mineral is reached. Carbonate of lime, the least soluble and often
+the most abundant mineral brought in, is the first to be
+precipitated. As concentration goes on, gypsum, which is insoluble
+in a strong brine, is deposited, and afterwards common salt. As
+the saltness of the lake varies with the seasons and with climatic
+changes, gypsum and salt are laid in alternate beds and are
+interleaved with sedimentary clays spread from the waste brought
+in by streams at times of flood. Few forms of life can live in
+bodies of salt water so concentrated that chemical deposits take
+place, and hence the beds of salt, gypsum, and silt of such lakes
+are quite barren of the remains of life. Similar deposits are
+precipitated by the concentration of sea water in lagoons and arms
+of the sea cut off from the ocean.
+
+LAKES BONNEVILLE AND LAHONTAN. These names are given to extinct
+lakes which once occupied large areas in the Great Basin, the
+former in Utah, the latter in northwestern Nevada. Their records
+remain in old horizontal beach lines which they drew along their
+mountainous shores at the different levels at which they stood,
+and in the deposits of their beds. At its highest stage Lake
+Bonneville, then one thousand feet deep, overflowed to the north
+and was a fresh-water lake. As it shrank below the outlet it
+became more and more salty, and the Great Salt Lake, its withered
+residue, is now depositing salt along its shores. In its strong
+brine lime carbonate is insoluble, and that brought in by streams
+is thrown down at once in the form of travertine.
+
+Lake Lahontan never had an outlet. The first chemical deposits to
+be made along its shores were deposits of travertine, in places
+eighty feet thick. Its floor is spread with fine clays, which must
+have been laid in deep, still water, and which are charged with
+the salts absorbed by them as the briny water of the lake dried
+away. These sedimentary clays are in two divisions, the upper and
+lower, each being about one hundred feet thick. They are separated
+by heavy deposits of well-rounded, cross-bedded gravels and sands,
+similar to those spread at the present time by the intermittent
+streams of arid regions. A similar record is shown in the old
+floors of Lake Bonneville. What conclusions do you draw from these
+facts as to the history of these ancient lakes?
+
+DELTAS
+
+In the river deposits which are left above sea level particles of
+waste are allowed to linger only for a time. From alluvial fans
+and flood plains they are constantly being taken up and swept
+farther on downstream. Although these land forms may long persist,
+the particles which compose them are ever changing. We may
+therefore think of the alluvial deposits of a valley as a stream
+of waste fed by the waste mantle as it creeps and washes down the
+valley sides, and slowly moving onwards to the sea.
+
+In basins waste finds a longer rest, but sooner or later lakes and
+dry basins are drained or filled, and their deposits, if above sea
+level, resume their journey to their final goal. It is only when
+carried below the level of the sea that they are indefinitely
+preserved.
+
+On reaching this terminus, rivers deliver their load to the ocean.
+In some cases the ocean is able to take it up by means of strong
+tidal and other currents, and to dispose of it in ways which we
+shall study later. But often the load is so large, or the tides
+are so weak, that much of the waste which the river brings in
+settles at its mouth, there building up a deposit called the
+DELTA, from the Greek letter of that name, whose shape it
+sometimes resembles.
+
+Deltas and alluvial fans have many common characteristics. Both
+owe their origin to a sudden check in the velocity of the river,
+compelling a deposit of the load; both are triangular in outline,
+the apex pointing upstream; and both are traversed by
+distributaries which build up all parts in turn.
+
+In a delta we may distinguish deposits of two distinct kinds,--
+the submarine and the subaerial. In part a delta is built of waste
+brought down by the river and redistributed and spread by waves
+and tides over the sea bottom adjacent to the river's mouth. The
+origin of these deposits is recorded in the remains of marine
+animals and plants which they contain.
+
+As the submarine delta grows near to the level of the sea the
+distributaries of the river cover it with subaerial deposits
+altogether similar to those of the flood plain, of which indeed
+the subaerial delta is the prolongation. Here extended deposits of
+peat may accumulate in swamps, and the remains of land and fresh-
+water animals and plants swept down by the stream are imbedded in
+the silts laid at times of flood.
+
+Borings made in the deltas of great rivers such as the
+Mississippi, the Ganges, and the Nile, show that the subaerial
+portion often reaches a surprising thickness. Layers of peat, old
+soils, and forest grounds with the stumps of trees are discovered
+hundreds of feet below sea level. In the Nile delta some eight
+layers of coarse gravel were found interbedded with river silts,
+and in the Ganges delta at Calcutta a boring nearly five hundred
+feet in depth stopped in such a layer.
+
+The Mississippi has built a delta of twelve thousand three hundred
+square miles, and is pushing the natural embankments of its chief
+distributaries into the Gulf at a maximum rate of a mile in
+sixteen years. Muddy shoals surround its front, shallow lakes,
+e.g. lakes Pontchartrain and Borgne, are formed between the
+growing delta and the old shore line, and elongate lakes and
+swamps are inclosed between the natural embankments of the
+distributaries.
+
+The delta of the Indus River, India, lies so low along shore that
+a broad tract of country is overflowed by the highest tides. The
+submarine portion of the delta has been built to near sea level
+over so wide a belt offshore that in many places large vessels
+cannot come even within sight of land because of the shallow
+water.
+
+A former arm of the sea, the Rann of Cutch, adjoining the delta on
+the east has been silted up and is now an immense barren flat of
+sandy mud two hundred miles in length and one hundred miles in
+greatest breadth. Each summer it is flooded with salt water when
+the sea is brought in by strong southwesterly monsoon winds, and
+the climate during the remainder of the year is hot and dry. By
+the evaporation of sea water the soil is thus left so salty that
+no vegetation can grow upon it, and in places beds of salt several
+feet in thickness have accumulated. Under like conditions salt
+beds of great thickness have been formed in the past and are now
+found buried among the deposits of ancient deltas.
+
+SUBSIDENCE OF GREAT DELTAS. As a rule great deltas are slowly
+sinking. In some instances upbuilding by river deposits has gone
+on as rapidly as the region has subsided. The entire thickness of
+the Ganges delta, for example, so far as it has been sounded,
+consists of deposits laid in open air. In other cases interbedded
+limestones and other sedimentary rocks containing marine fossils
+prove that at times subsidence has gained on the upbuilding and
+the delta has been covered with the sea.
+
+It is by gradual depression that delta deposits attain enormous
+thickness, and, being lowered beneath the level of the sea, are
+safely preserved from erosion until a movement of the earth's
+crust in the opposite direction lifts them to form part of the
+land. We shall read later in the hard rocks of our continent the
+records of such ancient deltas, and we shall not be surprised to
+find them as thick as are those now building at the mouths of
+great rivers.
+
+LAKE DELTAS. Deltas are also formed where streams lose their
+velocity on entering the still waters of lakes. The shore lines of
+extinct lakes, such as Lake Agassiz and Lakes Bonneville and
+Lahontan, may be traced by the heavy deposits at the mouths of
+their tributary streams.
+
+We have seen that the work of streams is to drain the lands of the
+water poured upon them by the rainfall, to wear them down, and to
+carry their waste away to the sea, there to be rebuilt by other
+agents into sedimentary rocks. The ancient strata of which the
+continents are largely made are composed chiefly of material thus
+worn from still more ancient lands--lands with their hills and
+valleys like those of to-day--and carried by their rivers to the
+ocean. In all geological times, as at the present, the work of
+streams has been to destroy the lands, and in so doing to furnish
+to the ocean the materials from which the lands of future ages
+were to be made. Before we consider how the waste of the land
+brought in by streams is rebuilt upon the ocean floor, we must
+proceed to study the work of two agents, glacier ice and the wind,
+which cooperate with rivers in the denudation of the land.
+
+
+
+
+
+CHAPTER V
+
+THE WORK OF GLACIERS
+
+
+THE DRIFT. The surface of northeastern North America, as far south
+as the Ohio and Missouri rivers, is generally covered by the
+drift,--a formation which is quite unlike any which we have so far
+studied. A section of it, such as that illustrated in Figure 87,
+shows that for the most part it is unstratified, consisting of
+clay, sand, pebbles, and even large bowlders, all mingled pell-
+mell together. The agent which laid the drift is one which can
+carry a load of material of all sizes, from the largest bowlder to
+the finest clay, and deposit it without sorting.
+
+The stones of the drift are of many kinds. The region from which
+it was gathered may well have been large in order to supply these
+many different varieties of rocks. Pebbles and bowlders have been
+left far from their original homes, as may be seen in southern
+Iowa, where the drift contains nuggets of copper brought from the
+region about Lake Superior. The agent which laid the drift is one
+able to gather its load over a large area and carry it a long way.
+
+The pebbles of the drift are unlike those rounded by running water
+or by waves. They are marked with scratches. Some are angular,
+many have had their edges blunted, while others have been ground
+flat and smooth on one or more sides, like gems which have been
+faceted by being held firmly against the lapidary's wheel. In many
+places the upper surface of the country rock beneath the drift has
+been swept clean of residual clays and other waste. All rock
+rotten has been planed away, and the ledges of sound rock to which
+the surface has been cut down have been rubbed smooth and
+scratched with long, straight, parallel lines. The agent which
+laid the drift can hold sand and pebbles firmly in its grasp and
+can grind them against the rock beneath, thus planing it down and
+scoring it, while faceting the pebbles also.
+
+Neither water nor wind can do these things. Indeed, nothing like
+the drift is being formed by any process now at work anywhere in
+the eastern United States. To find the agent which has laid this
+extensive formation we must go to a region of different climatic
+conditions.
+
+THE INLAND ICE OF GREENLAND. Greenland is about fifteen hundred
+miles long and nearly seven hundred miles in greatest width. With
+the exception of a narrow fringe of mountainous coast land, it is
+completely buried beneath a sheet of ice, in shape like a vast
+white shield, whose convex surface rises to a height of nine
+thousand feet above the sea. The few explorers who have crossed
+the ice cap found it a trackless desert destitute of all life save
+such lowly forms as the microscopic plant which produces the so-
+called "red snow." On the smooth plain of the interior no rock
+waste relieves the snow's dazzling whiteness; no streams of
+running water are seen; the silence is broken only by howling
+storm winds and the rustle of the surface snow which they drive
+before them. Sounding with long poles, explorers find that below
+the powdery snow of the latest snowfall lie successive layers of
+earlier snows, which grow more and more compact downward, and at
+last have altered to impenetrable ice. The ice cap formed by the
+accumulated snows of uncounted centuries may well be more than a
+mile in depth. Ice thus formed by the compacting of snow is
+distinguished when in motion as GLACIER ICE.
+
+The inland ice of Greenland moves. It flows with imperceptible
+slowness under its own weight, like, a mass of some viscous or
+plastic substance, such as pitch or molasses candy, in all
+directions outward toward the sea. Near the edge it has so thinned
+that mountain peaks are laid bare, these islands in the sea of ice
+being known as NUNATAKS. Down the valleys of the coastal belt it
+drains in separate streams of ice, or GLACIERS. The largest of
+these reach the sea at the head of inlets, and are therefore
+called TIDE GLACIERS. Their fronts stand so deep in sea water that
+there is visible seldom more than three hundred feet of the wall
+of ice, which in many glaciers must be two thousand and more feet
+high. From the sea walls of tide glaciers great fragments break
+off and float away as icebergs. Thus snows which fell in the
+interior of this northern land, perhaps many thousands of years
+ago, are carried in the form of icebergs to melt at last in the
+North Atlantic.
+
+Greenland, then, is being modeled over the vast extent of its
+interior not by streams of running water, as are regions in warm
+and humid climates, nor by currents of air, as are deserts to a
+large extent, but by a sheet of flowing ice. What the ice sheet is
+doing in the interior we may infer from a study of the separate
+glaciers into which it breaks at its edge.
+
+THE SMALLER GREENLAND GLACIERS. Many of the smaller glaciers of
+Greenland do not reach the sea, but deploy on plains of sand and
+gravel. The edges of these ice tongues are often as abrupt as if
+sliced away with a knife (Fig. 92), and their structure is thus
+readily seen. They are stratified, their layers representing in
+part the successive snowfalls of the interior of the country. The
+upper layers are commonly white and free from stones; but the
+lower layers, to the height of a hundred feet or more, are dark
+with debris which is being slowly carried on. So thickly studded
+with stones is the base of the ice that it is sometimes difficult
+to distinguish it from the rock waste which has been slowly
+dragged beneath the glacier or left about its edges. The waste
+beneath and about the glacier is unsorted. The stones are of many
+kinds, and numbers of them have been ground to flat faces. Where
+the front of the ice has retreated the rock surface is seen to be
+planed and scored in places by the stones frozen fast in the sole
+of the glacier.
+
+We have now found in glacier ice an agent able to produce the
+drift of North America. The ice sheet of Greenland is now doing
+what we have seen was done in the recent past in our own land. It
+is carrying for long distances rocks of many kinds gathered, we
+may infer, over a large extent of country. It is laying down its
+load without assortment in unstratified deposits. It grinds down
+and scores the rock over which it moves, and in the process many
+of the pebbles of its load are themselves also ground smooth and
+scratched. Since this work can be done by no other agent, we must
+conclude that the northeastern part of our own continent was
+covered in the recent past by glacier ice, as Greenland is to-day.
+
+VALLEY GLACIERS
+
+The work of glacier ice can be most conveniently studied in the
+separate ice streams which creep down mountain valleys in many
+regions such as Alaska, the western mountains of the United States
+and Canada, the Himalayas, and the Alps. As the glaciers of the
+Alps have been studied longer and more thoroughly than any others,
+we shall describe them in some detail as examples of valley
+glaciers in all parts of the world.
+
+CONDITIONS OF GLACIER FORMATION. The condition of the great
+accumulation of snow to which glaciers are due--that more or less
+of each winter's snow should be left over unmelted and
+unevaporated to the next--is fully met in the Alps. There is
+abundant moisture brought by the winds from neighboring seas. The
+currents of moist air driven up the mountain slopes are cooled by
+their own expansion as they rise, and the moisture which they
+contain is condensed at a temperature at or below 32 degrees F.,
+and therefore is precipitated in the form of snow. The summers are
+cool and their heat does not suffice to completely melt the heavy
+snow of the preceding winter. On the Alps the SNOW LINE--the lower
+limit of permanent snow--is drawn at about eight thousand five
+hundred feet above sea level. Above the snow line on the slopes
+and crests, where these are not too steep, the snow lies the year
+round and gathers in valley heads to a depth of hundreds of feet.
+
+This is but a small fraction of the thickness to which snow would
+be piled on the Alps were it not constantly being drained away.
+Below the snow fields which mantle the heights the mountain
+valleys are occupied by glaciers which extend as much as a
+vertical mile below the snow line. The presence in the midst of
+forests and meadows and cultivated fields of these tongues of ice,
+ever melting and yet from year to year losing none of their bulk,
+proves that their loss is made good in the only possible way. They
+are fed by snow fields above, whose surplus of snow they drain
+away in the form of ice. The presence of glaciers below the snow
+line is a clear proof that, rigid and motionless as they appear,
+glaciers really are in constant motion down valley.
+
+THE NEVE FIELD. The head of an Alpine valley occupied by a glacier
+is commonly a broad amphitheater deeply filled with snow. Great
+peaks tower above it, and snowy slopes rise on either side on the
+flanks of mountain spurs. From these heights fierce winds drift
+the snows into the amphitheater, and avalanches pour in their
+torrents of snow and waste. The snow of the amphitheater is like
+that of drifts in late winter after many successive thaws and
+freezings. It is made of hard grains and pellets and is called
+NEVE. Beneath the surface of the neve field and at its outlet the
+granular neve has been compacted to a mass of porous crystalline
+ice. Snow has been changed to neve, and neve to glacial ice, both
+by pressure, which drives the air from the interspaces of the
+snowflakes, and also by successive meltings and freezings, much as
+a snowball is packed in the warm hand and becomes frozen to a ball
+of ice.
+
+THE BERGSCHRUND. The neve is in slow motion. It breaks itself
+loose from the thinner snows about it, too shallow to share its
+motion, and from the rock rim which surrounds it, forming a deep
+fissure called the bergschrund, sometimes a score and more feet
+wide.
+
+SIZE OF GLACIERS. The ice streams of the Alps vary in size
+according to the amount of precipitation and the area of the neve
+fields which they drain. The largest of Alpine glaciers, the
+Aletsch, is nearly ten miles long and has an average width of
+about a mile. The thickness of some of the glaciers of the Alps is
+as much as a thousand feet. Giant glaciers more than twice the
+length of the longest in the Alps occur on the south slope of the
+Himalaya Mountains, which receive frequent precipitations of snow
+from moist winds from the Indian Ocean. The best known of the many
+immense glaciers of Alaska, the Muir, has an area of about eight
+hundred square miles (Fig. 95).
+
+GLACIER MOTION. The motion of the glaciers of the Alps seldom
+exceeds one or two feet a day. Large glaciers, because of the
+enormous pressure of their weight and because of less marginal
+resistance, move faster than small ones. The Muir advances at the
+rate of seven feet a day, and some of the larger tide glaciers of
+Greenland are reported to move at the exceptional rate of fifty
+feet and more in the same time. Glaciers move faster by day than
+by night, and in summer than in winter. Other laws of glacier
+motion may be discovered by a study of Figures 96 and 97. It is
+important to remember that glaciers do not slide bodily over their
+beds, but urged by gravity move slowly down valley in somewhat the
+same way as would a stream of thick mud. Although small pieces of
+ice are brittle, the large mass of granular ice which composes a
+glacier acts as a viscous substance.
+
+CREVASSES. Slight changes of slope in the glacier bed, and the
+different rates of motion in different parts, produce tensions
+under which the ice cracks and opens in great fissures called
+crevasses. At an abrupt descent in the bed the ice is shattered
+into great fragments, which unite again below the icefall.
+Crevasses are opened on lines at right angles to the direction of
+the tension. TRANSVERSE CREVASSES are due to a convexity in the
+bed which stretches the ice lengthwise (Fig. 99). MARGINAL
+CREVASSES are directed upstream and inwards; RADIAL CREVASSES are
+found where the ice stream deploys from some narrow valley and
+spreads upon some more open space. What is the direction of the
+tension which causes each and to what is it due?
+
+LATERAL AND MEDIAL MORAINES. The surface of a glacier is striped
+lengthwise by long dark bands of rock debris. Those in the center
+are called the medial moraines. The one on either margin is a
+lateral moraine, and is clearly formed of waste which has fallen
+on the edge of the ice from the valley slopes. A medial moraine
+cannot be formed in this way, since no rock fragments can fall so
+far out from the sides. But following it up the glacial stream,
+one finds that a medial moraine takes its beginning at the
+junction of the glacier and some tributary and is formed by the
+union of their two adjacent lateral moraines. Each branch thus
+adds a medial moraine, and by counting the number of medial
+moraines of a trunk stream one may learn of how many branches it
+is composed.
+
+Surface moraines appear in the lower course of the glacier as
+ridges, which may reach the exceptional height of one hundred
+feet. The bulk of such a ridge is ice. It has been protected from
+the sun by the veneer of moraine stuff; while the glacier surface
+on either side has melted down at least the distance of the height
+of the ridge. In summer the lowering of the glacial surface by
+melting goes on rapidly. In Swiss glaciers it has been estimated
+that the average lowering of the surface by melting and
+evaporation amounts to ten feet a year. As a moraine ridge grows
+higher and more steep by the lowering of the surface of the
+surrounding ice, the stones of its cover tend to slip down its
+sides. Thus moraines broaden, until near the terminus of a glacier
+they may coalesce in a wide field of stony waste.
+
+ENGLACIAL DRIFT. This name is applied to whatever debris is
+carried within the glacier. It consists of rock waste fallen on
+the neve and there buried by accumulations of snow, and of that
+engulfed in the glacier where crevasses have opened beneath a
+surface moraine. As the surface of the glacier is lowered by
+melting, more or less englacial drift is brought again to open
+air, and near the terminus it may help to bury the ice from view
+beneath a sheet of debris.
+
+THE GROUND MORAINE. The drift dragged along at the glacier's base
+and lodged beneath it is known as the ground moraine. Part of the
+material of it has fallen down deep crevasses and part has been
+torn and worn from the glacier's bed and banks. While the stones
+of the surface moraines remain as angular as when they lodged on
+the ice, many of those of the ground moraine have been blunted on
+the edges and faceted and scratched by being ground against one
+another and the rocky bed.
+
+In glaciers such as those of Greenland, whose basal layers are
+well loaded with drift and whose surface layers are nearly clean,
+different layers have different rates of motion, according to the
+amount of drift with which they are clogged. One layer glides over
+another, and the stones inset in each are ground and smoothed and
+scratched. Usually the sides of glaciated pebbles are more worn
+than the ends, and the scratches upon them run with the longer
+axis of the stone. Why?
+
+THE TERMINAL MORAINE. As a glacier is in constant motion, it
+brings to its end all of its load except such parts of the ground
+moraine as may find permanent lodgment beneath the ice. Where the
+glacier front remains for some time at one place, there is formed
+an accumulation of drift known as the terminal moraine. In valley
+glaciers it is shaped by the ice front to a crescent whose convex
+side is downstream. Some of the pebbles of the terminal moraine
+are angular, and some are faceted and scored, the latter having
+come by the hard road of the ground moraine. The material of the
+dump is for the most part unsorted, though the water of the
+melting ice may find opportunity to leave patches of stratified
+sands and gravels in the midst of the unstratified mass of drift,
+and the finer material is in places washed away.
+
+GLACIER DRAINAGE. The terminal moraine is commonly breached by a
+considerable stream, which issues from beneath the ice by a tunnel
+whose portal has been enlarged to a beautiful archway by melting
+in the sun and the warm air (Fig. 107). The stream is gray with
+silt and loaded with sand and gravel washed from the ground
+moraine. "Glacier milk" the Swiss call this muddy water, the gray
+color of whose silt proves it rock flour freshly ground by the ice
+from the unoxidized sound rock of its bed, the mud of streams
+being yellowish when it is washed from the oxidized mantle of
+waste. Since glacial streams are well loaded with waste due to
+vigorous ice erosion, the valley in front of the glacier is
+commonly aggraded to a broad, flat floor. These outwash deposits
+are known as VALLEY DRIFT.
+
+The sand brought out by streams from beneath a glacier differs
+from river sand in that it consists of freshly broken angular
+grains. Why?
+
+The stream derives its water chiefly from the surface melting of
+the glacier. As the ice is touched by the rays of the morning sun
+in summer, water gathers in pools, and rills trickle and unite in
+brooklets which melt and cut shallow channels in the blue ice. The
+course of these streams is short. Soon they plunge into deep wells
+cut by their whirling waters where some crevasse has begun to open
+across their path. These wells lead into chambers and tunnels by
+which sooner or later their waters find way to the rock floor of
+the valley and there unite in a subglacial stream.
+
+THE LOWER LIMIT OF GLACIERS. The glaciers of a region do not by
+any means end at a uniform height above sea level. Each terminates
+where its supply is balanced by melting. Those therefore which are
+fed by the largest and deepest neves and those also which are best
+protected from the sun by a northward exposure or by the depth of
+their inclosing valleys flow to lower levels than those whose
+supply is less and whose exposure to the sun is greater.
+
+A series of cold, moist years, with an abundant snowfall, causes
+glaciers to thicken and advance; a series of warm, dry years
+causes them to wither and melt back. The variation in glaciers is
+now carefully observed in many parts of the world. The Muir
+glacier has retreated two miles in twenty years. The glaciers of
+the Swiss Alps are now for the most part melting back, although a
+well-known glacier of the eastern Alps, the Vernagt, advanced five
+hundred feet in the year 1900, and was then plowing up its
+terminal moraine.
+
+How soon would you expect a glacier to advance after its neve
+fields have been swollen with unusually heavy snows, as compared
+with the time needed for the flood of a large river to reach its
+mouth after heavy rains upon its headwaters?
+
+On the surface of glaciers in summer time one may often see large
+stones supported by pillars of ice several feet in height (Fig.
+108). These "glacier tables" commonly slope more or less strongly
+to the south, and thus may be used to indicate roughly the points
+of the compass. Can you explain their formation and the direction
+of their slope? On the other hand, a small and thin stone, or a
+patch of dust, lying on the ice, tends to sink a few inches into
+it. Why?
+
+In what respects is a valley glacier like a mountain stream which
+flows out upon desert plains?
+
+Two confluent glaciers do not mingle their currents as do two
+confluent rivers. What characteristics of surface moraines prove
+this fact?
+
+What effect would you expect the laws of glacier motion to have on
+the slant of the sides of transverse crevasses?
+
+A trunk glacier has four medial moraines. Of how many tributaries
+is it composed? Illustrate by diagram.
+
+State all the evidences which you have found that glaciers move.
+
+If a glacier melts back with occasional pauses up a valley, what
+records are left of its retreat?
+
+PIEDMONT GLACIERS
+
+THE MALASPINA GLACIER. Piedmont (foot of the mountain) glaciers
+are, as the name implies, ice fields formed at the foot of
+mountains by the confluence of valley glaciers. The Malaspina
+glacier of Alaska, the typical glacier of this kind, is seventy
+miles wide and stretches for thirty miles from the foot of the
+Mount Saint Elias range to the shore of the Pacific Ocean. The
+valley glaciers which unite and spread to form this lake of ice
+lie above the snow line and their moraines are concealed beneath
+neve. The central area of the Malaspina is also free from debris;
+but on the outer edge large quantities of englacial drift are
+exposed by surface melting and form a belt of morainic waste a few
+feet thick and several miles wide, covered in part with a
+luxuriant forest, beneath which the ice is in places one thousand
+feet in depth. The glacier here is practically stagnant, and lakes
+a few hundred yards across, which could not exist were the ice in
+motion and broken with crevasses, gather on their beds sorted
+waste from the moraine. The streams which drain the glacier have
+cut their courses in englacial and subglacial tunnels; none flow
+for any distance on the surface. The largest, the Yahtse River,
+issues from a high archway in the ice,--a muddy torrent one
+hundred feet wide and twenty feet deep, loaded with sand and
+stones which it deposits in a broad outwash plain (Fig. 110).
+Where the ice has retreated from the sea there is left a hummocky
+drift sheet with hollows filled with lakelets. These deposits help
+to explain similar hummocky regions of drift and similar plains of
+coarse, water-laid material often found in the drift-covered area
+of the northeastern United States.
+
+THE GEOLOGICAL WORK OF GLACIER ICE
+
+The sluggish glacier must do its work in a different way from the
+agile river. The mountain stream is swift and small, and its
+channel occupies but a small portion of the valley. The glacier is
+slow and big; its rate of motion may be less than a millionth of
+that of running water over the same declivity, and its bulk is
+proportionately large and fills the valley to great depth.
+Moreover, glacier ice is a solid body plastic under slowly applied
+stresses, while the water of rivers is a nimble fluid.
+
+TRANSPORTATION. Valley glaciers differ from rivers as carriers in
+that they float the major part of their load upon their surface,
+transporting the heaviest bowlder as easily as a grain of sand;
+while streams push and roll much of their load along their beds,
+and their power of transporting waste depends solely upon their
+velocity. The amount of the surface load of glaciers is limited
+only by the amount of waste received from the mountain slopes
+above them. The moving floor of ice stretched high across a valley
+sweeps along as lateral moraines much of the waste which a
+mountain stream would let accumulate in talus and alluvial cones.
+
+While a valley glacier carries much of its load on top, an ice
+sheet, such as that of Greenland, is free from surface debris,
+except where moraines trail away from some nunatak. If at its edge
+it breaks into separate glaciers which drain down mountain
+valleys, these tongues of ice will carry the selvages of waste
+common to valley glaciers. Both ice sheets and valley glaciers
+drag on large quantities of rock waste in their ground moraines.
+
+Stones transported by glaciers are sometimes called erratics. Such
+are the bowlders of the drift of our northern states. Erratics may
+be set down in an insecure position on the melting of the ice.
+
+DEPOSIT. Little need be added here to what has already been said
+of ground and terminal moraines. All strictly glacial deposits are
+unstratified. The load laid down at the end of a glacier in the
+terminal moraine is loose in texture, while the drift lodged
+beneath the glacier as ground moraine is often an extremely dense,
+stony clay, having been compacted under the pressure of the
+overriding ice.
+
+EROSION. A glacier erodes its bed and banks in two ways,--by
+abrasion and by plucking.
+
+The rock bed over which a glacier has moved is seen in places to
+have been abraded, or ground away, to smooth surfaces which are
+marked by long, straight, parallel scorings aligned with the line
+of movement of the ice and varying in size from hair lines and
+coarse scratches to exceptional furrows several feet deep. Clearly
+this work has been accomplished by means of the sharp sand, the
+pebbles, and the larger stones with which the base of the glacier
+is inset, and which it holds in a firm grasp as running water
+cannot. Hard and fine-grained rocks, such as granite and
+quartzite, are often not only ground down to a smooth surface but
+are also highly polished by means of fine rock flour worn from the
+glacier bed.
+
+In other places the bed of the glacier is rough and torn. The
+rocks have been disrupted and their fragments have been carried
+away,--a process known as PLUCKING. Moving under immense pressure
+the ice shatters the rock, breaks off projections, presses into
+crevices and wedges the rocks apart, dislodges the blocks into
+which the rock is divided by joints and bedding planes, and
+freezing fast to the fragments drags them on. In this work the
+freezing and thawing of subglacial waters in any cracks and
+crevices of the rock no doubt play an important part. Plucking
+occurs especially where the bed rock is weak because of close
+jointing. The product of plucking is bowlders, while the product
+of abrasion is fine rock flour and sand.
+
+Is the ground moraine of Figure 87 due chiefly to abrasion or to
+plucking?
+
+ROCHES MOUTONNEES AND ROUNDED HILLS. The prominences left between
+the hollows due to plucking are commonly ground down and rounded
+on the stoss side,--the side from which the ice advances,--and
+sometimes on the opposite, the lee side, as well. In this way the
+bed rock often comes to have a billowy surface known as roches
+moutonnees (sheep rocks). Hills overridden by an ice sheet often
+have similarly rounded contours on the stoss side, while on the
+lee side they may be craggy, either because of plucking or because
+here they have been less worn from their initial profile.
+
+THE DIRECTION OF GLACIER MOVEMENT. The direction of the flow of
+vanished glaciers and ice sheets is recorded both in the
+differences just mentioned in the profiles of overridden hills and
+also in the minute details of the glacier trail.
+
+Flint nodules or other small prominences in the bed rock are found
+more worn on the stoss than on the lee side, where indeed they may
+have a low cone of rock protected by them from abrasion. Cavities,
+on the other hand, have their edges worn on the lee side and left
+sharp upon the stoss.
+
+Surfaces worn and torn in the ways which we have mentioned are
+said to be glaciated. But it must not be supposed that a glacier
+everywhere glaciates its bed. Although in places it acts as a rasp
+or as a pick, in others, and especially where its pressure is
+least, as near the terminus, it moves over its bed in the manner
+of a sled. Instances are known where glaciers have advanced over
+deposits of sand and gravel without disturbing them to any notable
+degree. Like a river, a glacier does not everywhere erode. In
+places it leaves its bed undisturbed and in places aggrades it by
+deposits of the ground moraine.
+
+CIRQUES. Valley glaciers commonly head as we have seen, in broad
+amphitheaters deeply filled with snow and ice. On mountains now
+destitute of glaciers, but whose glaciation shows that they have
+supported glaciers in the past, there are found similar crescentic
+hollows with high, precipitous walls and glaciated floors. Their
+floors are often basined and hold lakelets whose deep and quiet
+waters reflect the sheltering ramparts of rugged rock which tower
+far above them. Such mountain hollows are termed CIRQUES. As a
+powerful spring wears back a recess in the valley side where it
+discharges, so the fountain head of a glacier gradually wears back
+a cirque. In its slow movement the neve field broadly scours its
+bed to a flat or basined floor. Meanwhile the sides of the valley
+head are steepened and driven back to precipitous walls. For in
+winter the crevasse of the bergschrund which surrounds the neve
+field is filled with snow and the neve is frozen fast to the rocky
+sides of the valley. In early summer the neve tears itself free,
+dislodging and removing any loosened blocks, and the open fissure
+of the bergschrund allows frost and other agencies of weathering
+to attack the unprotected rock. As cirques are thus formed and
+enlarged the peaks beneath which they lie are sharpened, and the
+mountain crests are scalloped and cut back from either side to
+knife-edged ridges.
+
+In the western mountains of the United States many cirques, now
+empty of neve and glacier ice, and known locally as "basins,"
+testify to the fact that in recent times the snow line stood
+beneath the levels of their floors, and thus far below its present
+altitude.
+
+GLACIER TROUGHS. The channel worn to accommodate the big and
+clumsy glacier differs markedly from the river valley cut as with
+a saw by the narrow and flexible stream and widened by the weather
+and the wash of rains. The valley glacier may easily be from one
+thousand to three thousand feet deep and from one to three miles
+wide. Such a ponderous bulk of slowly moving ice does not readily
+adapt itself to sharp turns and a narrow bed. By scouring and
+plucking all resisting edges it develops a fitting channel with a
+wide, flat floor, and steep, smooth sides, above which are seen
+the weathered slopes of stream-worn mountain valleys. Since the
+trunk glacier requires a deeper channel than do its branches, the
+bed of a branch glacier enters the main trough at some distance
+above the floor of the latter, although the surface of the two ice
+streams may be accordant. Glacier troughs can be studied best
+where large glaciers have recently melted completely away, as is
+the case in many valleys of the mountains of the western United
+States and of central and northern Europe (Fig. 114). The typical
+glacier trough, as shown in such examples, is U-shaped, with a
+broad, flat floor, and high, steep walls. Its walls are little
+broken by projecting spurs and lateral ravines. It is as if a V-
+valley cut by a river had afterwards been gouged deeper with a
+gigantic chisel, widening the floor to the width of the chisel
+blade, cutting back the spurs, and smoothing and steepening the
+sides. A river valley could only be as wide-floored as this after
+it had long been worn down to grade.
+
+The floor of a glacier trough may not be graded; it is often
+interrupted by irregular steps perhaps hundreds and even a
+thousand feet in height, over which the stream that now drains the
+valley tumbles in waterfalls. Reaches between the steps are often
+basined. Lakelets may occupy hollows excavated in solid rock, and
+other lakes may be held behind terminal moraines left as dams
+across the valley at pauses in the retreat of the glacier.
+
+FJORDS are glacier troughs now occupied in part or wholly by the
+sea, either because they were excavated by a tide glacier to their
+present depth below sea level, or because of a submergence of the
+land. Their characteristic form is that of a long, deep, narrow
+bay with steep rock walls and basined floor. Fjords are found only
+in regions which have suffered glaciation, such as Norway and
+Alaska.
+
+HANGING VALLEYS. These are lateral valleys which open on their
+main valley some distance above its floor. They are conspicuous
+features of glacier troughs from which the ice has vanished; for
+the trunk glacier in widening and deepening its channel cut its
+bed below the bottoms of the lateral valleys.
+
+Since the mouths of hanging valleys are suspended on the walls of
+the glacier trough, their streams are compelled to plunge down its
+steep, high sides in waterfalls. Some of the loftiest and most
+beautiful waterfalls of the world leap from hanging valleys,--
+among them the celebrated Staubbach of the Lauterbrunnen valley of
+Switzerland, and those of the fjords of Norway and Alaska.
+
+Hanging valleys are found also in river gorges where the smaller
+tributaries have not been able to keep pace with a strong master
+stream in cutting down their beds. In this case, however, they are
+a mark of extreme youth; for, as the trunk stream approaches grade
+and its velocity and power to erode its bed decrease, the side
+streams soon cut back their falls and wear their beds at their
+mouths to a common level with that of the main river. The Grand
+Canyon of the Colorado must be reckoned a young valley. At its
+base it narrows to scarcely more than the width of the river, and
+yet its tributaries, except the very smallest, enter it at a
+common level.
+
+Why could not a wide-floored valley, such as a glacier trough,
+with hanging valleys opening upon it, be produced in the normal
+development of a river valley?
+
+THE TROUGHS OF YOUNG AND OF MATURE GLACIERS. The features of a
+glacier trough depend much on the length of time the preexisting
+valley was occupied with ice. During the infancy of a glacier, we
+may believe, the spurs of the valley which it fills are but little
+blunted and its bed is but little broken by steps. In youth the
+glacier develops icefalls, as a river in youth develops
+waterfalls, and its bed becomes terraced with great stairs. The
+mature glacier, like the mature river, has effaced its falls and
+smoothed its bed to grade. It has also worn back the projecting
+spurs of its valley, making itself a wide channel with smooth
+sides. The bed of a mature glacier may form a long basin, since it
+abrades most in its upper and middle course, where its weight and
+motion are the greatest. Near the terminus, where weight and
+motion are the least, it erodes least, and may instead deposit a
+sheet of ground moraine, much as a river builds a flood plain in
+the same part of its course as it approaches maturity. The bed of
+a mature glacier thus tends to take the form of a long, relatively
+narrow basin, across whose lower end may be stretched the dam of
+the terminal moraine. On the disappearance of the ice the basin is
+rilled with a long, narrow lake, such as Lake Chelan in Washington
+and many of the lakes in the Highlands of Scotland.
+
+Piedmont glaciers apparently erode but little. Beneath their lake-
+like expanse of sluggish or stagnant ice a broad sheet of ground
+moraine is probably being deposited.
+
+Cirques and glaciated valleys rapidly lose their characteristic
+forms after the ice has withdrawn. The weather destroys all
+smoothed, polished, and scored surfaces which are not protected
+beneath glacial deposits. The oversteepened sides of the trough
+are graded by landslips, by talus slopes, and by alluvial cones.
+Morainic heaps of drift are dissected and carried away. Hanging
+valleys and the irregular bed of the trough are both worn down to
+grade by the streams which now occupy them. The length of time
+since the retreat of the ice from a mountain valley may thus be
+estimated by the degree to which the destruction of the
+characteristic features of the glacier trough has been carried.
+
+In Figure 104 what characteristics of a glacier trough do you
+notice? What inference do you draw as to the former thickness of
+the glacier?
+
+Name all the evidences you would expect to find to prove the fact
+that in the recent geological past the valleys of the Alps
+contained far larger glaciers than at present, and that on the
+north of the Alps the ice streams united in a piedmont glacier
+which extended across the plains of Switzerland to the sides of
+the Jura Mountains.
+
+THE RELATIVE IMPORTANCE OF GLACIERS AND OF RIVERS. Powerful as
+glaciers are, and marked as are the land forms which they produce,
+it is easy to exaggerate their geological importance as compared
+with rivers. Under present climatic conditions they are confined
+to lofty mountains or polar lands. Polar ice sheets are permanent
+only so long as the lands remain on which they rest. Mountain
+glaciers can stay only the brief time during which the ranges
+continue young and high. As lofty mountains, such as the Selkirks
+and the Alps, are lowered by frost and glacier ice, the snowfall
+will decrease, the line of permanent snow will rise, and as the
+mountain hollows in which snow may gather are worn beneath the
+snow line, the glaciers must disappear. Under present climatic
+conditions the work of glaciers is therefore both local and of
+short duration.
+
+Even the glacial epoch, during which vast ice sheets deposited
+drift over northeastern North America, must have been brief as
+well as recent, for many lofty mountains, such as the Rockies and
+the Alps, still bear the marks of great glaciers which then filled
+their valleys. Had the glacial epoch been long, as the earth
+counts time, these mountains would have been worn low by ice; had
+the epoch been remote, the marks of glaciation would already have
+been largely destroyed by other agencies.
+
+On the other hand, rivers are well-nigh universally at work over
+the land surfaces of the globe, and ever since the dry land
+appeared they have been constantly engaged in leveling the
+continents and in delivering to the seas the waste which there is
+built into the stratified rocks.
+
+ICEBERGS. Tide glaciers, such as those of Greenland and Alaska,
+are able to excavate their beds to a considerable distance below
+sea level. From their fronts the buoyancy of sea water raises and
+breaks away great masses of ice which float out to sea as
+icebergs. Only about one seventh of a mass of glacier ice floats
+above the surface, and a berg three hundred feet high may be
+estimated to have been detached from a glacier not less than two
+thousand feet thick where it met the sea.
+
+Icebergs transport on their long journeys whatever drift they may
+have carried when part of the glacier, and scatter it, as they
+melt, over the ocean floor. In this way pebbles torn by the inland
+ice from the rocks of the interior of Greenland and glaciated
+during their carriage in the ground moraine are dropped at last
+among the oozes of the bottom of the North Atlantic.
+
+
+
+
+
+CHAPTER VI
+
+THE WORK OF THE WIND
+
+
+We are now to study the geological work of the currents of the
+atmosphere, and to learn how they erode, and transport and deposit
+waste as they sweep over the land. Illustrations of the wind's
+work are at hand in dry weather on any windy day.
+
+Clouds of dust are raised from the street and driven along by the
+gale. Here the roadway is swept bare; and there, in sheltered
+places, the dust settles in little windrows. The erosive power of
+waste-laden currents of air is suggested as the sharp grains of
+flying sand sting one's face or clatter against the window. In the
+country one sometimes sees the dust whirled in clouds from dry,
+plowed fields in spring and left in the lee of fences in small
+drifts resembling in form those of snow in winter.
+
+THE ESSENTIAL CONDITIONS for the wind's conspicuous work are
+illustrated in these simple examples; they are aridity and the
+absence of vegetation. In humid climates these conditions are only
+rarely and locally met; for the most part a thick growth of
+vegetation protects the moist soil from the wind with a cover of
+leaves and stems and a mattress of interlacing roots. But in arid
+regions either vegetation is wholly lacking, or scant growths are
+found huddled in detached clumps, leaving interspaces of
+unprotected ground (Fig. 119). Here, too, the mantle of waste,
+which is formed chiefly under the action of temperature changes,
+remains dry and loose for long periods. Little or no moisture is
+present to cause its particles to cohere, and they are therefore
+readily lifted and drifted by the wind.
+
+TRANSPORTATION BY THE WIND
+
+In the desert the finer waste is continually swept to and fro by
+the ever-shifting wind. Even in quiet weather the air heated by
+contact with the hot sands rises in whirls, and the dust is lifted
+in stately columns, sometimes as much as one thousand feet in
+height, which march slowly across the plain. In storms the sand is
+driven along the ground in a continuous sheet, while the air is
+tilled with dust. Explorers tell of sand storms in the deserts of
+central Asia and Africa, in which the air grows murky and
+suffocating. Even at midday it may become dark as night, and
+nothing can be heard except the roar of the blast and the whir of
+myriads of grains of sand as they fly past the ear.
+
+Sand storms are by no means uncommon in the arid regions of the
+western United States. In a recent year, six were reported from
+Yuma, Arizona. Trains on transcontinental railways are
+occasionally blockaded by drifting sand, and the dust sifts into
+closed passenger coaches, covering the seats and floors. After
+such a storm thirteen car loads of sand were removed from the
+platform of a station on a western railway.
+
+DUST FALLS. Dust launched by upward-whirling winds on the swift
+currents of the upper air is often blown for hundreds of miles
+beyond the arid region from which it was taken. Dust falls from
+western storms are not unknown even as far east as the Great
+Lakes. In 1896 a "black snow" fell in Chicago, and in another dust
+storm in the same decade the amount of dust carried in the air
+over Rock Island, Ill., was estimated at more than one thousand
+tons to the cubic mile.
+
+In March, 1901, a cyclonic storm carried vast quantities of dust
+from the Sahara northward across the Mediterranean to fall over
+southern and central Europe. On March 8th dust storms raged in
+southern Algeria; two days later the dust fell in Italy; and on
+the 11th it had reached central Germany and Denmark. It is
+estimated that in these few days one million eight hundred
+thousand tons of waste were carried from northern Africa and
+deposited on European soil.
+
+We may see from these examples the importance of the wind as an
+agent of transportation, and how vast in the aggregate are the
+loads which it carries. There are striking differences between air
+and water as carriers of waste. Rivers flow in fixed and narrow
+channels to definite goals. The channelless streams of the air
+sweep across broad areas, and, shifting about continually, carry
+their loads back and forth, now in one direction and now in
+another.
+
+WIND DEPOSITS
+
+The mantle of waste of deserts is rapidly sorted by the wind. The
+coarser rubbish, too heavy to be lifted into the air, is left to
+strew wide tracts with residual gravels (Fig. 120). The sand
+derived from the disintegration of desert rocks gathers in vast
+fields. About one eighth of the surface of the Sahara is said to
+be thus covered with drifting sand. In desert mountains, as those
+of Sinai, it lies like fields of snow in the high valleys below
+the sharp peaks. On more level tracts it accumulates in seas of
+sand, sometimes, as in the deserts of Arabia, two hundred and more
+feet deep.
+
+DUNES. The sand thus accumulated by the wind is heaped in wavelike
+hills called dunes. In the desert of northwestern India, where the
+prevalent wind is of great strength, the sand is laid in
+longitudinal dunes, i.e. in stripes running parallel with the
+direction of the wind; but commonly dunes lie, like ripple marks,
+transverse to the wind current. On the windward side they show a
+long, gentle slope, up which grains of sand can readily be moved;
+while to the lee their slope is frequently as great as the angle
+of repose (Fig. 122). Dunes whose sands are not fixed by
+vegetation travel slowly with the wind; for their material is ever
+shifted forward as the grains are driven up the windward slope
+and, falling over the crest, are deposited in slanting layers in
+the quiet of the lee.
+
+Like river deposits, wind-blown sands are stratified, since they
+are laid by currents of air varying in intensity, and therefore
+in transporting power, which carry now finer and now coarser
+materials and lay them down where their velocity is checked (Fig.
+123). Since the wind varies in direction, the strata dip in
+various directions. They also dip at various angles, according to
+the inclination of the surface on which they were laid.
+
+Dunes occur not only in arid regions, but also wherever loose sand
+lies unprotected by vegetation from the wind. From the beaches of
+sea and lake shores the wind drives inland the surface sand left
+dry between tides and after storms, piling it in dunes which may
+invade forests and fields and bury villages beneath their slowly
+advancing waves. On flood plains during summer droughts river
+deposits are often worked over by the wind; the sand is heaped in
+hummocks and much of the fine silt is caught and held by the
+forests and grassy fields of the bordering hills.
+
+The sand of shore dunes differs little in composition and the
+shape of its grains from that of the beach from which it was
+derived. But in deserts, by the long wear of grain on grain as
+they are blown hither and thither by the wind, all soft minerals
+are ground to powder and the sand comes to consist almost wholly
+of smooth round grams of hard quartz.
+
+Some marine sandstones, such as the St. Peter sandstone of the
+upper Mississippi valley, are composed so entirely of polished
+spherules of quartz that it has been believed by some that their
+grains were long blown about in ancient deserts before they were
+deposited in the sea.
+
+DUST DEPOSITS. As desert sands are composed almost wholly of
+quartz, we may ask what has become of the softer minerals of which
+the rocks whose disintegration has supplied the sand were in part,
+and often in large part, composed. The softer minerals have been
+ground to powder, and little by little the quartz sand also is
+worn by attrition to fine dust. Yet dust deposits are scant and
+few in great deserts such as the Sahara. The finer waste is blown
+beyond its limits and laid in adjacent oceans, where it adds to
+the muds and oozes of their floors, and on bordering steppes and
+forest lands, where it is bound fast by vegetation and slowly
+accumulates in deposits of unstratified loose yellow earth. The
+fine waste of the Sahara has been identified in dredgings from the
+bottom of the Atlantic Ocean, taken hundreds of miles from the
+coast of Africa.
+
+LOESS. In northern China an area as large as France is deeply
+covered with a yellow pulverulent earth called loess (German,
+loose), which many consider a dust deposit blown from the great
+Mongolian desert lying to the west. Loess mantles the recently
+uplifted mountains to the height of eight thousand feet and
+descends on the plains nearly to sea level. Its texture and lack
+of stratification give it a vertical cleavage; hence it stands in
+steep cliffs on the sides of the deep and narrow trenches which
+have been cut in it by streams.
+
+On loess hillsides in China are thousands of villages whose
+eavelike dwellings have been excavated in this soft, yet firm, dry
+loam. While dust falls are common at the present time in this
+region, the loess is now being rapidly denuded by streams, and its
+yellow silt gives name to the muddy Hwang-ho (Yellow River), and
+to the Yellow Sea, whose waters it discolors for scores of miles
+from shore.
+
+Wind deposits both of dust and of sand may be expected to contain
+the remains of land shells, bits of wood, and bones of land
+animals, testifying to the fact that they were accumulated in open
+air and not in the sea or in bodies of fresh water.
+
+WIND EROSION
+
+Sand-laden currents of air abrade and smooth and polish exposed
+rock surfaces, acting in much the same way as does the jet of
+steam fed with sharp sand, which is used in the manufacture of
+ground glass. Indeed, in a single storm at Cape Cod a plate glass
+of a lighthouse was so ground by flying sand that its transparency
+was destroyed and its removal made necessary.
+
+Telegraph poles and wires whetted by wind-blown sands are
+destroyed within a few years. In rocks of unequal resistance the
+harder parts are left in relief, while the softer are etched away.
+Thus in the pass of San Bernardino, Cal., through which strong
+winds stream from the west, crystals of garnet are left projecting
+on delicate rock fingers from the softer rock in which they were
+imbedded.
+
+Wind-carved pebbles are characteristically planed, the facets
+meeting along a summit ridge or at a point like that of a pyramid.
+We may suppose that these facets were ground by prevalent winds
+from certain directions, or that from time to time the stone was
+undermined and rolled over as the sand beneath it was blown away
+on the windward side, thus exposing fresh surfaces to the driving
+sand. Such wind-carved pebbles are sometimes found in ancient
+rocks and may be accepted as evidence that the sands of which the
+rocks are composed were blown about by the wind.
+
+DEFLATION. In the denudation of an arid region, wind erosion is
+comparatively ineffective as compared with deflation (Latin, de,
+from; flare, to blow),--a term by which is meant the constant
+removal of waste by the wind, leaving the rocks bare to the
+continuous attack of the weather. In moist climates denudation is
+continually impeded by the mantle of waste and its cover of
+vegetation, and the land surface can be lowered no faster than the
+waste is removed by running water. Deep residual soils come to
+protect all regions of moderate slope, concealing from view the
+rock structure, and the various forms of the land are due more to
+the agencies of erosion and transportation than to differences in
+the resistance of the underlying rocks.
+
+But in arid regions the mantle is rapidly removed, even from well-
+nigh level plains and plateaus, by the sweep of the wind and the
+wash of occasional rains. The geological structure of these
+regions of naked rock can be read as far as the eye can see, and
+it is to this structure that the forms of the land are there
+largely due. In a land mass of horizontal strata, for example, any
+softer surface rocks wear down to some underlying, resistant
+stratum, and this for a while forms the surface of a level plateau
+(Fig. 129). The edges of the capping layer, together with those of
+any softer layers beneath it, wear back in steep cliffs, dissected
+by the valleys of wet-weather streams and often swept bare to the
+base by the wind. As they are little protected by talus, which
+commonly is removed about as fast as formed, these escarpments and
+the walls of the valleys retreat indefinitely, exposing some hard
+stratum beneath which forms the floor of a widening terrace.
+
+The high plateaus of northern Arizona and southern Utah, north of
+the Grand Canyon of the Colorado River, are composed of stratified
+rocks more than ten thousand feet thick and of very gentle
+inclination northward. From the broad plat form in which the
+canyon has been cut rises a series of gigantic stairs, which are
+often more than one thousand feet high and a score or more of
+miles in breadth. The retreating escarpments, the cliffs of the
+mesas and buttes which they have left behind as outliers, and the
+walls of the ravines are carved into noble architectural forms--
+into cathedrals, pyramids, amphitheaters, towers, arches, and
+colonnades--by the processes of weathering aided by deflation. It
+is thus by the help of the action of the wind that great plateaus
+in arid regions are dissected and at last are smoothed away to
+waterless plains, either composed of naked rock, or strewed with
+residual gravels, or covered with drifting residual sand.
+
+The specific gravity of air is 1/823 that of water. How does this
+fact affect the weight of the material which each can carry at the
+same velocity?
+
+If the rainfall should lessen in your own state to from five to
+ten inches a year, what changes would take place in the vegetation
+of the country? in the soil? in the streams? in the erosion of
+valleys? in the agencies chiefly at work in denuding the land?
+
+In what way can a wind-carved pebble be distinguished from a
+river-worn pebble? from a glaciated pebble?
+
+
+
+
+
+CHAPTER VII
+
+THE SEA AND ITS SHORES
+
+
+We have already seen that the ocean is the goal at which the waste
+of the land arrives. The mantle of rock waste, creeping down
+slopes, is washed to the sea by streams, together with the
+material which the streams have worn from their beds and that
+dissolved by underground waters. In arid regions the winds sweep
+waste either into bordering oceans or into more humid regions
+where rivers take it up and carry it on to the sea. Glaciers
+deliver the load of their moraines either directly to the sea or
+leave it for streams to transport to the same goal. All deposits
+made on the land, such as the flood plains of rivers, the silts of
+lake beds, dune sands, and sheets of glacial drift, mark but
+pauses in the process which is to bring all the materials of the
+land now above sea level to rest upon the ocean bed.
+
+But the sea is also at work along all its shores as an agent of
+destruction, and we must first take up its work in erosion before
+we consider how it transports and deposits the waste of the land.
+
+SEA EROSION
+
+THE SEA CLIFF AND THE ROCK BENCH. On many coasts the land fronts
+the ocean in a line of cliffs. To the edge of the cliffs there
+lead down valleys and ridges, carved by running water, which, if
+extended, would meet the water surface some way out from shore.
+Evidently they are now abruptly cut short at the present shore
+line because the land has been cut back.
+
+Along the foot of the cliff lies a gently shelving bench of rock,
+more or less thickly veneered with sand and shingle. At low tide
+its inner margin is laid bare, but at high tide it is covered
+wholly, and the sea washes the base of the cliffs. A notch, of
+which the SEA CLIFF and the ROCK BENCH are the two sides, has been
+cut along the shore.
+
+WAVES. The position of the rock bench, with its inner margin
+slightly above low tide, shows that it has been cut by some agent
+which acts like a horizontal saw set at about sea level. This
+agent is clearly the surface agitation of the water; it is the
+wind-raised wave.
+
+As a wave comes up the shelving bench the crest topples forward
+and the wave "breaks," striking a blow whose force is measured by
+the momentum of all its tons of falling water. On the coast of
+Scotland the force of the blows struck by the waves of the
+heaviest storms has sometimes exceeded three tons to the square
+foot. But even a calm sea constantly chafes the shore. It heaves
+in gentle undulations known as the ground swell, the result of
+storms perhaps a thousand miles distant, and breaks on the shore
+in surf.
+
+The blows of the waves are not struck with clear water only, else
+they would have little effect on cliffs of solid rock. Storm waves
+arm themselves with the sand and gravel, the cobbles, and even the
+large bowlders which lie at the base of the cliff, and beat
+against it with these hammers of stone.
+
+Where a precipice descends sheer into deep water, waves swash up
+and down the face of the rocks but cannot break and strike
+effective blows. They therefore erode but little until the talus
+fallen from the cliff is gradually built up beneath the sea to the
+level at which the waves drag bottom upon it and break.
+
+Compare the ways in which different agents abrade. The wind
+lightly brushes sand and dust over exposed surfaces of rock.
+Running water sweeps fragments of various sizes along its
+channels, holding them with a loose hand. Glacial ice grinds the
+stones of its ground moraine against the underlying rock with the
+pressure of its enormous weight. The wave hurls fragments of rock
+against the sea cliff, bruising and battering it by the blow. It
+also rasps the bench as it drags sand and gravel to and fro upon
+it.
+
+WEATHERING OF SEA CLIFFS. The sea cliff furnishes the weapons for
+its own destruction. They are broken from it not only by the wave
+but also by the weather. Indeed the sea cliff weathers more
+rapidly, as a rule, than do rock ledges inland. It is abundantly
+wet with spray. Along its base the ground water of the neighboring
+land finds its natural outlet in springs which under mine it.
+Moreover, it is unprotected by any shield of talus. Fragments of
+rock as they fall from its face are battered to pieces by the
+waves and swept out to sea. The cliff is thus left exposed to the
+attack of the weather, and its retreat would be comparatively
+rapid for this reason alone.
+
+Sea cliffs seldom overhang, but commonly, as in Figure 134, slope
+seaward, showing that the upper portion has retreated at a more
+rapid rate than has the base. Which do you infer is on the whole
+the more destructive agent, weathering or the wave?
+
+Draw a section of a sea cliff cut in well jointed rocks whose
+joints dip toward the land. Draw a diagram of a sea cliff where
+the joints dip toward the sea.
+
+SEA CAVES. The wave does not merely batter the face of the cliff.
+Like a skillful quarryman it inserts wedges in all natural
+fissures, such as joints, and uses explosive forces. As a wave
+flaps against a crevice it compresses the air within with the
+sudden stroke; as it falls back the air as suddenly expands. On
+lighthouses heavily barred doors have been burst outward by the
+explosive force of the air within, as it was released from
+pressure when a partial vacuum was formed by the refluence of the
+wave. Where a crevice is filled with water the entire force of the
+blow of the wave is transmitted by hydraulic pressure to the sides
+of the fissure. Thus storm waves little by little pry and suck the
+rock loose, and in this way, and by the blows which they strike
+with the stones of the beach, they quarry out about a joint, or
+wherever the rock may be weak, a recess known as a SEA CAVE,
+provided that the rock above is coherent enough to form a roof.
+Otherwise an open chasm results.
+
+BLOWHOLES AND SEA ARCHES. As a sea cave is drilled back into the
+rock, it may encounter a joint or crevice opened to the surface by
+percolating water. The shock of the waves soon enlarges this to a
+blowhole, which one may find on the breezy upland, perhaps a
+hundred yards and more back from the cliff's edge. In quiet
+weather the blowhole is a deep well; in storm it plays a fountain
+as the waves drive through the long tunnel below and spout their
+spray high in air in successive jets. As the roof of the cave thus
+breaks down in the rear, there may remain in front for a while a
+sea arch, similar to the natural bridges of land caverns.
+
+STACKS AND WAVE-CUT ISLANDS. As the sea drives its tunnels and
+open drifts into the cliff, it breaks through behind the
+intervening portions and leaves them isolated as stacks, much as
+monuments are detached from inland escarpments by the weather; and
+as the sea cliff retreats, these remnant masses may be left behind
+as rocky islets. Thus the rock bench is often set with stacks,
+islets in all stages of destruction, and sunken reefs, all wrecks
+of the land testifying to its retreat before the incessant attack
+of the waves.
+
+COVES. Where zones of soft or closely jointed rock outcrop along a
+shore, or where minor water courses conic down to the sea and aid
+in erosion, the shore is worn back in curved reentrants called
+coves; while the more resistant rocks on either hand are left
+projecting as headlands (Fig. 139). After coves are cut back a
+short distance by the waves, the headlands come to protect them,
+as with breakwaters, and prevent their indefinite retreat. The
+shore takes a curve of equilibrium, along which the hard rock of
+the exposed headland and the weak rock of the protected cove wear
+back at an equal rate.
+
+RATE OF RECESSION. The rate at which a shore recedes depends on
+several factors. In soft or incoherent rocks exposed to violent
+storms the retreat is so rapid as to be easily measured. The coast
+of Yorkshire, England, whose cliffs are cut in glacial drift,
+loses seven feet a year on the average, and since the Norman
+conquest a strip a mile wide, with farmsteads and villages and
+historic seaports, has been devoured by the sea. The sandy south
+shore of Martha's Vineyard wears back three feet a year. But hard
+rocks retreat so slowly that their recession has seldom been
+measured by the records of history.
+
+SHORE DRIFT
+
+BOWLDER AND PEBBLE BEACHES. About as fast as formed the waste of
+the sea cliff is swept both along the shore and out to sea. The
+road of waste along shore is the BEACH. We may also define the
+beach as the exposed edge of the sheet of sediment formed by the
+carriage of land waste out to sea. At the foot of sea cliffs,
+where the waves are pounding hardest, one commonly finds the rock
+bench strewn on its inner margin with large stones, dislodged by
+the waves and by the weather and some-what worn on their corners
+and edges. From this BOWLDER BEACH the smaller fragments of waste
+from the cliff and the fragments into which the bowlders are at
+last broken drift on to more sheltered places and there accumulate
+in a PEBBLE BEACH, made of pebbles well rounded by the wear which
+they have suffered. Such beaches form a mill whose raw material is
+constantly supplied by the cliff. The breakers of storms set it in
+motion to a depth of several feet, grinding the pebbles together
+with a clatter to be heard above the roar of the surf. In such a
+rock crusher the life of a pebble is short. Where ships have
+stranded on our Atlantic coast with cargoes of hard-burned brick
+or of coal, a year of time and a drift of five miles along the
+shore have proved enough to wear brick and coal to powder. At no
+great distance from their source, therefore, pebble beaches give
+place to beaches of sand, which occupy the more sheltered reaches
+of the shore.
+
+SAND BEACHES. The angular sand grains of various minerals into
+which pebbles are broken by the waves are ground together under
+the beating surf and rounded, and those of the softer minerals are
+crushed to powder. The process, however, is a slow one, and if we
+study these sand grains under a lens we may be surprised to see
+that, though their corners and edges have been blunted, they are
+yet far from the spherical form of the pebbles from which they
+were derived. The grains are small, and in water they have lost
+about half their weiglit in air; the blows which they strike one
+another are therefore weak. Besides, each grain of sand of the wet
+beach is protected by a cushion of water from the blows of its
+neighbors.
+
+The shape and size of these grains and the relative proportion of
+grains of the softer minerals which still remain give a rough
+measure of the distance in space and time which they have traveled
+from their source. The sand of many beaches, derived from the
+rocks of adjacent cliffs or brought in by torrential streams from
+neighboring highlands, is dark with grains of a number of minerals
+softer than quartz. The white sand of other beaches, as those of
+the east coast of Florida, is almost wholly composed of quartz
+grains; for in its long travel down the Atlantic coast the weaker
+minerals have been worn to powder and the hardest alone survive.
+
+How does the absence of cleavage in quartz affect the durability
+of quartz sand?
+
+HOW SHORE DRIFT MIGRATES. It is under the action of waves and
+currents that shore drift migrates slowly along a coast. Where
+waves strike a coast obliquely they drive the waste before them
+little by little along the shore. Thus on a north-south coast,
+where the predominant storms are from the northeast, there will be
+a migration of shore drift southwards.
+
+All shores are swept also by currents produced by winds and tides.
+These are usually far too gentle to transport of themselves the
+coarse materials of which beaches are made. But while the wave
+stirs the grains of sand and gravel, and for a moment lifts them
+from the bottom, the current carries them a step forward on their
+way. The current cannot lift and the wave cannot carry, but
+together the two transport the waste along the shore. The road of
+shore drift is therefore the zone of the breaking waves.
+
+THE BAY-HEAD BEACH. As the waste derived from the wear of waves
+and that brought in by streams is trailed along a coast it
+assumes, under varying conditions, a number of distinct forms.
+When swept into the head of a sheltered bay it constitutes the
+bay-head beach. By the highest storm waves the beach is often
+built higher than the ground immediately behind it, and forms a
+dam inclosing a shallow pond or marsh.
+
+THE BAY BAR. As the stream of shore drift reaches the mouth of a
+bay of some size it often occurs that, instead of turning in, it
+sets directly across toward the opposite headland. The waste is
+carried out from shore into the deeper waters of the bay mouth;
+where it is no longer supported by the breaking waves, and sinks
+to the bottom. The dump is gradually built to the surface as a
+stubby spur, pointing across the bay, and as it reaches the zone
+of wave action current and wave can now combine to carry shore
+drift along it, depositing their load continually at the point of
+the spur. An embankment is thus constructed in much the same
+manner as a railway fill, which, while it is building, serves as a
+roadway along which the dirt from an adjacent cut is carted to be
+dumped at the end. When the embankment is completed it bridges the
+bay with a highway along which shore drift now moves without
+interruption, and becomes a bay bar.
+
+INCOMPLETE BAY BARS. Under certain conditions the sea cannot carry
+out its intention to bridge a bay. Rivers discharging in bays
+demand open way to the ocean. Strong tidal currents also are able
+to keep open channels scoured by their ebb and flow. In such cases
+the most that land waste can do is to build spits and shoals,
+narrowing and shoaling the channel as much as possible. Incomplete
+bay bars sometimes have their points recurved by currents setting
+at right angles to the stream of shore drift and are then
+classified as HOOKS (Fig. 142).
+
+SAND REEFS. On low coasts where shallow water extends some
+distance out, the highway of shore drift lies along a low, narrow
+ridge, termed the sand reef, separated from the land by a narrow
+stretch of shallow water called the LAGOON. At intervals the reef
+is held open by INLETS,--gaps through which the tide flows and
+ebbs, and by which the water of streams finds way to the sea.
+
+No finer example of this kind of shore line is to be found in the
+world than the coast of Texas. From near the mouth of the Rio
+Grande a continuous sand reef draws its even curve for a hundred
+miles to Corpus Christi Pass, and the reefs are but seldom
+interrupted by inlets as far north as Galveston Harbor. On this
+coast the tides are variable and exceptionally weak, being less
+than one foot in height, while the amount of waste swept along the
+shore is large. The lagoon is extremely shallow, and much of it is
+a mud flat too shoal for even small boats. On the coast of New
+Jersey strong tides are able to keep open inlets at intervals of
+from two to twenty miles in spite of a heavy alongshore drift.
+
+Sand reefs are formed where the water is so shallow near shore
+that storm waves cannot run in it and therefore break some
+distance out from land. Where storm waves first drag bottom they
+erode and deepen the sea floor, and sweep in sediment as far as
+the line where they break. Here, where they lose their force, they
+drop their load and beat up the ridge which is known as the sand
+reef when it reaches the surface.
+
+SHORES OF ELEVATION AND DEPRESSION
+
+Our studies have already brought to our notice two distinct forms
+of strand lines,--one the high, rocky coast cut back to cliffs by
+the attack of the waves, and the other the low, sandy coast where
+the waves break usually upon the sand reef. To understand the
+origin of these two types we must know that the meeting place of
+sea and land is determined primarily by movements of the earth's
+crust. Where a coast land emerges the--shore line moves seaward;
+where it is being submerged the shore line advances on the land.
+
+SHORES OF ELEVATION. The retreat of the sea, either because of a
+local uplift of the land or for any other reason, such as the
+lowering of any portion of ocean bottom, lays bare the inner
+margin of the sea floor. Where the sea floor has long received the
+waste of the land it has been built up to a smooth, subaqueous
+plain, gently shelving from the land. Since the new shore line is
+drawn across this even surface it is simple and regular, and is
+bordered on the one side by shallow water gradually deepening
+seaward, and on the other by low land composed of material which
+has not yet thoroughly consolidated to firm rock. A sand reef is
+soon beaten up by the waves, and for some time conditions will
+favor its growth. The loss of sand driven into the lagoon beyond,
+and of that ground to powder by the surf and carried out to sea,
+is more than made up by the stream of alongshore drift, and
+especially by the drag of sediments to the reef by the waves as
+they deepen the sea floor on its seaward side.
+
+Meanwhile the lagoon gradually fills with waste from the reef and
+from the land. It is invaded by various grasses and reeds which
+have learned to grow in salt and brackish water; the marsh, laid
+bare only at low tide, is built above high tide by wind drift and
+vegetable deposits, and becomes a meadow, soldering the sand reef
+to the mainland.
+
+While the lagoon has been filling, the waves have been so
+deepening the sea floor off the sand reef that at last they are
+able to attack it vigorously. They now wear it back, and, driving
+the shore line across the lagoon or meadow, cut a line of low
+cliffs on the mainland. Such a shore is that of Gascony in
+southwestern France,--a low, straight, sandy shore, bordered by
+dunes and unprotected by reefs from the attack of the waves of the
+Bay of Biscay.
+
+We may say, then, that on shores of elevation the presence of sand
+reefs and lagoons indicates the stage of youth, while the absence
+of these features and the vigorous and unimpeded attack by the sea
+upon the mainland indicate the stage of maturity. Where much waste
+is brought in by rivers the maturity of such a coast may be long
+delayed. The waste from the land keeps the sea shallow offshore
+and constantly renews the sand reef. The energy of the waves is
+consumed in handling shore drift, and no energy is left for an
+effective attack upon the land. Indeed, with an excessive amount
+of waste brought down by streams the land may be built out and
+encroach temporarily upon the sea; and not until long denudation
+has lowered the land, and thus decreased the amount of waste from
+it, may the waves be able to cut through the sand reef and thus
+the coast reach maturity.
+
+SHORES OF DEPRESSION
+
+Where a coastal region is undergoing submergence the shore line
+moves landward. The horizontal plane of the sea now intersects an
+old land surface roughened by subaerial denudation. The shore line
+is irregular and indented in proportion to the relief of the land
+and the amount of the submergence which the land has suffered. It
+follows up partially submerged valleys, forming bays, and bends
+round the divides, leaving them to project as promontories and
+peninsulas. The outlines of shores of depression are as varied as
+are the forms of the land partially submerged. We give a few
+typical illustrations.
+
+The characteristics of the coast of Maine are due chiefly to the
+fact that a mountainous region of hard rocks, once worn to a
+peneplain, and after a subsequent elevation deeply dissected by
+north-south valleys, has subsided, the depression amounting on its
+southern margin to as much as six hundred feet below sea level.
+Drowned valleys penetrate the land in long, narrow bays, and
+rugged divides project in long, narrow land arms prolonged seaward
+by islands representing the high portions of their extremities. Of
+this exceedingly ragged shore there are said to be two thousand
+miles from the New Brunswick boundary as far west as Portland,--a
+straight-line distance of but two hundred miles. Since the time of
+its greatest depression the land is known to have risen some three
+hundred feet; for the bays have been shortened, and the waste with
+which their floors were strewn is now in part laid bare as clay
+plains about the bay heads and in narrow selvages about the
+peninsulas and islands.
+
+The coast of Dalmatia, on the Adriatic Sea, is characterized by
+long land arms and chains of long and narrow islands, all parallel
+to the trend of the coast. A region of parallel mountain ranges
+has been depressed, and the longitudinal valleys which lie between
+them are occupied by arms of the sea.
+
+Chesapeake Bay is a branching bay due to the depression of an
+ancient coastal plain which, after having emerged from the sea,
+was channeled with broad, shallow valleys. The sea has invaded the
+valley of the trunk stream and those of its tributaries, forming a
+shallow bay whose many branches are all directed toward its axis
+(Fig. 146).
+
+Hudson Bay, and the North, the Baltic, and the Yellow seas are
+examples where the sinking of the land has brought the sea in over
+low plains of large extent, thus deeply indenting the continental
+out-line. The rise of a few hundred feet would restore these
+submerged plains to the land.
+
+THE CYCLE OF SHORES OF DEPRESSION. In its infantile stage the
+outline of a shore of depression depends almost wholly on the
+previous relief of the land, and but little on erosion by the sea.
+Sea cliffs and narrow benches appear where headlands and outlying
+islands have been nipped by the waves. As yet, little shore waste
+has been formed. The coast of Maine is an example of this stage.
+
+In early youth all promontories have been strongly cliffed, and
+under a vigorous attack of the sea the shore of open bays may be
+cut back also. Sea stacks and rocky islets, caves and coves, make
+the shore minutely ragged. The irregularity of the coast, due to
+depression, is for a while increased by differential wave wear on
+harder and softer rocks. The rock bench is still narrow. Shore
+waste, though being produced in large amounts, is for the most
+part swept into deeper water and buried out of sight. Examples of
+this stage are the east coast of Scotland and the California coast
+near San Francisco.
+
+Later youth is characterized by a large accumulation of shore
+waste. The rock bench has been cut back so that it now furnishes a
+good roadway for shore drift. The stream of alongshore drift grows
+larger and larger, filling the heads of the smaller bays with
+beaches, building spits and hooks, and tying islands with sand
+bars to the mainland. It bridges the larger bays with bay bars,
+while their length is being reduced as their inclosing
+promontories are cut back by the waves. Thus there comes to be a
+straight, continuous, and easy road, no longer interrupted by
+headlands and bays, for the transportation of waste alongshore.
+The Baltic coast of Germany is in this stage.
+
+All this while streams have been busy filling with delta deposits
+the bays into which they empty. By these steps a coast gradually
+advances to MATURITY, the stage when the irregularities due to
+depression have been effaced, when outlying islands formed by
+subsidence have been planed away, and when the shore line has been
+driven back behind the former bay heads. The sea now attacks the
+land most effectively along a continuous and fairly straight line
+of cliffs. Although the first effect of wave wear was to increase
+the irregularities of the shore, it sooner or later rectifies it,
+making it simple and smooth. Northwestern France may be cited as
+an upland plain, dissected and depressed, whose coast has reached
+maturity.
+
+In the OLD AGE of coasts the rock bench is cut back so far that
+the waves can no longer exert their full effect upon the shore.
+Their energy is dissipated in moving shore drift hither and
+thither and in abrading the bench when they drag bottom upon it.
+Little by little the bench is deepened by tidal currents and the
+drag of waves; but this process is so slow that meanwhile the sea
+cliffs melt down under the weather, and the bench becomes a broad
+shoal where waves and tides gradually work over the waste from the
+land to greater fineness and sweep it out to sea.
+
+PLAINS OF MARINE ABRASION. While subaerial denudation reduces the
+land to baselevel, the sea is sawing its edges to WAVE BASE, i.e.
+the lowest limit of the wave's effective wear. The widened rock
+bench forms when uplifted a plain of marine abrasion, which like
+the peneplain bevels across strata regardless of their various
+inclinations and various degrees of hardness.
+
+How may a plain of marine abrasion be expected to differ from a
+peneplain in its mantle of waste?
+
+Compared with subaerial denudation, marine abrasion is a
+comparatively feeble agent. At the rate of five feet per century--
+a higher rate than obtains on the youthful rocky, coast of
+Britain--it would require more than ten million years to pare a
+strip one hundred miles wide from the margin of a continent, a
+time sufficient, at the rate at which the Mississippi valley is
+now being worn away, for subaerial denudation to lower the lands
+of the globe to the level of the sea.
+
+Slow submergence favors the cutting of a wide rock bench. The
+water continually deepens upon the bench; storm waves can
+therefore always ride in to the base of the cliffs and attack them
+with full force; shore waste cannot impede the onset of the waves,
+for it is continually washed out in deeper water below wave base.
+
+BASAL CONGOLMERATES. As the sea marches across the land during a
+slow submergence, the platform is covered with sheets of sea-laid
+sediments. Lowest of these is a conglomerate,--the bowlder and
+pebble beach, widened indefinitely by the retreat of the cliffs at
+whose base it was formed, and preserved by the finer deposits laid
+upon it in the constantly deepening water as the land subsides.
+Such basal conglomerates are not uncommon among the ancient rocks
+of the land, and we may know them by their rounded pebbles and
+larger stones, composed of the same kind of rock as that of the
+abraded and evened surface on which they lie.
+
+
+
+
+
+CHAPTER VIII
+
+OFFSHORE AND DEEP-SEA DEPOSITS
+
+
+The alongshore deposits which we have now studied are the exposed
+edge of a vast subaqueous sheet of waste which borders the
+continents and extends often for as much as two or three hundred
+miles from land. Soundings show that offshore deposits are laid in
+belts parallel to the coast, the coarsest materials lying nearest
+to the land and the finest farthest out. The pebbles and gravel
+and the clean, coarse sand of beaches give place to broad
+stretches of sand, which grows finer and finer until it is
+succeeded by sheets of mud. Clearly there is an offshore movement
+of waste by which it is sorted, the coarser being sooner dropped
+and the finer being carried farther out.
+
+OFFSHORE DEPOSITS
+
+The debris torn by waves from rocky shores is far less in amount
+than the waste of the land brought down to the sea by rivers,
+being only one thirty-third as great, according to a conservative
+estimate. Both mingle alongshore in all the forms of beach and bar
+that have been described, and both are together slowly carried out
+to sea. On the shelving ocean floor waste is agitated by various
+movements of the unquiet water,--by the undertow (an outward-
+running bottom current near the shore), by the ebb and flow of
+tides, by ocean currents where they approach the land, and by
+waves and ground swells, whose effects are sometimes felt to a
+depth of six hundred feet. By all these means the waste is slowly
+washed to and fro, and as it is thus ground finer and finer and
+its soluble parts are more and more dissolved, it drifts farther
+and farther out from land. It is by no steady and rapid movement
+that waste is swept from the shore to its final resting place. Day
+after day and century after century the grains of sand and
+particles of mud are shifted to and fro, winnowed and spread in
+layers, which are destroyed and rebuilt again and again before
+they are buried safe from further disturbance.
+
+These processes which are hidden from the eye are among the most
+important of those with which our science has to do; for it is
+they which have given shape to by far the largest part of the
+stratified rocks of which the land is made.
+
+THE CONTINENTAL DELTA. This fitting term has been recently
+suggested for the sheet of waste slowly accumulating along the
+borders of the continents. Within a narrow belt, which rarely
+exceeds two or three hundred miles, except near the mouths of
+muddy rivers such as the Amazon and Congo, nearly all the waste of
+the continent, whether worn from its surface by the weather, by
+streams, by glaciers, or by the wind, or from its edge by the
+chafing of the waves, comes at last to its final resting place.
+The agencies which spread the material of the continental delta
+grow more and more feeble as they pass into deeper and more quiet
+water away from shore. Coarse materials are therefore soon dropped
+along narrow belts near land. Gravels and coarse sands lie in
+thick, wedge-shaped masses which thin out seaward rapidly and give
+place to sheets of finer sand.
+
+SEA MUDS. Outermost of the sediments derived from the waste of the
+continents is a wide belt of mud; for fine clays settle so slowly,
+even in sea water,--whose saltness causes them to sink much faster
+than they would in fresh water,--that they are wafted far before
+they reach a bottom where they may remain undisturbed. Muds are
+also found near shore, carpeting the floors of estuaries, and
+among stretches of sandy deposits in hollows where the more quiet
+water has permitted the finer silt to rest.
+
+Sea muds are commonly bluish and consolidate to bluish shales; the
+red coloring matter brought from land waste--iron oxide--is
+altered to other iron compounds by decomposing organic matter in
+the presence of sea water. Yellow and red muds occur where the
+amount of iron oxide in the silt brought down to the sea by rivers
+is too great to be reduced, or decomposed, by the organic matter
+present.
+
+Green muds and green sand owe their color to certain chemical
+changes which take place where waste from the land accumulates on
+the sea floor with extreme slowness. A greenish mineral called
+GLAUCONITE--a silicate of iron and alumina--is then formed. Such
+deposits, known as GREEN SAND, are now in process of making in
+several patches off the Atlantic coast, and are found on the
+coastal plain of New Jersey among the offshore deposits of earlier
+geological ages.
+
+ORGANIC DEPOSITS. Living creatures swarm along the shore and on
+the shallows out from land as nowhere else in the ocean. Seaweed
+often mantles the rock of the sea cliff between the levels of high
+and low tide, protecting it to some degree from the blows of
+waves. On the rock bench each little pool left by the ebbing tide
+is an aquarium abounding in the lowly forms of marine life. Below
+low-tide level occur beds of molluscous shells, such as the
+oyster, with countless numbers of other humble organisms. Their
+harder parts--the shells of mollusks, the white framework of
+corals, the carapaces of crabs and other crustaceans, the shells
+of sea urchins, the bones and teeth of fishes--are gradually
+buried within the accumulating sheets of sediment, either whole
+or, far more often, broken into fragments by the waves.
+
+By means of these organic remains each layer of beach deposits and
+those of the continental delta may contain a record of the life of
+the time when it was laid. Such a record has been made ever since
+living creatures with hard parts appeared upon the globe. We shall
+find it sealed away in the stratified rocks of the continents,--
+parts of ancient sea deposits now raised to form the dry land.
+Thus we have in the traces of living creatures found in the rocks,
+i.e. in fossils, a history of the progress of life upon the
+planet.
+
+MOLLUSCOUS SHELL DEPOSITS. The forms of marine life of importance
+in rock making thrive best in clear water, where little sediment
+is being laid, and where at the same time the depth is not so
+great as to deprive them of needed light, heat, and of sufficient
+oxygen absorbed by sea water from the air. In such clear and
+comparatively shallow water there often grow countless myriads of
+animals, such as mollusks and corals, whose shells and skeletons
+of carbonate of lime gradually accumulate in beds of limestone.
+
+A shell limestone made of broken fragments cemented together is
+sometimes called COQUINA, a local term applied to such beds
+recently uplifted from the sea along the coast of Florida (Fig.
+149).
+
+OOLITIC limestone (oon, an egg; lithos, a stone) is so named from
+the likeness of the tiny spherules which compose it to the roe of
+fish. Corals and shells have been pounded by the waves to
+calcareous sand, and each grain has been covered with successive
+concentric coatings of lime carbonate deposited about it from
+solution.
+
+The impalpable powder to which calcareous sand is ground by the
+waves settles at some distance from shore in deeper and quieter
+water as a limy silt, and hardens into a dense, fine-grained
+limestone in which perhaps no trace of fossil is found to suggest
+the fact that it is of organic origin.
+
+From Florida Keys there extends south to the trough of Florida
+Straits a limestone bank covered by from five hundred and forty to
+eighteen hundred feet of water. The rocky bottom consists of
+limestone now slowly building from the accumulation of the remains
+of mollusks, small corals, sea urchins, worms with calcareous
+tubes, and lime-secreting seaweed, which live upon its surface.
+
+Where sponges and other silica-secreting organisms abound on
+limestone banks, silica forms part of the accumulated deposit,
+either in its original condition, as, for example, the spicules of
+sponges, or gathered into concretions and layers of flint.
+
+Where considerable mud is being deposited along with carbonate of
+lime there is in process of making a clayey limestone or a limy
+shale; where considerable sand, a sandy limestone or a limy
+sandstone.
+
+CONSOLIDATION OF OFFSHORE DEPOSITS. We cannot doubt that all these
+loose sediments of the sea floor are being slowly consolidated to
+solid rock. They are soaked with water which carries in solution
+lime carbonate and other cementing substances. These cements are
+deposited between the fragments of shells and corals, the grains
+of sand and the particles of mud, binding them together into firm
+rock. Where sediments have accumulated to great thickness the
+lower portions tend also to consolidate under the weight of the
+overlying beds. Except in the case of limestones, recent sea
+deposits uplifted to form land are seldom so well cemented as are
+the older strata, which have long been acted upon by underground
+waters deep below the surface within the zone of cementation, and
+have been exposed to view by great erosion.
+
+RIPPLE MARKS, SUN CRACKS, ETC. The pulse of waves and tidal
+currents agitates the loose material of offshore deposits,
+throwing it into fine parallel ridges called ripple marks. One may
+see this beautiful ribbing imprinted on beach sands uncovered by
+the outgoing tide, and it is also produced where the water is of
+considerable depth. While the tide is out the surface of shore
+deposits may be marked by the footprints of birds and other
+animals, or by the raindrops of a passing shower.
+
+The mud of flats, thus exposed to the sun and dried, cracks in a
+characteristic way. Such markings may be covered over with a thin
+layer of sediment at the next flood tide and sealed away as a
+lasting record of the manner and place in which the strata were
+laid. In Figure 150 we have an illustration of a very ancient
+ripple-marked sand consolidated to hard stone, uplifted and set on
+edge by movements of the earth's crust, and exposed to open air
+after long erosion.
+
+STRATIFICATION. For the most part the sheet of sea-laid waste is
+hidden from our sight. Where its edge is exposed along the shore
+we may see the surface markings which have just been noticed.
+Soundings also, and the observations made in shallow waters by
+divers, tell something of its surface; but to learn more of its
+structures we must study those ancient sediments which have been
+lifted from the sea and dissected by subaerial agencies. From them
+we ascertain that sea deposits are stratified. They lie in
+distinct layers which often differ from one another in thickness,
+in size of particles, and perhaps in color. They are parted by
+bedding planes, each of which represents either a change in
+material or a pause during which deposition ceased and the
+material of one layer had time to settle and become somewhat
+consolidated before the material of the next was laid upon
+it. Stratification is thus due to intermittently acting forces,
+such as the agitation of the water during storms, the flow and ebb
+of the tide, and the shifting channels of tidal currents. Off the
+mouths of rivers, stratification is also caused by the coarser and
+more abundant material brought down at time of floods being laid
+on the finer silt which is discharged during ordinary stages.
+
+How stratified deposits are built up is well illustrated in the
+flats which border estuaries, such as the Bay of Fundy. Each
+advance of the tide spreads a film of mud, which dries and hardens
+in the air during low water before another film is laid upon it by
+the next incoming tidal flood. In this way the flats have been
+covered by a clay which splits into leaves as thin as sheets of
+paper.
+
+It is in fine material, such as clays and shales and limestones,
+that the thinnest and most uniform layers, as well as those of
+widest extent, occur. On the other hand, coarse materials are
+commonly laid in thick beds, which soon thin out seaward and give
+place to deposits of finer stuff. In a general way strata are laid
+in well-nigh horizontal sheets, for the surface on which they are
+laid is generally of very gentle inclination. Each stratum,
+however, is lenticular, or lenslike, in form, having an area where
+it is thickest, and thinning out thence to its edges, where it is
+overlapped by strata similar in shape.
+
+CROSS BEDDING. There is an apparent exception to this rule where
+strata whose upper and lower surfaces may be about horizontal are
+made up of layers inclined at angles which may be as high as the
+angle of repose. In this case each stratum grew by the addition
+along its edge of successive layers of sediment, precisely as does
+a sand bar in a river, the sand being pushed continuously over the
+edge and coming to rest on a sloping surface. Shoals built by
+strong and shifting tidal currents often show successive strata in
+which the cross bedding is inclined in different directions.
+
+THICKNESS OF SEA DEPOSITS. Remembering the vast amount of
+material denuded from the land and deposited offshore, we should
+expect that with the lapse of time sea deposits would have grown
+to an enormous thickness. It is a suggestive fact that, as a rule,
+the profile of the ocean bed is that of a soup plate,--a basin
+surrounded by a flaring rim. On the CONTINENTAL SHELF, as the rim
+is called, the water is seldom more than six hundred feet in depth
+at the outer edge, and shallows gradually towards shore. Along the
+eastern coast of the United States the continental shelf is from
+fifty to one hundred and more miles in width; on the Pacific coast
+it is much narrower. So far as it is due to upbuilding, a wide
+continental shelf, such as that of the Atlantic coast, implies a
+massive continental delta thousands of feet in thickness. The
+coastal plain of the Atlantic states may be regarded as the
+emerged inner margin of this shelf, and borings made along the
+coast probe it to the depth of as much as three thousand feet
+without finding the bottom of ancient offshore deposits.
+Continental shelves may also be due in part to a submergence of
+the outer margin of a continental plateau and to marine abrasion.
+
+DEPOSITION OF SEDIMENTS AND SUBSIDENCE. The stratified rocks of
+the land show in many places ancient sediments which reach a
+thickness which is measured in miles, and which are yet the
+product of well-nigh continuous deposition. Such strata may prove
+by their fossils and by their composition and structure that they
+were all laid offshore in shallow water. We must infer that,
+during the vast length of time recorded by the enormous pile, the
+floor of the sea along the coast was slowly sinking, and that the
+trough was constantly being filled, foot by foot, as fast as it
+was depressed. Such gradual, quiet movements of the earth's crust
+not only modify the outline of coasts, as we have seen, but are of
+far greater geological importance in that they permit the making
+of immense deposits of stratified rock.
+
+A slow subsidence continued during long time is recorded also in
+the succession of the various kinds of rock that come to be
+deposited in the same area. As the sea transgresses the land, i.e.
+encroaches upon it, any given part of the sea bottom is brought
+farther and farther from the shore. The basal conglomerate formed
+by bowlder and pebble beaches comes to be covered with sheets of
+sand, and these with layers of mud as the sea becomes deeper and
+the shore more remote; while deposits of limestone are made when
+at last no waste is brought to the place from the now distant
+land, and the water is left clear for the growth of mollusks and
+other lime-secreting organisms.
+
+RATE OF DEPOSITION. As deposition in the sea corresponds to
+denudation on the land, we are able to make a general estimate of
+the rate at which the former process is going on. Leaving out of
+account the soluble matter removed, the Mississippi is lowering
+its basin at the rate of one foot in five thousand years, and we
+may assume this as the average rate at which the earth's land
+surface of fifty-seven million square miles is now being denuded
+by the removal of its mechanical waste. But sediments from the
+land are spread within a zone but two or three hundred miles in
+width along the margin of the continents, a line one hundred
+thousand miles long. As the area of deposition--about twenty-five
+million square miles--is about one half the area of denudation,
+the average rate of deposition must be twice the average rate of
+denudation, i.e. about one foot in twenty-five hundred years. If
+some deposits are made much more rapidly than this, others are
+made much more slowly. If they were laid no faster than the
+present average rate, the strata of ancient sea deposits exposed
+in a quarry fifty feet deep represent a lapse of at least one
+hundred and twenty-five thousand years, and those of a formation
+five hundred feet thick required for their accumulation one
+million two hundred and fifty thousand years.
+
+THE SEDIMENTARY RECORD AND THE DENUDATION CYCLE. We have seen that
+the successive stages in a cycle of denudation, such as that by
+which a land mass of lofty mountains is worn to low plains, are
+marked each by its own peculiar land forms, and that the forms of
+the earlier stages are more or less completely effaced as the
+cycle draws toward an end. Far more lasting records of each stage
+are left in the sedimentary deposits of the continental delta.
+
+Thus, in the youth of such a land mass as we have mentioned,
+torrential streams flowing down the steep mountain sides deliver
+to the adjacent sea their heavy loads of coarse waste, and thick
+offshore deposits of sand and gravel (Fig. 156) record the high
+elevation of the bordering land. As the land is worn to lower
+levels, the amount and coarseness of the waste brought to the sea
+diminishes, until the sluggish streams carry only a fine silt
+which settles on the ocean floor near to land in wide sheets of
+mud which harden into shale. At last, in the old age of the region
+(Fig. 157), its low plains contribute little to the sea except the
+soluble elements of the rocks, and in the clear waters near the
+land lime-secreting organisms flourish and their remains
+accumulate in beds of limestone. When long-weathered lands
+mantled with deep, well-oxidized waste are uplifted by a gradual
+movement of the earth's crust, and the mantle is rapidly stripped
+off by the revived streams, the uprise is recorded in wide
+deposits of red and yellow clays and sands upon the adjacent ocean
+floor.
+
+Where the waste brought in is more than the waves can easily
+distribute, as off the mouths of turbid rivers which drain
+highlands near the sea, deposits are little winnowed, and are laid
+in rapidly alternating, shaly sandstones and sandy shales.
+
+Where the highlands are of igneous rock, such as granite, and
+mechanical disintegration is going on more rapidly than chemical
+decay, these conditions are recorded in the nature of the deposits
+laid offshore. The waste swept in by streams contains much
+feldspar and other minerals softer and more soluble than quartz,
+and where the waves have little opportunity to wear and winnow it,
+it comes to rest in beds of sandstone in which grains of feldspar
+and other soft minerals are abundant. Such feldspathic sandstones
+are known as ARKOSE.
+
+On the other hand, where the waste supplied to the sea comes
+chiefly from wide, sandy, coastal plains, there are deposited off-
+shore clean sandstones of well-worn grains of quartz alone. In
+such coastal plains the waste of the land is stored for ages.
+Again and again they are abandoned and invaded by the sea as from
+time to time the land slowly emerges and is again submerged. Their
+deposits are long exposed to the weather, and sorted over by the
+streams, and winnowed and worked over again and again by the
+waves. In the course of long ages such deposits thus become
+thoroughly sorted, and the grains of all minerals softer than
+quartz are ground to mud.
+
+DEEP-SEA OOZES AND CLAYS
+
+GLOBIGERINA OOZE. Beyond the reach of waste from the land the
+bottom of the deep sea is carpeted for the most part with either
+chalky ooze or a fine red clay. The surface waters of the warm
+seas swarm with minute and lowly animals belonging to the order of
+the Foraminifera, which secrete shells of carbonate of lime. At
+death these tiny white shells fall through the sea water like
+snowflakes in the air, and, slowly dissolving, seem to melt quite
+away before they can reach depths greater than about three miles.
+Near shore they reach bottom, but are masked by the rapid deposit
+of waste derived from the land. At intermediate depths they mantle
+the ocean floor with a white, soft lime deposit known as
+Globigerina ooze, from a genus of the Foraminifera which
+contributes largely to its formation.
+
+RED CLAY. Below depths of from fifteen to eighteen thousand feet
+the ocean bottom is sheeted with red or chocolate colored clay. It
+is the insoluble residue of seashells, of the debris of submarine
+volcanic eruptions, of volcanic dust wafted by the winds, and of
+pieces of pumice drifted by ocean currents far from the volcanoes
+from which they were hurled. The red clay builds up with such
+inconceivable slowness that the teeth of sharks and the hard ear
+bones of whales may be dredged in large numbers from the deep
+ocean bed, where they have lain unburied for thousands of years;
+and an appreciable part of the clay is also formed by the dust of
+meteorites consumed in the atmosphere,--a dust which falls
+everywhere on sea and land, but which elsewhere is wholly masked
+by other deposits.
+
+The dark, cold abysses of the ocean are far less affected by
+change than any other portion of the surface of the lithosphere.
+These vast, silent plains of ooze lie far below the reach of
+storms. They know no succession of summer and winter, or of night
+and day. A mantle of deep and quiet water protects them from the
+agents of erosion which continually attack, furrow, and destroy
+the surface of the land. While the land is the area of erosion,
+the sea is the area of deposition. The sheets of sediment which
+are slowly spread there tend to efface any inequalities, and to
+form a smooth and featureless subaqueous plain.
+
+With few exceptions, the stratified rocks of the land are proved
+by their fossils and composition to have been laid in the sea; but
+in the same way they are proved to be offshore, shallow-water
+deposits, akin to those now making on continental shelves. Deep-
+sea deposits are absent from the rocks of the land, and we may
+therefore infer that the deep sea has never held sway where the
+continents now are,--that the continents have ever been, as now,
+the elevated portions of the lithosphere, and that the deep seas
+of the present have ever been its most depressed portions.
+
+THE REEF-BUILDING CORALS
+
+In warm seas the most conspicuous of rock-making organisms are the
+corals known as the reef builders. Floating in a boat over a coral
+reef, as, for example, off the south coast of Florida or among the
+Bahamas, one looks down through clear water on thickets of
+branching coral shrubs perhaps as much as eight feet high, and
+hemispherical masses three or four feet thick, all abloom with
+countless minute flowerlike coral polyps, gorgeous in their colors
+of yellow, orange, green, and red. In structure each tiny polyp is
+little more than a fleshy sac whose mouth is surrounded with
+petal-like tentacles, or feelers. From the sea water the polyps
+secrete calcium carbonate and build it up into the stony framework
+which supports their colonies. Boring mollusks, worms, and sponges
+perforate and honeycomb this framework even while its surface is
+covered with myriads of living polyps. It is thus easily broken by
+the waves, and white fragments of coral trees strew the ground
+beneath. Brilliantly colored fishes live in these coral groves,
+and countless mollusks, sea urchins, and other forms of marine
+life make here their home. With the debris from all these sources
+the reef is constantly built up until it rises to low-tide level.
+Higher than this the corals cannot grow, since they are killed by
+a few hours' exposure to the air.
+
+When the reef has risen to wave base, the waves abrade it on the
+windward side and pile to leeward coral blocks torn from their
+foundation, filling the interstices with finer fragments. Thus
+they heap up along the reef low, narrow islands (Fig. 160).
+
+Reef building is a comparatively rapid progress. It has been
+estimated that off Florida a reef could be built up to the surface
+from a depth of fifty feet in about fifteen hundred years.
+
+CORAL LIMESTONES. Limestones of various kinds are due to the reef
+builders. The reef rock is made of corals in place and broken
+fragments of all sizes, cemented together with calcium carbonate
+from solution by infiltrating waters. On the island beaches coral
+sand is forming oolitic limestone, and the white coral mud with
+which the sea is milky for miles about the reef in times of storm
+settles and concretes into a compact limestone of finest grain.
+Corals have been among the most important limestone builders of
+the sea ever since they made their appearance in the early
+geological ages.
+
+The areas on which coral limestone is now forming are large. The
+Great Barrier Reef of Australia, which lies off the north-eastern
+coast, is twelve hundred and fifty miles long, and has a width of
+from ten to ninety miles. Most of the islands of the tropics are
+either skirted with coral reefs or are themselves of coral
+formation.
+
+CONDITIONS OF CORAL GROWTH. Reef-building corals cannot live
+except in clear salt water less, as a rule, than one hundred and
+fifty feet in depth, with a winter temperature not lower than 68
+degrees F. An important condition also is an abundant food supply,
+and this is best secured in the path of the warm oceanic currents.
+
+Coral reefs may be grouped in three classes,--fringing reefs,
+barrier reefs, and atolls.
+
+FRINGING REEFS. These take their name from the fact that they are
+attached as narrow fringes to the shore. An example is the reef
+which forms a selvage about a mile wide along the northeastern
+coast of Cuba. The outer margin, indicated by the line of white
+surf, where the corals are in vigorous growth, rises from about
+forty feet of water. Between this and the shore lies a stretch of
+shoal across which one can wade at low water, composed of coral
+sand with here and there a clump of growing coral.
+
+BARRIER REEFS. Reefs separated from the shore by a ship channel of
+quiet water, often several miles in width and sometimes as much as
+three hundred feet in depth, are known as barrier reefs. The
+seaward face rises abruptly from water too deep for coral growth.
+Low islands are cast up by the waves upon the reef, and inlets
+give place for the ebb and flow of the tides. Along the west coast
+of the island of New Caledonia a barrier reef extends for four
+hundred miles, and for a length of many leagues seldom approaches
+within eight miles of the shore.
+
+ATOLLS. These are ring-shaped or irregular coral islands, or
+island-studded reefs, inclosing a central lagoon. The narrow zone
+of land, like the rim of a great bowl sunken to the water's edge,
+rises hardly more than twenty feet at most above the sea, and is
+covered with a forest of trees such as the cocoanut, whose seeds
+can be drifted to it uninjured from long distances. The white
+beach of coral sand leads down to the growing reef, on whose outer
+margin the surf is constantly breaking. The sea face of the reef
+falls off abruptly, often to depths of thousands of feet, while
+the lagoon varies in depth from a few feet to one hundred and
+fifty or two hundred, and exceptionally measures as much as three
+hundred and fifty feet.
+
+THEORIES OF CORAL REEFS. Fringing reefs require no explanation,
+since the depth of water about them is not greater than that at
+which coral can grow; but barrier reefs and atolls, which may rise
+from depths too great for coral growth demand a theory of their
+origin.
+
+Darwin's theory holds that barrier reefs and atolls are formed
+from fringing reefs by SUBSIDENCE. The rate of sinking cannot be
+greater than that of the upbuilding of the reef, since otherwise
+the corals would be carried below their depth and drowned. The
+process is illustrated in Figure 161, where v represents a
+volcanic island in mid ocean undergoing slow depression, and ss
+the sea level before the sinking began, when the island was
+surrounded by a fringing reef. As the island slowly sinks, the
+reef builds up with equal pace. It rears its seaward face more
+steep than the island slope, and thus the intervening space
+between the sinking, narrowing land and the outer margin of the
+reef constantly widens. In this intervening space the corals are
+more or less smothered with silt from the outer reef and from the
+land, and are also deprived in large measure of the needful supply
+of food and oxygen by the vigorous growth of the corals on the
+outer rim. The outer rim thus becomes a barrier reef and the inner
+belt of retarded growth is deepened by subsidence to a ship
+channel, s's' representing sea level at this time. The final
+stage, where the island has been carried completely beneath the
+sea and overgrown by the contracting reef, whose outer ring now
+forms an atoll, is represented by s"s".
+
+In very many instances, however, atolls and barrier reefs may be
+explained without subsidence. Thus a barrier reef may be formed by
+the seaward growth of a fringing reef upon the talus of its sea
+face. In Figure 162 f is a fringing reef whose outer wall rises
+from about one hundred and fifty feet, the lower limit of the
+reef-building species. At the foot of this submarine cliff a talus
+of fallen blocks t accumulates, and as it reaches the zone of
+coral growth becomes the foundation on which the reef is steadily
+extended seaward. As the reef widens, the polyps of the
+circumference flourish, while those of the inner belt are retarded
+in their growth and at last perish. The coral rock of the inner
+belt is now dissolved by sea water and scoured out by tidal
+currents until it gives place to a gradually deepening ship
+channel, while the outer margin is left as a barrier reef.
+
+In much the same way atolls may be built on any shoal which lies
+within the zone of coral growth. Such shoals may be produced when
+volcanic islands are leveled by waves and ocean currents, and when
+submarine plateaus, ridges, and peaks are built up by various
+organic agencies, such as molluscous and foraminiferal shell
+deposits. The reef-building corals, whose eggs are drifted widely
+over the tropic seas by ocean currents, colonize such submarine
+foundations wherever the conditions are favorable for their
+growth. As the reef approaches the surface the corals of the inner
+area are smothered by silt and starved, and their Submarine
+Volcanic Peak hard parts are dissolved and scoured away; while
+those of the circumference, with abundant food supply, nourish and
+build the ring of the atoll. Atolls may be produced also by the
+backward drift of sand from either end of a crescentic coral reef
+or island, the spits uniting in the quiet water of the lee to
+inclose a lagoon. In the Maldive Archipelago all gradations
+between crescent-shaped islets and complete atoll rings have been
+observed.
+
+In a number of instances where coral reefs have been raised by
+movements of the earth's crust, the reef formation is found to be
+a thin veneer built upon a foundation of other deposits. Thus
+Christmas Island, in the Indian Ocean, is a volcanic pile rising
+eleven hundred feet above sea level and fifteen thousand five
+hundred feet above the bottom of the sea. The summit is a plateau
+surrounded by a rim of hills of reef formation, which represent
+the ring of islets of an ancient atoll. Beneath the reef are thick
+beds of limestone, composed largely of the remains of
+foraminifers, which cover the lavas and fragraental materials of
+the old submarine volcano.
+
+Among the ancient sediments which now form the stratified rocks of
+the land there occur many thin reef deposits, but none are known
+of the immense thickness which modern reefs are supposed to reach
+according to the theory of subsidence.
+
+Barrier and fringing reefs are commonly interrupted off the mouths
+of rivers. Why?
+
+SUMMARY. We have seen that the ocean bed is the goal to which the
+waste of the rocks of the land at last arrives. Their soluble
+parts, dissolved by underground waters and carried to the sea by
+rivers, are largely built up by living creatures into vast sheets
+of limestone. The less soluble portions--the waste brought in by
+streams and the waste of the shore--form the muds and sands of
+continental deltas. All of these sea deposits consolidate and
+harden, and the coherent rocks of the land are thus reconstructed
+on the ocean floor. But the destination is not a final one. The
+stratified rocks of the land are for the most part ancient
+deposits of the sea, which have been lifted above sea level; and
+we may believe that the sediments now being laid offshore are the
+"dust of continents to be," and will some time emerge to form
+additions to the land. We are now to study the movements of the
+earth's crust which restore the sediments of the sea to the light
+of day, and to whose beneficence we owe the habitable lands of the
+present.
+
+
+
+
+
+PART II
+
+INTERNAL GEOLOGICAL AGENCIES
+
+CHAPTER IX
+
+MOVEMENTS OF THE EARTH'S CRUST
+
+
+The geological agencies which we have so far studied--weathering,
+streams, underground waters, glaciers, winds, and the ocean--all
+work upon the earth from without, and all are set in motion by an
+energy external to the earth, namely, the radiant energy of the
+sun. All, too, have a common tendency to reduce the inequalities
+of the earth's surface by leveling the lands and strewing their
+waste beneath the sea.
+
+But despite the unceasing efforts of these external agencies, they
+have not destroyed the continents, which still rear their broad
+plains and great plateaus and mountain ranges above the sea.
+Either, then, the earth is very young and the agents of denudation
+have not yet had time to do their work, or they have been opposed
+successfully by other forces.
+
+We enter now upon a department of our science which treats of
+forces which work upon the earth from within, and increase the
+inequalities of its surface. It is they which uplift and recreate
+the lands which the agents of denudation are continually
+destroying; it is they which deepen the ocean bed and thus
+withdraw its waters from the shores. At times also these forces
+have aided in the destruction of the lands by gradually lowering
+them and bringing in the sea. Under the action of forces resident
+within the earth the crust slowly rises or sinks; from time to
+time it has been folded and broken; while vast quantities of
+molten rock have been pressed up into it from beneath and
+outpoured upon its surface. We shall take up these phenomena in
+the following chapters, which treat of upheavals and depressions
+of the crust, foldings and fractures of the crust, earthquakes,
+volcanoes, the interior conditions of the earth, mineral veins,
+and metamorphism.
+
+OSCILLATIONS OF THE CRUST
+
+Of the various movements of the crust due to internal agencies we
+will consider first those called oscillations, which lift or
+depress large areas so slowly that a long time is needed to
+produce perceptible changes of level, and which leave the strata
+in nearly their original horizontal attitude. These movements are
+most conspicuous along coasts, where they can be referred to the
+datum plane of sea level; we will therefore take our first
+illustrations from rising and sinking shores.
+
+NEW JERSEY. Along the coasts of New Jersey one may find awash at
+high tide ancient shell heaps, the remains of tribal feasts of
+aborigines. Meadows and old forest grounds, with the stumps still
+standing, are now overflowed by the sea, and fragments of their
+turf and wood are brought to shore by waves. Assuming that the sea
+level remains constant, it is clear that the New Jersey coast is
+now gradually sinking. The rate of submergence has been estimated
+at about two feet per century.
+
+On the other hand, the wide coastal plain of New Jersey is made of
+stratified sands and clays, which, as their marine fossils show,
+were outspread beneath the sea. Their present position above sea
+level proves that the land now subsiding emerged in the recent
+past.
+
+The coast of New Jersey is an example of the slow and tranquil
+oscillations of the earth's unstable crust now in progress along
+many shores. Some are emerging from the sea, some are sinking
+beneath it; and no part of the land seems to have been exempt from
+these changes in the past.
+
+EVIDENCES OF CHANGES OF LEVEL. Taking the surface of the sea as a
+level of reference, we may accept as proofs of relative upheaval
+whatever is now found in place above sea level and could have been
+formed only at or beneath it, and as proofs of relative subsidence
+whatever is now found beneath the sea and could only have been
+formed above it.
+
+Thus old strand lines with sea cliffs, wave-cut rock benches, and
+beaches of wave-worn pebbles or sand, are striking proofs of
+recent emergence to the amount of their present height above tide.
+No less conclusive is the presence of sea-laid rocks which we may
+find in the neighboring quarry or outcrop, although it may have
+been long ages since they were lifted from the sea to form part of
+the dry land.
+
+Among common proofs of subsidence are roads and buildings and
+other works of man, and vegetal growths and deposits, such as
+forest grounds and peat beds, now submerged beneath the sea. In
+the deltas of many large rivers, such as the Po, the Nile, the
+Ganges, and the Mississippi, buried soils prove subsidences of
+hundreds of feet; and in several cases, as in the Mississippi
+delta, the depression seems to be now in progress.
+
+Other proofs of the same movement are drowned land forms which are
+modeled only in open air. Since rivers cannot cut their valleys
+farther below the baselevel of the sea than the depths of their
+channels, DROWNED VALLEYS are among the plainest proofs of
+depression. To this class belong Narragansett, Delaware,
+Chesapeake, Mobile, and San Francisco bays, and many other similar
+drowned valleys along the coasts of the United States. Less
+conspicuous are the SUBMARINE CHANNELS which, as soundings show,
+extend from the mouths of a number of rivers some distance out to
+sea. Such is the submerged channel which reaches from New York Bay
+southeast to the edge of the continental shelf, and which is
+supposed to have been cut by the Hudson River when this part of
+the shelf was a coastal plain.
+
+WARPING. In a region undergoing changes of level the rate of
+movement commonly varies in different parts. Portions of an area
+may be rising or sinking, while adjacent portions are stationary
+or moving in the opposite direction. In this way a land surface
+becomes WARPED. Thus, while Nova Scotia and New Brunswick are now
+rising from the level of the sea, Prince Edward Island and Cape
+Breton Island are sinking, and the sea now flows over the site of
+the famous old town of Louisburg destroyed in 1758.
+
+Since the close of the glacial epoch the coasts of Newfoundland
+and Labrador have risen hundreds of feet, but the rate of
+emergence has not been uniform. The old strand line, which stands
+at five hundred and seventy-five feet above tide at St. John's,
+Newfoundland, declines to two hundred and fifty feet near the
+northern point of Labrador.
+
+THE GREAT LAKES is now under-going perceptible warping. Rivers
+enter the lakes from the south and west with sluggish currents and
+deep channels resembling the estuaries of drowned rivers; while
+those that enter from opposite directions are swift and shallow.
+At the western end of Lake Erie are found submerged caves
+containing stalactites, and old meadows and forest grounds are now
+under water. It is thus seen that the water of the lakes is rising
+along their southwestern shores, while from their north-eastern
+shores it is being withdrawn. The region of the Great Lakes is
+therefore warping; it is rising in the northeast as compared with
+the southwest.
+
+From old bench marks and records of lake levels it has been
+estimated that the rate of warping amounts to five inches a
+century for every one hundred miles. It is calculated that the
+water of Lake Michigan is rising at Chicago at the rate of nine or
+ten inches per century. The divide at this point between the
+tributaries of the Mississippi and Lake Michigan is but eight feet
+above the mean stage of the lake. If the canting of the region
+continues at its present rate, in a thousand years the waters of
+the lake will here overflow the divide. In three thousand five
+hundred years all the lakes except Ontario will discharge by this
+outlet, via the Illinois and Mississippi rivers, into the Gulf of
+Mexico. The present outlet by the Niagara River will be left dry,
+and the divide between the St. Lawrence and the Mississippi
+systems will have shifted from Chicago to the vicinity of Buffalo.
+
+PHYSIOGRAPHIC EFFECTS OF OSCILLATIONS. We have already mentioned
+several of the most important effects of movements of elevation
+and depression, such as their effects on rivers, the mantle of
+waste, and the forms of coasts. Movements of elevation--including
+uplifts by folding and fracture of the crust to be noticed later--
+are the necessary conditions for erosion by whatever agent. They
+determine the various agencies which are to be chiefly concerned m
+the wear of any land,--whether streams or glaciers, weathering or
+the wind,--and the degree of their efficiency. The lands must be
+uplifted before they can be eroded, and since they must be eroded
+before their waste can be deposited, movements of elevation are a
+prerequisite condition for sedimentation also. Subsidence is a
+necessary condition for deposits of great thickness, such as those
+of the Great Valley of California and the Indo-Gangetic plain (p.
+101), the Mississippi delta (p. 109), and the still more important
+formations of the continental delta in gradually sinking troughs
+(p. 183). It is not too much to say that the character and
+thickness of each formation of the stratified rocks depend
+primarily on these crustal movements.
+
+Along the Baltic coast of Sweden, bench marks show that the sea is
+withdrawing from the land at a rate which at the north amounts to
+between three and four feet per century; Towards the south the
+rate decreases. South of Stockholm, until recent years, the sea
+has gained upon the land, and here in several seaboard towns
+streets by the shore are still submerged. The rate of oscillation
+increases also from the coast inland. On the other hand, along the
+German coast of the Baltic the only historic fluctuations of sea
+level are those which may be accounted for by variations due to
+changes in rainfall. In 1730 Celsius explained the changes of
+level of the Swedish coast as due to a lowering of the Baltic
+instead of to an elevation of the land. Are the facts just stated
+consistent with his theory?
+
+At the little town of Tadousac--where the Saguenay River empties
+into the St. Lawrence--there are terraces of old sea beaches, some
+almost as fresh as recent railway fills, the highest standing two
+hundred and thirty feet above the river. Here the Saguenay is
+eight hundred and forty feet in depth, and the tide ebbs and flows
+far up its stream. Was its channel cut to this depth by the river
+when the land was at its present height? What oscillations are
+here recorded, and to what amount?
+
+A few miles north of Naples, Italy, the ruins of an ancient Roman
+temple lie by the edge of the sea, on a narrow plain which is
+overlooked in the rear by an old sea cliff (Fig. 166). Three
+marble pillars are still standing. For eleven feet above their
+bases these columns are uninjured, for to this height they were
+protected by an accumulation of volcanic ashes; but from eleven to
+nineteen feet they are closely pitted with the holes of boring
+marine mollusks. From these facts trace the history of the
+oscillations of the region.
+
+FOLDINGS OF THE CRUST
+
+The oscillations which we have just described leave the strata not
+far from their original horizontal attitude. Figure 167 represents
+a region in which movements of a very different nature have taken
+place. Here, on either side of the valley V, we find outcrops of
+layers tilted at high angles. Sections along the ridge r show that
+it is composed of layers which slant inward from either side. In
+places the outcropping strata stand nearly on edge, and on the
+right of the valley they are quite overturned; a shale SH has come
+to overlie a limestone LM although the shale is the older rock,
+whose original position was beneath the limestone.
+
+It is not reasonable to suppose that these rocks were deposited in
+the attitude in which we find them now; we must believe that, like
+other stratified rocks, they were outspread in nearly level sheets
+upon the ocean floor. Since that time they must have been
+deformed. Layers of solid rock several miles in thickness have
+been crumpled and folded like soft wax in the hand, and a vast
+denudation has worn away the upper portions of the folds, in part
+represented in our section by dotted lines.
+
+DIP AND STRIKE. In districts where the strata have been disturbed
+it is desirable to record their attitude. This is most easily done
+by taking the angle at which the strata are inclined and the
+compass direction in which they slant. It is also convenient to
+record the direction in which the outcrop of the strata trends
+across the country.
+
+The inclination of a bed of rocks to the horizon is its DIP. The
+amount of the dip is the angle made with a horizontal plane. The
+dip of a horizontal layer is zero, and that of a vertical layer is
+90 degrees. The direction of the dip is taken with the compass.
+Thus a geologist's notebook in describing the attitude of
+outcropping strata contains many such entries as these: dip 32
+degrees north, or dip 8 degrees south 20 degrees west,--meaning in
+the latter case that the amount of the dip is 8 degrees and the
+direction of the dip bears 20 degrees west of south.
+
+The line of intersection of a layer with the horizontal plane is
+the STRIKE. The strike always runs at right angles to the dip.
+
+Dip and strike may be illustrated by a book set aslant on a shelf.
+The dip is the acute angle made with the shelf by the side of the
+book, while the strike is represented by a line running along the
+book's upper edge. If the dip is north or south, the strike runs
+east and west.
+
+FOLDED STRUCTURES. An upfold, in which the strata dip away from a
+line drawn along the crest and called the axis of the fold, is
+known as an ANTICLINE. A downfold, where the strata dip from
+either side toward the axis of the trough, is called a SYNCLINE.
+There is sometimes seen a downward bend in horizontal or gently
+inclined strata, by which they descend to a lower level. Such a
+single flexure is a MONOCLINE.
+
+DEGREES OF FOLDING. Folds vary in degree from broad, low swells,
+which can hardly be detected, to the most highly contorted and
+complicated structures. In SYMMETRIC folds the dips of the rocks
+on each side the axis of the fold are equal. In UNSYMMETRICAL
+folds one limb is steeper than the other, as in the anticline in
+Figure 167. In OVERTURNED folds one limb is inclined beyond the
+perpendicular. FAN FOLDS have been so pinched that the original
+anticlines are left broader at the top than at the bottom.
+
+In folds where the compression has been great the layers are often
+found thickened at the crest and thinned along the limbs. Where
+strong rocks such as heavy limestones are folded together with
+weak rocks such as shales, the strong rocks are often bent into
+great simple folds, while the weak rocks are minutely crumpled.
+
+SYSTEMS OF FOLDS. As a rule, folds occur in systems. Over the
+Appalachian mountain belt, for example, extending from
+northeastern Pennsylvania to northern Alabama and Georgia, the
+earth's crust has been thrown into a series of parallel folds
+whose axes run from northeast to southwest (Fig. 175). In
+Pennsylvania one may count a score or more of these earth waves,--
+some but from ten to twenty miles in length, and some extending as
+much as two hundred miles before they die away. On the eastern
+part of this belt the folds are steeper and more numerous than on
+the western side.
+
+CAUSE AND CONDITIONS OF FOLDING. The sections which we have
+studied suggest that rocks are folded by lateral pressure. While a
+single, simple fold might be produced by a heave, a series of
+folds, including overturns, fan folds, and folds thickened on
+their crests at the expense of their limbs, could only be made in
+one way,--by pressure from the side. Experiment has reproduced all
+forms of folds by subjecting to lateral thrust layers of plastic
+material such as wax.
+
+Vast as the force must have been which could fold the solid rocks
+of the crust as one may crumple the leaves of a magazine in the
+fingers, it is only under certain conditions that it could have
+produced the results which we see. Rocks are brittle, and it is
+only when under a HEAVY LOAD and by GREAT PRESSURE SLOWLY APPLIED,
+that they can thus be folded and bent instead of being crushed to
+pieces. Under these conditions, experiments prove that not only
+metals such as steel, but also brittle rocks such as marble, can
+be deformed and molded and made to flow like plastic clay.
+
+ZONE OF FLOW, ZONE OF FLOW AND FRACTURE, AND ZONE OF FRACTURE. We
+may believe that at depths which must be reckoned in tens of
+thousands of feet the load of overlying rocks is so great that
+rocks of all kinds yield by folding to lateral pressure, and flow
+instead of breaking. Indeed, at such profound depths and under
+such inconceivable weight no cavity can form, and any fractures
+would be healed at once by the welding of grain to grain. At less
+depths there exists a zone where soft rocks fold and flow under
+stress, and hard rocks are fractured; while at and near the
+surface hard and soft rocks alike yield by fracture to strong
+pressure.
+
+STRUCTURES DEVELOPED IN COMPRESSED ROCKS
+
+Deformed rocks show the effects of the stresses to which they have
+yielded, not only in the immense folds into which they have been
+thrown but in their smallest parts as well. A hand specimen of
+slate, or even a particle under the microscope, may show
+plications similar in form and origin to the foldings which have
+produced ranges of mountains. A tiny flake of mica in the rocks of
+the Alps may be puckered by the same resistless forces which have
+folded miles of solid rock to form that lofty range.
+
+SLATY CLEAVAGE. Rocks which have yielded to pressure often split
+easily in a certain direction across the bedding planes. This
+cleavage is known as slaty cleavage, since it is most perfectly
+developed in fine-grained, homogeneous rocks, such as slates,
+which cleave to the thin, smooth-surfaced plates with which we are
+familiar in the slates used in roofing and for ciphering and
+blackboards. In coarse-grained rocks, pressure develops more
+distant partings which separate the rocks into blocks.
+
+Slaty cleavage cannot be due to lamination, since it commonly
+crosses bedding planes at an angle, while these planes have been
+often well-nigh or quite obliterated. Examining slate with a
+microscope, we find that its cleavage is due to the grain of the
+rock. Its particles are flattened and lie with their broad faces
+in parallel planes, along which the rock naturally splits more
+easily than in any other direction. The irregular grains of the
+mud which has been altered to slate have been squeezed flat by a
+pressure exerted at right angles to the plane of cleavage.
+Cleavage is found only in folded rocks, and, as we may see in
+Figure 176, the strike of the cleavage runs parallel to the strike
+of the strata and the axis of the folds. The dip of the cleavage
+is generally steep, hence the pressure was nearly horizontal. The
+pressure which has acted at right angles to the cleavage, and to
+which it is due, is the same lateral pressure which has thrown the
+strata into folds.
+
+We find additional proof that slates have undergone compression at
+right angles to their cleavage in the fact that any inclusions in
+them, such as nodules and fossils, have been squeezed out of shape
+and have their long diameters lying in the planes of cleavage.
+
+That pressure is competent to cause cleavage is shown by
+experiment. Homogeneous material of fine grain, such as beeswax,
+when subjected to heavy pressure cleaves at right angles to the
+direction of the compressing force.
+
+RATE OF FOLDING. All the facts known with regard to rock
+deformation agree that it is a secular process, taking place so
+slowly that, like the deepening of valleys by erosion, it escapes
+the notice of the inhabitants of the region. It is only under
+stresses slowly applied that rocks bend without breaking. The
+folds of some of the highest mountains have risen so gradually
+that strong, well-intrenched rivers which had the right of way
+across the region were able to hold to their courses, and as a
+circular saw cuts its way through the log which is steadily driven
+against it, so these rivers sawed their gorges through the fold as
+fast as it rose beneath them. Streams which thus maintain the
+course which they had antecedent to a deformation of the region
+are known as ANTECEDENT streams. Examples of such are the Sutlej
+and other rivers of India, whose valleys trench the outer ranges
+of the Himalayas and whose earlier river deposits have been
+upturned by the rising ridges. On the other hand, mountain crests
+are usually divides, parting the head waters of different drainage
+systems. In these cases the original streams of the region have
+been broken or destroyed by the uplift of the mountain mass across
+their paths.
+
+On the whole, which have worked more rapidly, processes of
+deformation or of denudation?
+
+LAND FORMS DUE TO FOLDING
+
+As folding goes on so slowly, it is never left to form surface
+features unmodified by the action of other agencies. An anticlinal
+fold is attacked by erosion as soon as it begins to rise above the
+original level, and the higher it is uplifted, and the stronger
+are its slopes, the faster is it worn away. Even while rising, a
+young upfold is often thus unroofed, and instead of appearing as a
+long, Smooth, boat-shaped ridge, it commonly has had opened along
+the rocks of the axis, when these are weak, a valley which is
+overlooked by the infacing escarpments of the hard layers of the
+sides of the fold. Under long-continued erosion, anticlines may be
+degraded to valleys, while the synclines of the same system may be
+left in relief as ridges.
+
+FOLDED MOUNTAINS. The vastness of the forces which wrinkle the
+crust is best realized in the presence of some lofty mountain
+range. All mountains, indeed, are not the result of folding. Some,
+as we shall see, are due to upwarps or to fractures of the crust;
+some are piles of volcanic material; some are swellings caused by
+the intrusion of molten matter beneath the surface; some are the
+relicts left after the long denudation of high plateaus.
+
+But most of the mountain ranges of the earth, and some of the
+greatest, such as the Alps and the Himalayas, were originally
+mountains of folding. The earth's crust has wrinkled into a fold;
+or into a series of folds, forming a series of parallel ridges and
+intervening valleys; or a number of folds have been mashed
+together into a vast upswelling of the crust, in which the layers
+have been so crumpled and twisted, overturned and crushed, that it
+is exceedingly difficult to make out the original structure.
+
+The close and intricate folds seen in great mountain ranges were
+formed, as we have seen, deep below the surface, within the zone
+of folding. Hence they may never have found expression in any
+individual surface features. As the result of these deformations
+deep under ground the surface was broadly lifted to mountain
+height, and the crumpled and twisted mountain structures are now
+to be seen only because erosion has swept away the heavy cover of
+surface rocks under whose load they were developed.
+
+When the structure of mountains has been deciphered it is possible
+to estimate roughly the amount of horizontal compression which the
+region has suffered. If the strata of the folds of the Alps were
+smoothed out, they would occupy a belt seventy-four miles wider
+than that to which they have been compressed, or twice their
+present width. A section across the Appalachian folds in
+Pennyslvania shows a compression to about two thirds the original
+width; the belt has been shortened thirty-five miles in every
+hundred.
+
+Considering the thickness of their strata, the compression which
+mountains have undergone accounts fully for their height, with
+enough to spare for all that has been lost by denudation.
+
+The Appalachian folds involve strata thirty thousand feet in
+thickness. Assuming that the folded strata rested on an unyielding
+foundation, and that what was lost in width was gained in height,
+what elevation would the range have reached had not denudation
+worn it as it rose?
+
+THE LIFE HISTORY OF MOUNTAINS. While the disturbance and uplift of
+mountain masses are due to deformation, their sculpture into
+ridges and peaks, valleys and deep ravines, and all the forms
+which meet the eye in mountain scenery, excepting in the very
+youngest ranges, is due solely to erosion. We may therefore
+classify mountains according to the degree to which they have been
+dissected. The Juras are an example of the stage of early youth,
+in which the anticlines still persist as ridges and the synclines
+coincide with the valleys; this they owe as much to the slight
+height of their uplift as to the recency of its date.
+
+The Alps were upheaved at various times, the last uplift being
+later than the uplift of the Juras, but to so much greater height
+that erosion has already advanced them well on towards maturity.
+The mountain mass has been cut to the core, revealing strange
+contortions of strata which could never have found expression at
+the surface. Sharp peaks, knife-edged crests, deep valleys with
+ungraded slopes subject to frequent landslides, are all features
+of Alpine scenery typical of a mountain range at this stage in its
+life history. They represent the survival of the hardest rocks and
+the strongest structures, and the destruction of the weaker in
+their long struggle for existence against the agents of erosion.
+Although miles of rock have been removed from such ranges as the
+Alps, we need not suppose that they ever stood much, if any,
+higher than at present. All this vast denudation may easily have
+been accomplished while their slow upheaval was going on; in
+several mountain ranges we have evidence that elevation has not
+yet ceased.
+
+Under long denudation mountains are subdued to the forms
+characteristic of old age. The lofty peaks and jagged crests of
+their earlier life are smoothed down to low domes and rounded
+crests. The southern Appalachians and portions of the Hartz
+Mountains in Germany are examples of mountains which have reached
+this stage.
+
+There are numerous regions of upland and plains in which the rocks
+are found to have the same structure that we have seen in folded
+mountains; they are tilted, crumpled, and overturned, and have
+clearly suffered intense compression. We may infer that their
+folds were once lifted to the height of mountains and have since
+been wasted to low-lying lands. Such a section as that of Figure
+67 illustrates how ancient mountains may be leveled to their
+roots, and represents the final stage to which even the Alps and
+the Himalayas must sometime arrive. Mountains, perhaps of Alpine
+height, once stood about Lake Superior; a lofty range once
+extended from New England and New Jersey southwestward to Georgia
+along the Piedmont belt. In our study of historic geology we shall
+see more clearly how short is the life of mountains as the earth
+counts time, and how great ranges have been lifted, worn away, and
+again upheaved into a new cycle of erosion.
+
+THE SEDIMENTARY HISTORY OF FOLDED MOUNTAINS. We may mention here
+some of the conditions which have commonly been antecedent to
+great foldings of the crust.
+
+1. Mountain ranges are made of belts of enormously and
+exceptionally thick sediments. The strata of the Appalachians are
+thirty thousand feet thick, while the same formations thin out to
+five thousand feet in the Mississippi valley. The folds of the
+Wasatch Mountains involve strata thirty thousand feet thick, which
+thin to two thousand feet in the region of the Plains.
+
+2. The sedimentary strata of which mountains are made are for the
+most part the shallow-water deposits of continental deltas.
+Mountain ranges have been upfolded along the margins of
+continents.
+
+3. Shallow-water deposits of the immense thickness found in
+mountain ranges can be laid only in a gradually sinking area. A
+profound subsidence, often to be reckoned in tens of thousands of
+feet, precedes the upfolding of a mountain range.
+
+Thus the history of mountains of folding is as follows: For long
+ages the sea bottom off the coast of a continent slowly subsides,
+and the great trough, as fast as it forms, is filled with
+sediments, which at last come to be many thousands of feet thick.
+The downward movement finally ceases. A slow but resistless
+pressure sets in, and gradually, and with a long series of many
+intermittent movements, the vast mass of accumulated sediments is
+crumpled and uplifted into a mountain range.
+
+FRACTURES AND DISLOCATIONS OF THE CRUST
+
+Considering the immense stresses to which the rocks of the crust
+are subjected, it is not surprising to find that they often yield
+by fracture, like brittle bodies, instead of by folding and
+flowing, like plastic solids. Whether rocks bend or break depends
+on the character and condition of the rocks, the load of overlying
+rocks which they bear, and the amount of the force and the
+slowness with which it is applied.
+
+JOINTS. At the surface, where their load is least, we find rocks
+universally broken into blocks of greater or less size by partings
+known as joints. Under this name are included many division planes
+caused by cooling and drying; but it is now generally believed
+that the larger and more regular joints, especially those which
+run parallel to the dip and strike of the strata, are fractures
+due to up-and-down movements and foldings and twistings of the
+rocks.
+
+Joints are used to great advantage in quarrying, and we have seen
+how they are utilized by the weather in breaking up rock masses,
+by rivers in widening their valleys, by the sea in driving back
+its cliffs, by glaciers in plucking their beds, and how they are
+enlarged in soluble rocks to form natural passageways for
+underground waters. The ends of the parted strata match along both
+sides of joint planes; in. joints there has been little or no
+displacement of the broken rocks.
+
+FAULTS. In Figure 184 the rocks have been both broken and
+dislocated along the plane ff'. One side must have been moved up
+or down past the other. Such a dislocation is called a fault. The
+amount of the displacement, as measured by the vertical distance
+between the ends of a parted layer, is the throw. The angle which
+the fault plane makes with the vertical is the HADE. In Figure 184
+the right side has gone down relatively to the left; the right is
+the side of the downthrow, while the left is the side of the
+upthrow. Where the fault plane is not vertical the surfaces on the
+two sides may be distinguished as the HANGING WALL and the FOOT
+WALL. Faults differ in throw from a fraction of an inch to many
+thousands of feet.
+
+SLICKENSIDES. If we examine the walls of a fault, we may find
+further evidence of movement in the fact that the surfaces are
+polished and grooved by the enormous friction which they have
+suffered as they have ground one upon the other. These
+appearances, called sliekensides, have sometimes been mistaken for
+the results of glacial action.
+
+NORMAL FAULTS. Faults are of two kinds,--normal faults and thrust
+faults. Normal faults, of which Figure 184 is an example, hade to
+the downthrow; the hanging wall has gone down. The total length of
+the strata has been increased by the displacement. It seems that
+the strata have been stretched and broken, and that the blocks
+have readjusted themselves under the action of gravity as they
+settled.
+
+THRUST FAULTS. Thrust faults hade to the upthrow; the hanging wall
+has gone up. Clearly such faults, where the strata occupy less
+space than before, are due to lateral thrust. Folds and thrust
+faults are closely associated. Under lateral pressure strata may
+fold to a certain point and then tear apart and fault along the
+surface of least resistance. Under immense pressure strata also
+break by shear without folding. Thus, in Figure 185, the rigid
+earth block under lateral thrust has found it easier to break
+along the fault plane than to fold. Where such faults are nearly
+horizontal they are distinguished as THRUST PLANES.
+
+In all thrust faults one mass has been pushed over another, so as
+to bring the underlying and older strata upon younger beds; and
+when the fault planes are nearly horizontal, and especially when
+the rocks have been broken into many slices which have slidden far
+one upon another, the true succession of strata is extremely hard
+to decipher.
+
+In the Selkirk Mountains of Canada the basement rocks of the
+region have been driven east for seven miles on a thrust plane,
+over rocks which originally lay thousands of feet above them.
+
+Along the western Appalachians, from Virginia to Georgia, the
+mountain folds are broken by more than fifteen parallel thrust
+planes, running from northeast to southwest, along which the older
+strata have been pushed westward over the younger. The longest
+continuous fault has been traced three hundred and seventy-five
+miles, and the greatest horizontal displacement has been estimated
+at not less than eleven miles.
+
+CRUSH BRECCIA. Rocks often do not fault with a clean and simple
+fracture, but along a zone, sometimes several yards in width, in
+which they are broken to fragments. It may occur also that strata
+which as a whole yield to lateral thrust by folding include beds
+of brittle rocks, such as thin-layered limestones, which are
+crushed to pieces by the strain. In either case the fragments when
+recemented by percolating waters form a rock known as a CRUSH
+BRECCIA (pronounced BRETCHA).
+
+Breccia is a term applied to any rock formed of cemented ANGULAR
+fragments. This rock may be made by the consolidation of volcanic
+cinders, of angular waste at the foot of cliffs, or of fragments
+of coral torn by the waves from coral reefs, as well as of strata
+crushed by crustal movements.
+
+SURFACE FEATURES DUE TO DISLOCATIONS
+
+FAULT SCARPS. A fault of recent date may be marked at surface by a
+scarp, because the face of the upthrown block has not yet been
+worn to the level of the downthrow side.
+
+After the upthrown block has been worn down to this level,
+differential erosion produces fault scarps wherever weak rocks and
+resistant rocks are brought in contact along the fault plane; and
+the harder rocks, whether on the upthrow or the downthrow side,
+emerge in a line of cliffs. Where a fault is so old that no abrupt
+scarps appear, its general course is sometimes marked by the line
+of division between highland and lowland or hill and plain. Great
+faults have sometimes brought ancient crystalline rocks in contact
+with weaker and younger sedimentary rocks, and long after erosion
+has destroyed all fault scarps the harder crystallines rise in an
+upland of rugged or mountainous country which meets the lowland
+along the line of faulting.
+
+The vast majority of faults give rise to no surface features. The
+faulted region may be old enough to have been baseleveled, or the
+rocks on both sides of the line of dislocation may be alike in
+their resistance to erosion and therefore have been worn down to a
+common slope. The fault may be entirely concealed by the mantle of
+waste, and in such cases it can be inferred from abrupt changes in
+the character or the strike and dip of the strata where they may
+outcrop near it.
+
+The plateau trenched by the Grand Canyon of the Colorado River
+exhibits a series of magnificent fault scarps whose general course
+is from north to south, marking the edges of the great crust
+blocks into which the country has been broken. The highest part of
+the plateau is a crust block ninety miles long and thirty-five
+miles in maximum width, which has been hoisted to nine thousand
+three hundred feet above, sea level. On the east it descends four
+thousand feet by a monoclinal fold, which passes into a fault
+towards the north. On the west it breaks down by a succession of
+terraces faced by fault scarps. The throw of these faults varies
+from seven hundred feet to more than a mile. The escarpments,
+however, are due in a large degree to the erosion of weaker rock
+on the downthrow side.
+
+The Highlands of Scotland meet the Lowlands on the south with a
+bold front of rugged hills along a line of dislocation which runs
+across the country from sea to sea. On the one side are hills of
+ancient crystalline rocks whose crumpled structures prove that
+they are but the roots of once lofty mountains; on the other lies
+a lowland of sandstone and other stratified rocks formed from the
+waste of those long-vanished mountain ranges. Remnants of
+sandstone occur in places on the north of the great fault, and are
+here seen to rest on the worn and fairly even surface of the
+crystallines. We may infer that these ancient mountains were
+reduced along their margins to low plains, which were slowly
+lowered beneath the sea to receive a cover of sedimentary rocks.
+Still later came an uplift and dislocation. On the one side
+erosion has since stripped off the sandstones for the most part,
+but the hard crystalline rocks yet stand in bold relief. On the
+other side the weak sedimentary rocks have been worn down to
+lowlands.
+
+RIFT VALLEYS. In a broken region undergoing uplift or the unequal
+settling which may follow, a slice inclosed between two fissures
+may sink below the level of the crust blocks on either side, thus
+forming a linear depression known as a rift valley, or valley of
+fracture.
+
+One of the most striking examples of this rare type of valley is
+the long trough which runs straight from the Lebanon Mountains of
+Syria on the north to the Red Sea on the south, and whose central
+portion is occupied by the Jordan valley and the Dead Sea. The
+plateau which it gashes has been lifted more than three thousand
+feet above sea level, and the bottom of the trough reaches a depth
+of two thousand six hundred feet below that level in parts of the
+Dead Sea. South of the Dead Sea the floor of the trough rises
+somewhat above sea level, and in the Gulf of Akabah again sinks
+below it. This uneven floor could be accounted for either by the
+profound warping of a valley of erosion or by the unequal
+depression of the floor of a rift valley. But that the trough is a
+true valley of fracture is proved by the fact that on either side
+it is bounded by fault scarps and monoclinal folds. The keystone
+of the arch has subsided. Many geologists believe that the Jordan-
+Akabah trough, the long narrow basin of the Red Sea, and the chain
+of down-faulted valleys which in Africa extends from the strait of
+Bab-el-Mandeb as far south as Lake Nyassa--valleys which contain
+more than thirty lakes--belong to a single system of dislocation.
+
+Should you expect the lateral valleys of a rift valley at the time
+of its formation to enter it as hanging valleys or at a common
+level?
+
+BLOCK MOUNTAINS. Dislocations take place on so grand a scale that
+by the upheaval of blocks of the earth's crust or the down-
+faulting of the blocks about one which is relatively stationary,
+mountains known as block mountains are produced. A tilted crust
+block may present a steep slope on the side upheaved and a more
+gentle descent on the side depressed.
+
+THE BASIN RANGES. The plateaus of the United States bounded by the
+Rocky Mouirtains on the east, and on the west by the ranges which
+front the Pacific, have been profoundly fractured and faulted. The
+system of great fissures by which they are broken extends north
+and south, and the long, narrow, tilted crust blocks intercepted
+between the fissures give rise to the numerous north-south ranges
+of the region. Some of the tilted blocks, as those of southern
+Oregon, are as yet but moderately carved by erosion, and shallow
+lakes lie on the waste that has been washed into the depressions
+between them. We may therefore conclude that their displacement is
+somewhat recent. Others, as those of Nevada, are so old that they
+have been deeply dissected; their original form has been destroyed
+by erosion, and the intermontane depressions are occupied by wide
+plains of waste.
+
+DISLOCATIONS AND RIVER VALLEYS. Before geologists had proved that
+rivers can by their own unaided efforts cut deep canyons, it was
+common to consider any narrow gorge as a gaping fissure of the
+crust. This crude view has long since been set aside. A map of the
+plateaus of northern Arizona shows how independent of the immense
+faults of the region is the course of the Colorado River. In the
+Alps the tunnels on the Saint Gotthard railway pass six times
+beneath the gorge of the Reuss, but at no point do the rocks show
+the slightest trace of a fault.
+
+RATE OF DISLOCATION. So far as human experience goes, the earth
+movements which we have just studied, some of which have produced
+deep-sunk valleys and lofty mountain ranges, and faults whose
+throw is to be measured in thousands of feet, are slow and
+gradual. They are not accomplished by a single paroxysmal effort,
+but by slow creep and a series of slight slips continued for vast
+lengths of time.
+
+In the Aspen mining district in Colorado faulting is now going on
+at a comparatively rapid rate. Although no sudden slips take
+place, the creep of the rock along certain planes of faulting
+gradually bends out of shape the square-set timbers in horizontal
+drifts and has closed some vertical shafts by shifting the upper
+portion across the lower. Along one of the faults of this region
+it is estimated that there has been a movement of at least four
+hundred feet since the Glacial epoch. More conspicuous are the
+instances of active faulting by means of sudden slips. In 1891
+there occurred along an old fault plane in Japan a slip which
+produced an earth rent traced for fifty miles (Fig. 192). The
+country on one side was depressed in places twenty feet below that
+on the other, and also shifted as much as thirteen feet
+horizontally in the direction of the fault line.
+
+In 1872 a slip occurred for forty miles on the great line of
+dislocation which runs along the eastern base of the Sierra Nevada
+Mountains. In the Owens valley, California, the throw amounted to
+twenty-five feet in places, with a horizontal movement along the
+fault line of as much as eighteen feet. Both this slip and that in
+Japan just mentioned caused severe earthquakes.
+
+For the sake of clearness we have described oscillations,
+foldings, and fractures of the crust as separate processes, each
+giving rise to its own peculiar surface features, but in nature
+earth movements are by no means so simple,--they are often
+implicated with one another: folds pass into faults; in a deformed
+region certain rocks have bent, while others under the same
+strain, but under different conditions of plasticity and load,
+have broken; folded mountains have been worn to their roots, and
+the peneplains to which they have been denuded have been upwarped
+to mountain height and afterwards dissected,--as in the case of
+the Alleghany ridges, the southern Carpathians, and other ranges,
+--or, as in the case of the Sierra Nevada Mountains, have been
+broken and uplifted as mountains of fracture.
+
+Draw the following diagrams, being careful to show the direction
+in which the faulted blocks have moved, by the position of the two
+parts of some well-defined layer of limestone, sandstone, or
+shale, which occurs on each side of the fault plane, as in Figure
+184.
+
+1. A normal fault with a hade of 15 degrees, the original fault
+scarp remaining.
+
+2. A normal fault with a hade of 50 degrees, the original fault
+scarp worn away, showing cliffs caused by harder strata on the
+downthrow side.
+
+3. A thrust fault with a hade of 30 degrees, showing cliffs due to
+harder strata outcropping on the downthrow.
+
+4. A thrust fault with a hade of 80 degrees, with surface
+baseleveled.
+
+5. In a region of normal faults a coal mine is being worked along
+the seam of coal AB (Fig. 193). At B it is found broken by a fault
+f which hades toward A. To find the seam again, should you advise
+tunneling up or down from B?
+
+6. In a vertical shaft of a coal mine the same bed of coal is
+pierced twice at different levels because of a fault. Draw a
+diagram to show whether the fault is normal or a thrust.
+
+7. Copy the diagram in Figure 194, showing how the two ridges may
+be accounted for by a single resistant stratum dislocated by a
+fault. Is the fault a STRIKE FAULT, i.e. one running parallel with
+the strike of the strata, or a DIP FAULT, one running parallel
+with the direction of the dip?
+
+8. Draw a diagram of the block in Figure 195 as it would appear if
+dislocated along the plane efg by a normal fault whose throw
+equals one fourth the height of the block. Is the fault a strike
+or a dip fault? Draw a second diagram showing the same block after
+denudation has worn it down below the center of the upthrown side.
+Note that the outcrop of the coal seam is now deceptively
+repeated. This exercise may be done in blocks of wood instead of
+drawings.
+
+9. Draw diagrams showing by dotted lines the conditions both of A
+and of B, Figure 196, after deformation had given the strata their
+present attitude.
+
+10. What is the attitude of the strata of this earth block, Figure
+197? What has taken place along the plane bef? When did the
+dislocation occur compared with the folding of the strata? With
+the erosion of the valleys on the right-hand side of the mountain?
+With the deposition of the sediments? Do you find any remnants of
+the original surface baf produced by the dislocation? From the
+left-hand side of the mountain infer what was the relief of the
+region before the dislocation. Give the complete history recorded
+in the diagram from the deposition of the strata to the present.
+
+11. Which is the older fault, in Figure 198, or When did the lava
+flow occur? How long a time elapsed between the formation of the
+two faults as measured in the work done in the interval? How long
+a time since the formation of the later fault?
+
+12. Measure by the scale the thickness lie of the coal-bearing
+strata outcropping from a to b in Figure 199. On any convenient
+scale draw a similar section of strata with a dip of 30 degrees
+outcropping along a horizontal line normal to the strike one
+thousand feet in length, and measure the thickness of the strata
+by the scale employed. The thickness may also be calculated by
+trigonometry.
+
+UNCONFORMITY
+
+Strata deposited one upon, another in an unbroken succession are
+said to be conformable. But the continuous deposition of strata is
+often interrupted by movements of the earth's crust, Old sea
+floors are lifted to form land and are again depressed beneath the
+sea to receive a cover of sediments only after an interval during
+which they were carved by subaerial erosion. An erosion surface
+which thus parts older from younger strata is known as an
+UNCONFORMITY, and the strata above it are said to be UNCONFORMABLE
+with the rocks below, or to rest unconformably upon them. An
+unconformity thus records movements of the crust and a consequent
+break in the deposition of the strata. It denotes a period of land
+erosion of greater or less length, which may sometimes be roughly
+measured by the stage in the erosion cycle which the land surface
+had attained before its burial. Unconformable strata may be
+parallel, as in Figure 200, where the record includes the
+deposition of strata, their emergence, the erosion of the land
+surface, a submergence and the deposit of the strata, and lastly,
+emergence and the erosion of the present surface.
+
+Often the earth movements to which the uplift or depression was
+due involved tilting or folding of the earlier strata, so that the
+strata are now nonparallel as well as unconformable. In Figure
+201, for example, the record includes deposition, uplift, and
+tilting of a; erosion, depression, the deposit of b; and finally
+the uplift which has brought the rocks to open air and permitted
+the dissection by which the unconformity is revealed. From this
+section infer that during early Silurian times the area was sea,
+and thick sea muds were laid upon it. These were later altered to
+hard slates by pressure and upfolded into mountains. During the
+later Silurian and the Devonian the area was land and suffered
+vast denudation. In the Carboniferous period it was lowered
+beneath the sea and received a cover of limestone.
+
+THE AGE OF MOUNTAINS. It is largely by means of unconformities
+that we read the history of mountain making and other deformations
+and movements of the crust. In Figure 203, for example, the
+deformation which upfolded the range of mountains took place after
+the deposit of the series of strata a of which the mountains are
+composed, and before the deposit of the stratified rocks, which
+rest unconformably on a and have not shared their uplift.
+
+Most great mountain ranges, like the Sierra Nevada and the Alps,
+mark lines of weakness along which the earth's crust has yielded
+again and again during the long ages of geological time. The
+strata deposited at various times about their flanks have been
+infolded by later crumplings with the original mountain mass, and
+have been repeatedly crushed, inverted, faulted, intruded with
+igneous rocks, and denuded. The structure of great mountain ranges
+thus becomes exceedingly complex and difficult to read. A
+comparatively simple case of repeated uplift is shown in Figure
+204. In the section of a portion of the Alps shown in Figure 179 a
+far more complicated history may be deciphered.
+
+UNCONFORMITIES IN THE COLORADO CANYON, ARIZONA. How geological
+history may be read in unconformities is further illustrated in
+Figures 207 and 208. The dark crystalline rocks a at the bottom of
+the canyon are among the most ancient known, and are overlain
+unconformably by a mass of tilted coarse marine sandstones b,
+whose total thickness is not seen in the diagram and measures
+twelve thousand feet perpendicularly to the dip. Both a and b rise
+to a common level nn and upon them rest the horizontal sea-laid
+strata c, in which the upper portion of the canyon has been cut.
+
+Note that the crystalline rocks a have been crumpled and crushed.
+Comparing their structure with that of folded mountains, what do
+you infer as to their relief after their deformation? To which
+surface were they first worn down, mm' or nm? Describe and account
+for the surface mm'. How does it differ from the surface of the
+crystalline rocks seen in the Torridonian Mountains, and why? This
+surface mm' is one of the oldest land surfaces of which any
+vestige remains.
+
+It is a bit of fossil geography buried from view since the
+earliest geological ages and recently brought to light by the
+erosion of the canyon.
+
+How did the surface mm' come to receive its cover of sandstones b?
+From the thickness and coarseness of these sediments draw
+inferences as to the land mass from which they were derived. Was
+it rising or subsiding? high or low? Were its streams slow or
+swift? Was the amount of erosion small or great?
+
+Note the strong dip of these sandstones b. Was the surface mm'
+tilted as now when the sandstones were deposited upon it? When was
+it tilted? Draw a diagram showing the attitude of the rocks after
+this tilting occurred, and their height relative to sea level.
+
+The surface nn' is remarkably even, although diversified by some
+low hills which rise into the bedded rocks of c, and it may be
+traced for long distances up and down the canyon. Were the layers
+of b and the surface mm' always thus cut short by nn' as now? What
+has made the surface nn' so even? How does it come to cross the
+hard crystalline rocks a and the weaker sandstones b at the same
+impartial level? How did the sediments of c come to be laid upon
+it? Give now the entire history recorded in the section, and in
+addition that involved in the production of the platform P, shown
+in Figure 130, and that of the cutting of the canyon. How does the
+time involved in the cutting of the canyon compare with that
+required for the production of the surfaces mm', nn', and P?
+
+
+
+
+
+CHAPTER X
+
+EARTHQUAKES
+
+
+Any sudden movement of the rocks of the crust, as when they tear
+apart when a fissure is formed or extended, or slip from time to
+time along a growing fault, produces a jar called an earthquake,
+which spreads in all directions from the place of disturbance.
+
+THE CHARLESTON EARTHQUAKE. On the evening of August 31, 1886, the
+city of Charleston, S.C., was shaken by one of the greatest
+earthquakes which has occurred in the United States. A slight
+tremor which rattled the windows was followed a few seconds later
+by a roar, as of subterranean thunder, as the main shock passed
+beneath the city. Houses swayed to and fro, and their heaving
+floors overturned furniture and threw persons off their feet as,
+dizzy and nauseated, they rushed to the doors for safety. In sixty
+seconds a number of houses were completely wrecked, fourteen
+thousand chimneys were toppled over, and in all the city scarcely
+a building was left without serious injury. In the vicinity of
+Charleston railways were twisted and trains derailed. Fissures
+opened in the loose superficial deposits, and in places spouted
+water mingled with sand from shallow underlying aquifers.
+
+The point of origin, or FOCUS, of the earthquake was inferred from
+subsequent investigations to be a rent in the rocks about twelve
+miles beneath the surface. From the center of greatest
+disturbance, which lay above the focus, a few miles northwest of
+the city, the surface shock traveled outward in every direction,
+with decreasing effects, at the rate of nearly two hundred miles
+per minute. It was felt from Boston to Cuba, and from eastern Iowa
+to the Bermudas, over a circular area whose diameter was a
+thousand miles.
+
+An earthquake is transmitted from the focus through the elastic
+rocks of the crust, as a wave, or series of waves, of compression
+and rarefaction, much as a sound wave is transmitted through the
+elastic medium of the air. Each earth particle vibrates with
+exceeding swiftness, but over a very short path. The swing of a
+particle in firm rock seldom exceeds one tenth of an inch in
+ordinary earthquakes, and when it reaches one half an inch and an
+inch, the movement becomes dangerous and destructive.
+
+The velocity of earthquake waves, like that of all elastic waves,
+varies with the temperature and elasticity of the medium. In the
+deep, hot, elastic rocks they speed faster than in the cold and
+broken rocks near the surface. The deeper the point of origin and
+the more violent the initial shock, the faster and farther do the
+vibrations run.
+
+Great earthquakes, caused by some sudden displacement or some
+violent rending of the rocks, shake the entire planet. Their waves
+run through the body of the earth at the rate of about three
+hundred and fifty miles a minute, and more slowly round its
+circumference, registering their arrival at opposite sides of the
+globe on the exceedingly delicate instruments of modern earthquake
+observatories.
+
+GEOLOGICAL EFFECTS. Even great earthquakes seldom produce
+geological effects of much importance. Landslides may be shaken
+down from the sides of mountains and hills, and cracks may be
+opened in the surface deposits of plains; but the transient
+shiver, which may overturn cities and destroy thousands of human
+lives, runs through the crust and leaves it much the same as
+before.
+
+EARTHQUAKES ATTENDING GREAT DISPLACEMENTS. Great earthquakes
+frequently attend the displacement of large masses of the rocks of
+the crust. In 1822 the coast of Chile was suddenly raised three or
+four feet, and the rise was five or six feet a mile inland. In
+1835 the same region was again upheaved from two to ten feet. In
+each instance a destructive earthquake was felt for one thousand
+miles along the coast.
+
+THE GREAT CALIFORNIA EARTHQUAKE OF 1906. A sudden dislocation
+occurred in 1906 along an ancient fault plane which extends for
+300 miles through western California. The vertical displacement
+did not exceed four feet, while the horizontal shifting reached a
+maximum of twenty feet. Fences, rows of trees, and roads which
+crossed the fault were broken and offset. The latitude and
+longitude of all points over thousands of square miles were
+changed. On each side of the fault the earth blocks moved in
+opposite directions, the block on the east moving southward and
+that on the west moving northward and to twice the distance. East
+and west of the fault the movements lessened with increasing
+distance from it.
+
+This sudden slip set up an earthquake lasting sixty-five seconds,
+followed by minor shocks recurring for many days. In places the
+jar shook down the waste on steep hillsides, snapped off or
+uprooted trees, and rocked houses from their foundations or threw
+down their walls or chimneys. The water mains of San Francisco
+were broken, and the city was thus left defenseless against a
+conflagration which destroyed $500,000,000 worth of property. The
+destructive effects varied with the nature of the ground.
+Buildings on firm rock suffered least, while those on deep
+alluvium were severely shaken by the undulations, like water
+waves, into which the loose material was thrown. Well-braced steel
+structures, even of the largest size, were earthquake proof, and
+buildings of other materials, when honestly built and
+intelligently designed to withstand earthquake shocks, usually
+suffered little injury. The length of the intervals between severe
+earthquakes in western California shows that a great dislocation
+so relieves the stresses of the adjacent earth blocks that scores
+of years may elapse before the stresses again accumulate and cause
+another dislocation.
+
+Perhaps the most violent earthquake which ever visited the United
+States attended the depression, in 1812, of a region seventy-five
+miles long and thirty miles wide, near New Madrid, Mo. Much of the
+area was converted into swamps and some into shallow lakes, while
+a region twenty miles in diameter was bulged up athwart the
+channel of the Mississippi. Slight quakes are still felt in this
+region from time to time, showing that the strains to which the
+dislocation was due have not yet been fully relieved.
+
+EARTHQUAKES ORIGINATING BENEATH THE SEA. Many earthquakes
+originate beneath the sea, and in a number of examples they seem
+to have been accompanied, as soundings indicate, by local
+subsidences of the ocean bottom. There have been instances where
+the displacement has been sufficient to set the entire Pacific
+Ocean pulsating for many hours. In mid ocean the wave thus
+produced has a height of only a few feet, while it may be two
+hundred miles in width. On shores near the point of origin
+destructive waves two or three score feet in height roll in, and
+on coasts thousands of miles distant the expiring undulations may
+be still able to record themselves on tidal gauges.
+
+DISTRIBUTION OF EARTHQUAKES. Every half hour some considerable
+area of the earth's surface is sensibly shaken by an earthquake,
+but earthquakes are by no means uniformly distributed over the
+globe. As we might infer from what we know as to their causes,
+earthquakes are most frequent in regions now undergoing
+deformation. Such are young rising mountain ranges, fault lines
+where readjustments recur from time to time, and the slopes of
+suboceanic depressions whose steepness suggests that subsidence
+may there be in progress.
+
+Earthquakes, often of extreme severity, frequently visit the lofty
+and young ranges of the Andes, while they are little known in the
+subdued old mountains of Brazil. The Highlands of Scotland are
+crossed by a deep and singularly straight depression called the
+Great Glen, which has been excavated along a very ancient line of
+dislocation. The earthquakes which occur from time to time in this
+region, such as the Inverness earthquake in 1891, are referred to
+slight slips along this fault plane.
+
+In Japan, earthquakes are very frequent. More than a thousand are
+recorded every year, and twenty-nine world-shaking earthquakes
+occurred in the three years ending with 1901. They originate, for
+the most part, well down on the eastern flank of the earth fold
+whose summit is the mountainous crest of the islands, and which
+plunges steeply beneath the sea to the abyss of the Tuscarora
+Deep.
+
+MINOR CAUSES OF EARTHQUAKES. Since any concussion within the crust
+sets up an earth jar, there are several minor causes of
+earthquakes, such as volcanic explosions and even the collapse of
+the roofs of caves. The earthquakes which attend the eruption of
+volcanoes are local, even in the case of the most violent volcanic
+paroxysms known. When the top of a volcano has been blown to
+fragments, the accompanying earth shock has sometimes not been
+felt more than twenty-five miles away.
+
+DEPTH OF FOCUS. The focus of the Charleston earthquake, estimated
+at about twelve miles below the surface, was exceptionally deep.
+Volcanic earthquakes are particularly shallow, and probably no
+earthquakes known have started at a greater depth than fifteen or
+twenty miles. This distance is so slight compared with the earth's
+radius that we may say that earthquakes are but skin-deep.
+
+Should you expect the velocity of an earthquake to be greater in a
+peneplain or in a river delta?
+
+After an earthquake, piles on which buildings rested were found
+driven into the ground, and chimneys crushed at base. From what
+direction did the shock come?
+
+Chimneys standing on the south walls of houses toppled over on the
+roof. Should you infer that the shock in this case came from the
+north or south?
+
+How should you expect a shock from the east to affect pictures
+hanging on the east and the west walls of a room? how the pictures
+hanging on the north and the south walls?
+
+In parts of the country, as in southwestern Wisconsin, slender
+erosion pillars, or "monuments," are common. What inference could
+you draw as to the occurrence in such regions of severe
+earthquakes in the recent past?
+
+
+
+
+
+CHAPTER XI
+
+VOLCANOES
+
+
+Connected with movements of the earth's crust which take place so
+slowly that they can be inferred only from their effects is one of
+the most rapid and impressive of all geological processes,--the
+extrusion of molten rock from beneath the surface of the earth,
+giving rise to all the various phenomena of volcanoes.
+
+In a volcano, molten rock from a region deep below, which we may
+call its reservoir, ascends through a pipe or fissure to the
+surface. The materials erupted may be spread over vast areas, or,
+as is commonly the case, may accumulate about the opening, forming
+a conical pile known as the volcanic cone. It is to this cone that
+popular usage refers the word VOLCANO; but the cone is simply a
+conspicuous part of the volcanic mechanism whose still more
+important parts, the reservoir and the pipe, are hidden from view.
+
+Volcanic eruptions are of two types,--EFFUSIVE eruptions, in which
+molten rock wells up from below and flows forth in streams of LAVA
+(a comprehensive term applied to all kinds of rock emitted from
+volcanoes in a molten state), and EXPLOSIVE eruptions, in which
+the rock is blown out in fragments great and small by the
+expansive force of steam.
+
+ERUPTIONS OF THE EFFUSIVE TYPE
+
+THE HAWAIIAN VOLCANOES. The Hawaiian Islands are all volcanic in
+origin, and have a linear arrangement characteristic of many
+volcanic groups in all parts of the world. They are strung along a
+northwest-southeast line, their volcanoes standing in two parallel
+rows as if reared along two adjacent lines of fracture or folding.
+In the northwestern islands the volcanoes have long been extinct
+and are worn low by erosion. In the southeastern island. Hawaii,
+three volcanoes are still active and in process of building. Of
+these Mauna Loa, the monarch of volcanoes, with a girth of two
+hundred miles and a height of nearly fourteen thousand feet above
+sea level, is a lava dome the slope of whose sides does not
+average more than five degrees. On the summit is an elliptical
+basin ten miles in circumference and several hundred feet deep.
+Concentric cracks surround the rim, and from time to time the
+basin is enlarged as great slices are detached from the vertical
+walls and engulfed.
+
+Such a volcanic basin, formed by the insinking of the top of the
+cone, is called a CALDERA.
+
+On the flanks of Mauna Loa, four thousand feet above sea level,
+lies the caldera of Kilauea, an independent volcano whose dome has
+been joined to the larger mountain by the gradual growth of the
+two. In each caldera the floor, which to the eye is a plain of
+black lava, is the congealed surface of a column of molten rock.
+At times of an eruption lakes of boiling lava appear which may be
+compared to air holes in a frozen river. Great waves surge up,
+lifting tons of the fiery liquid a score of feet in air, to fall
+back with a mighty plunge and roar, and occasionally the lava
+rises several hundred feet in fountains of dazzling brightness.
+The lava lakes may flood the floor of the basin, but in historic
+times have never been known to fill it and overflow the rim.
+Instead, the heavy column of lava breaks way through the sides of
+the mountain and discharges in streams which flow down the
+mountain slopes for a distance sometimes of as much as thirty-five
+miles. With the drawing off of the lava the column in the duct of
+the volcano lowers, and the floor of the caldera wholly or in part
+subsides. A black and steaming abyss marks the place of the lava
+lakes. After a time the lava rises in the duct, the floor is
+floated higher, and the boiling lakes reappear.
+
+The eruptions of the Hawaiian volcanoes are thus of the effusive
+type. The column of lava rises, breaks through the side of the
+mountain, and discharges in lava streams. There are no explosions,
+and usually no earthquakes, or very slight ones, accompany the
+eruptions. The lava in the calderas boils because of escaping
+steam, but the vapor emitted is comparatively little, and seldom
+hangs above the summits in heavy clouds. We see here in its
+simplest form the most impressive and important fact in all
+volcanic action, molten rock has been driven upward to the surface
+from some deep-lying source.
+
+LAVA FLOWS. As lava issues from the side of a volcano or overflows
+from the summit, it flows away in a glowing stream resembling
+molten iron drawn white-hot from an iron furnace. The surface of
+the stream soon cools and blackens, and the hard crust of
+nonconducting rock may grow thick and firm enough to form a
+tunnel, within which the fluid lava may flow far before it loses
+its heat to any marked degree. Such tunnels may at last be left as
+caves by the draining away of the lava, and are sometimes several
+miles in length.
+
+PAHOEHOE AND AA. When the crust of highly fluid lava remains
+unbroken after its first freezing, it presents a smooth, hummocky,
+and ropy surface known by the Hawaiian term PAHOEHOE. On the other
+hand, the crust of a viscid flow may be broken and splintered as
+it is dragged along by the slowly moving mass beneath. The stream
+then appears as a field of stones clanking and grinding on, with
+here and there from some chink a dull red glow or a wisp of steam.
+It sets to a surface called AA, of broken, sharp-edged blocks,
+which is often both difficult and dangerous to traverse.
+
+FISSURE ERUPTIONS. Some of the largest and most important outflows
+of lava have not been connected with volcanic cones, but have been
+discharged from fissures, flooding the country far and wide with
+molten rock. Sheet after sheet of molten rock has been
+successively outpoured, and there have been built up, layer upon
+layer, plateaus of lava thousands of feet in thickness and many
+thousands of square miles in area.
+
+ICELAND. This island plateau has been rent from time to time by
+fissures from which floods of lava have outpoured. In some
+instances the lava discharges along the whole length of the
+fissure, but more often only at certain points upon it. The Laki
+fissure, twenty miles long, was in eruption in 1783 for seven
+months. The inundation of fluid rock which poured from it is the
+largest of historic record, reaching a distance of forty-seven
+miles and covering two hundred and twenty square miles to an
+average depth of a hundred feet. At the present time the fissure
+is traced by a line of several hundred insignificant mounds of
+fragmental materials which mark where the lava issued.
+
+The distance to which the fissure eruptions of Iceland flow on
+slopes extremely gentle is noteworthy. One such stream is ninety
+miles in length, and another seventy miles long has a slope of
+little more than one half a degree.
+
+Where lava is emitted at one point and flows to a less distance
+there is gradually built up a dome of the shape of an inverted
+saucer with an immense base but comparatively low. Many LAVA DOMES
+have been discovered in Iceland, although from their exceedingly
+gentle slopes, often but two or three degrees, they long escaped
+the notice of explorers.
+
+The entire plateau of Iceland, a region as large as Ohio, is
+composed of volcanic products,--for the most part of successive
+sheets of lava whose total thickness falls little short of two
+miles. The lava sheets exposed to view were outpoured in open air
+and not beneath the sea; for peat bogs and old forest grounds are
+interbedded with them, and the fossil plants of these vegetable
+deposits prove that the plateau has long been building and is very
+ancient. On the steep sea cliffs of the island, where its
+structure is exhibited, the sheets of lava are seen to be cut with
+many DIKES,--fissures which have been filled by molten rock,--and
+there is little doubt that it was through these fissures that the
+lava outwelled in successive flows which spread far and wide over
+the country and gradually reared the enormous pile of the plateau.
+
+ERUPTIONS OF THE EXPLOSIVE TYPE
+
+In the majority of volcanoes the lava which rises in the pipe is
+at least in part blown into fragments with violent explosions and
+shot into the air together with vast quantities of water vapor and
+various gases. The finer particles into--which the lava is
+exploded are called VOLCANIC DUST or VOLCANIC ASHES, and are often
+carried long distances by the wind before they settle to the
+earth. The coarser fragments fall about the vent and there
+accumulate in a steep, conical, volcanic mountain. As successive
+explosions keep open the throat of the pipe, there remains on the
+summit a cup-shaped depression called the CRATER.
+
+STROMBOLI. To study the nature of these explosions we may visit
+Stromboli, a low volcano built chiefly of fragmental materials,
+which rises from the sea off the north coast of Sicily and is in
+constant though moderate action.
+
+Over the summit hangs a cloud of vapor which strikingly resembles
+the column of smoke puffed from the smokestack of a locomotive, in
+that it consists of globular masses, each the product of a
+distinct explosion. At night the cloud of vapor is lighted with a
+red glow at intervals of a few minutes, like the glow on the trail
+of smoke behind the locomotive when from time to time the fire bos
+is opened. Because of this intermittent light flashing thousands
+of feet above the sea, Stromboli has been given the name of the
+Lighthouse of the Mediterranean.
+
+Looking down into the crater of the volcano, one sees a viscid
+lava slowly seething. The agitation gradually increases. A great
+bubble forms. It bursts with an explosion which causes the walls
+of the crater to quiver with a miniature earthquake, and an
+outrush of steam carries the fragments of the bubble aloft for a
+thousand feet to fall into the crater or on the mountain side
+about it. With the explosion the cooled and darkened crust of the
+lava is removed, and the light of the incandescent liquid beneath
+is reflected from the cloud of vapor which overhangs the cone.
+
+At Stromboli we learn the lesson that the explosive force in
+volcanoes is that of steam. The lava in the pipe is permeated with
+it much as is a thick boiling porridge. The steam in boiling
+porridge is unable to escape freely and gathers into bubbles which
+in breaking spurt out drops of the pasty substance; in the same
+way the explosion of great bubbles of steam in the viscid lava
+shoots clots and fragments of it into the air.
+
+KRAKATOA. The most violent eruption of history, that of Krakatoa,
+a small volcanic island in the strait between Sumatra and Java,
+occurred in the last week of August, 1883. Continuous explosions
+shot a column of steam and ashes. seventeen miles in air. A black
+cloud, beneath which was midnight darkness and from which fell a
+rain of ashes and stones, overspread the surrounding region to a
+distance of one hundred and fifty miles. Launched on the currents
+of the upper air, the dust was swiftly carried westward to long
+distances. Three days after the eruption it fell on the deck of a
+ship sixteen hundred miles away, and in thirteen days the finest
+impalpable powder from the volcano had floated round the globe.
+For many months the dust hung over Europe and America as a faint
+lofty haze illuminated at sunrise and sunset with brilliant
+crimson. In countries nearer the eruption, as in India and Africa,
+the haze for some time was so thick that it colored sun and moon
+with blue, green, and copper-red tints and encircled them with
+coronas.
+
+At a distance of even a thousand miles the detonations of the
+eruption sounded like the booming of heavy guns a few miles away.
+In one direction they were audible for a distance as great as that
+from San Francisco to Cleveland. The entire atmosphere was thrown
+into undulations under which all barometers rose and fell as the
+air waves thrice encircled the earth. The shock of the explosions
+raised sea waves which swept round the adjacent shores at a height
+of more than fifty feet, and which were perceptible halfway around
+the globe.
+
+At the close of the eruption it was found that half the mountain
+had been blown away, and that where the central part of the island
+had been the sea was a thousand feet deep.
+
+MARTINIQUE AND ST. VINCENT. In 1902 two dormant volcanoes of the
+West Indies, Mt. Pelee in Martinique and Soufriere in St. Vincent,
+broke into eruption simultaneously. No lava was emitted, but there
+were blown into the air great quantities of ashes, which mantled
+the adjacent parts of the islands with a pall as of gray snow. In
+early stages of the eruption lakes which occupied old craters were
+discharged and swept down the ash-covered mountain valleys in
+torrents of boiling mud.
+
+On several occasions there was shot from the crater of each
+volcano a thick and heavy cloud of incandescent ashes and steam,
+which rushed down the mountain side like an avalanche, red with
+glowing stones and scintillating with lightning flashes. Forests
+and buildings in its path were leveled as by a tornado, wood was
+charred and set on fire by the incandescent fragments, all
+vegetation was destroyed, and to breathe the steam and hot,
+suffocating dust of the cloud was death to every living creature.
+On the morning of the 8th of May, 1902, the first of these
+peculiar avalanches from Mt. Pelee fell on the city of St. Pierre
+and instantly destroyed the lives of its thirty thousand
+inhabitants.
+
+The eruptions of many volcanoes partake of both the effusive and
+the explosive types: the molten rock in the pipe is in part blown
+into the air with explosions of steam, and in part is discharged
+in streams of lava over the lip of the crater and from fissures in
+the sides of the cone. Such are the eruptions of Vesuvius, one of
+which is illustrated in Figure 219.
+
+SUBMARINE ERUPTIONS. The many volcanic islands of the ocean and
+the coral islands resting on submerged volcanic peaks prove that
+eruptions have often taken place upon the ocean floor and have
+there built up enormous piles of volcanic fragments and lava. The
+Hawaiian volcanoes rise from a depth of eighteen thousand feet of
+water and lift their heads to about thirty thousand feet above the
+ocean bed. Christmas Island (see p. 194), built wholly beneath the
+ocean, is a coral-capped volcanic peak, whose total height, as
+measured from the bottom of the sea, is more than fifteen thousand
+feet. Deep-sea soundings have revealed the presence of numerous
+peaks which fail to reach sea level and which no doubt are
+submarine volcanoes. A number of volcanoes on the land were
+submarine in their early stages, as, for example, the vast pile of
+Etna, the celebrated Sicilian volcano, which rests on stratified
+volcanic fragments containing marine shells now uplifted from the
+sea.
+
+Submarine outflows of lava and deposits of volcanic fragments
+become covered with sediments during the long intervals between
+eruptions. Such volcanic deposits are said to be CONTEMPORANEOUS,
+because they are formed during the same period as the strata among
+which they are imbedded. Contemporaneous lava sheets may be
+expected to bake the surface of the stratum on which they rest,
+while the sediments deposited upon them are unaltered by their
+heat. They are among the most permanent records of volcanic
+action, far outlasting the greatest volcanic mountains built in
+open air.
+
+From upraised submarine volcanoes, such as Christmas Island, it is
+learned that lava flows which are poured out upon the bottom of
+the sea do not differ materially either in composition or texture
+from those of the land.
+
+VOLCANIC PRODUCTS
+
+Vast amounts of steam are, as we have seen, emitted from
+volcanoes, and comparatively small quantities of other vapors,
+such as various acid and sulphurous gases. The rocks erupted from
+volcanoes differ widely in chemical composition and in texture.
+
+ACIDIC AND BASIC LAVAS. Two classes of volcanic rocks may be
+distinguished,--those containing a large proportion of silica
+(silicic acid, SiO2) and therefore called ACIDIC, and those
+containing less silica and a larger proportion of the bases (lime,
+magnesia, soda, etc.) and therefore called BASIC. The acidic
+lavas, of which RHYOLITE and THRACHYTE are examples, are
+comparatively light in color and weight, and are difficult to
+melt. The basic lavas, of which BASALT is a type, are dark and
+heavy and melt at a lower temperature.
+
+SCORIA AND PUMICE. The texture of volcanic rocks depends in part
+on the degree to which they were distended by the steam which
+permeated them when in a molten state. They harden into compact
+rock where the steam cannot expand. Where the steam is released
+from pressure, as on the surface of a lava stream, it forms
+bubbles (steam blebs) of various sizes, which give the hardened
+rock a cellular structure (Fig. 220), In this way are formed the
+rough slags and clinkers called SCORIA, which are found on the
+surface of flows and which are also thrown out as clots of lava in
+explosive eruptions.
+
+On the surface of the seething lava in the throat of the volcano
+there gathers a rock foam, which, when hurled into the air, is
+cooled and falls as PUMICE,--a spongy gray rock so light that it
+floats on water.
+
+AMYGDULES. The steam blebs of lava flows are often drawn out from
+a spherical to an elliptical form resembling that of an almond,
+and after the rock has cooled these cavities are gradually filled
+with minerals deposited from solution by underground water. From
+their shape such casts are called amygdules (Greek, amygdalon, an
+almond). Amygdules are commonly composed of silica. Lavas contain
+both silica and the alkalies, potash and soda, and after
+dissolving the alkalies, percolating water is able to take silica
+also into solution. Most AGATES are banded amygdules in which the
+silica has been laid in varicolored, concentric layers.
+
+GLASSY AND STONY LAVAS. Volcanic rocks differ in texture according
+also to the rate at which they have solidified. When rapidly
+cooled, as on the surface of a lava flow, molten rock chills to a
+glass, because the minerals of which it is composed have not had
+time to separate themselves from the fused mixture and form
+crystals. Under slow cooling, as in the interior of the flow, it
+becomes a stony mass composed of crystals set in a glassy paste.
+In thin slices of volcanic glass one may see under the microscope
+the beginnings of crystal growth in filaments and needles and
+feathery forms, which are the rudiments of the crystals of various
+minerals.
+
+Spherulites, which also mark the first changes of glassy lavas
+toward a stony condition, are little balls within the rock,
+varying from microscopic size to several inches in diameter, and
+made up of radiating fibers.
+
+Perlitic structure, common among glassy lavas, consists of
+microscopic curving and interlacing cracks, due to contraction.
+
+FLOW LINES are exhibited by volcanic rocks both to the naked eye
+and under the microscope. Steam blebs, together with crystals and
+their embryonic forms, are left arranged in lines and streaks by
+the currents of the flowing lava as it stiffened into rock.
+
+PORPHYRITIC STRUCTURE. Rocks whose ground mass has scattered
+through it large conspicuous crystals are said to be PORPHYRITIC,
+and it is especially among volcanic rocks that this structure
+occurs. The ground mass of porphyries either may be glassy or may
+consist in part of a felt of minute crystals; in either case it
+represents the consolidation of the rock after its outpouring upon
+the surface. On the other hand, the large crystals of porphyry
+have slowly formed deep below the ground at an earlier date.
+
+COLUMNAR STRUCTURE. Just as wet starch contracts on drying to
+prismatic forms, so lava often contracts on cooling to a mass of
+close-set, prismatic, and commonly six-sided columns, which stand
+at right angles to the cooling surface. The upper portion of a
+flow, on rapid cooling from the surface exposed to the air, may
+contract to a confused mass of small and irregular prisms; while
+the remainder forms large and beautifully regular columns, which
+have grown upward by slow cooling from beneath.
+
+FRAGMENTAL MATERIALS
+
+Rocks weighing many tons are often thrown from a volcano at the
+beginning of an outburst by the breaking up of the solidofied
+floor of the crater; and during the progress of an eruption large
+blocks may be torn from the throat of the volcano by the outrush
+of steam. But the most important fragmental materials are those
+derived from the lava itself. As lava rises in the pipe, the steam
+which permeates it is released from pressure and explodes, hurling
+the lava into the air in fragments of all sizes,--large pieces of
+scoria, LAPILLI (fragments the size of a pea or walnut), volcanic
+"sand" and volcanic "ashes." The latter resemble in appearance the
+ashes of wood or coal, but they are not in any sense, like them, a
+residue after combustion.
+
+Volcanic ashes are produced in several ways: lava rising in the
+volcanic duct is exploded into fine dust by the steam which
+permeates it; glassy lava, hurled into the air and cooled
+suddenly, is brought into a state of high strain and tension, and,
+like Prince Rupert's drops, flies to pieces at the least
+provocation. The clash of rising and falling projectiles also
+produces some dust, a fair sample of which may be made by grating
+together two pieces of pumice.
+
+Beds of volcanic ash occur widely among recent deposits in the
+western United States. In Nebraska ash beds are found in twenty
+counties, and are often as white as powdered pumice. The beds grow
+thicker and coarser toward the southwestern part of the state,
+where their thickness sometimes reaches fifty feet. In what
+direction would you look for the now extinct volcano whose
+explosive eruptions are thus recorded?
+
+TUFF. This is a convenient term designating any rock composed of
+volcanic fragments. Coarse tuffs of angular fragments are called
+VOLCANIC BRECIA, and when the fragments have been rounded and
+sorted by water the rock is termed a VOLCANIC CONGLOMERATE. Even
+when deposited in the open air, as on the slopes of a volcano,
+tuffs may be rudely bedded and their fragments more or less
+rounded, and unless marine shells or the remains of land plants
+and animals are found as fossils in them, there is often
+considerable difficulty in telling whether they were laid in water
+or in air. In either case they soon become consolidated. Chemical
+deposits from percolating waters fill the interstices, and the bed
+of loose fragments is cemented to hard rock.
+
+The materials of which tuffs are composed are easily recognized as
+volcanic in their origin. The fragments are more or less cellular,
+according to the degree to which they were distended with steam
+when in a molten state, and even in the finest dust one may see
+the glass or the crystals of lava from which it was derived. Tuffs
+often contain VOCLANIC BOMBS,--balls of lava which took shape
+while whirling in the air, and solidified before falling to the
+ground.
+
+ANCIENT VOLCANIC ROCKS. It is in these materials and structures
+which we have described that volcanoes leave some of their most
+enduring records. Even the volcanic rocks of the earliest geological
+ages, uplifted after long burial beneath the sea and exposed to view
+by deep erosion, are recognized and their history read despite the
+many changes which they may have undergone. A sheet of ancient lava
+may be distinguished by its composition from the sediments among
+which it is imbedded. The direction of its flow lines may be noted.
+The cellular and slaggy surface where the pasty lava was distended
+by escaping steam is recognized by the amygdules which now fill the
+ancient steam blebs. In a pile of successive sheets of lava each
+flow may be distinguished and its thickness measured; for the
+surface of each sheet is glassy and scoriaceous, while beneath its
+upper portions the lava of each flow is more dense and stony. The
+length of time which elapsed before a sheet was buried beneath the
+materials of succeeding eruptions may be told by the amount of
+weathering which it had undergone, the depth of ancient soil--now
+baked to solid rock--upon it, and the erosion which it had suffered
+in the interval.
+
+If the flow occurred from some submarine volcano, we may recognize
+the fact by the sea-laid sediments which cover it, filling the
+cracks and crevices of its upper surface and containing pieces of
+lava washed from it in their basal layers.
+
+Long-buried glassy lavas devitrify, or pass to a stony condition,
+under the unceasing action of underground waters; but their flow
+lines and perlitic and spherulitic structures remain to tell of
+their original state.
+
+Ancient tuffs are known by the fragmental character of their
+volcanic material, even though they have been altered to firm
+rock. Some remains of land animals and plants may be found
+imbedded to tell that the beds were laid in open air; while the
+remains of marine organisms would prove as surely that the tuffs
+were deposited in the sea.
+
+In these ways ancient volcanoes have been recognized near Boston,
+in southeastern Pennsylvania, about Lake Superior, and in other
+regions of the United States.
+
+THE LIFE HISTORY OF A VOLCANO
+
+The invasion of a region by volcanic forces is attended by
+movements of the crust heralded by earthquakes. A fissure or a
+pipe is opened and the building of the cone or the spreading of
+wide lava sheets is begun.
+
+VOLCANIC CONES. The shape of a volcanic cone depends chiefly on
+the materials erupted. Cones made of fragments may have sides as
+steep as the angle of repose, which in the case of coarse scoria
+is sometimes as high as thirty or forty degrees. About the base of
+the mountain the finer materials erupted are spread in more gentle
+slopes, and are also washed forward by rains and streams. The
+normal profile is thus a symmetric cone with a flaring base.
+
+Cones built of lava vary in form according to the liquidity of the
+lava. Domes of gentle slope, as those of Hawaii, for example, are
+formed of basalt, which flows to long distances before it
+congeals. When superheated and emitted from many vents, this
+easily melted lava builds great plateaus, such as that of Iceland.
+On the other hand, lavas less fusible, or poured out at a lower
+temperature, stiffen when they have flowed but a short distance,
+and accumulate in a steep cone. Trachyte has been extruded in a
+state so viscid that it has formed steepsided domes like that of
+Sarcoui.
+
+Most volcanoes are built, like Vesuvius, both of lava flows and of
+tuffs, and sections show that the structure of the cone consists
+of outward-dipping, alternating layers of lava, scoria, and ashes.
+
+From time to time the cone is rent by the violence of explosions
+and by the weight of the column of lava in the pipe. The fissures
+are filled with lava and some discharge on the sides of the
+mountain, building parasitic cones, while all form dikes, which
+strengthen the pile with ribs of hard rock and make it more
+difficult to rend.
+
+Great catastrophes are recorded in the shape of some volcanoes
+which consist of a circular rim perhaps miles in diameter,
+inclosing a vast crater or a caldera within which small cones may
+rise. We may infer that at some time the top of the mountain has
+been blown off, or has collapsed and been engulfed because some
+reservoir beneath had been emptied by long-continued eruptions.
+
+The cone-building stage may be said to continue until eruptions of
+lava and fragmental materials cease altogether. Sooner or later
+the volcanic forces shift or die away, and no further eruptions
+add to the pile or replace its losses by erosion during periods of
+repose. Gases however are still emitted, and, as sulphur vapors
+are conspicuous among them, such vents are called SOLFATARAS.
+Mount Hood, in Oregon, is an example of a volcano sunk to this
+stage. From a steaming rift on its side there rise sulphurous
+fumes which, half a mile down the wind, will tarnish a silver
+coin.
+
+GEYSERS AND HOT SPRINGS. The hot springs of volcanic regions are
+among the last vestiges of volcanic heat. Periodically eruptive
+boiling springs are termed geysers. In each of the geyser regions
+of the earth--the Yellowstone National Park, Iceland, and New
+Zealand--the ground water of the locality is supposed to be heated
+by ancient lavas that, because of the poor conductivity of the
+rock, still remain hot beneath the surface.
+
+OLD FAITHFUL, one of the many geysers of the Yellowstone National
+Park, plays a fountain of boiling water a hundred feet in air;
+while clouds of vapor from the escaping steam ascend to several
+times that height. The eruptions take place at intervals of from
+seventy to ninety minutes. In repose the geyser is a quiet pool,
+occupying a craterlike depression in a conical mound some twelve
+feet high. The conduit of the spring is too irregular to be
+sounded. The mound is composed of porous silica deposited by the
+waters of the geyser.
+
+Geysers erupt at intervals instead of continuously boiling,
+because their long, narrow, and often tortuous conduits do not
+permit a free circulation of the water. After an eruption the tube
+is refilled and the water again gradually becomes heated. Deep in
+the tube where it is in contact with hot lavas the water sooner or
+later reaches the boiling point, and bursting into steam shoots
+the water above it high in air.
+
+CARBONATED SPRINGS. After all the other signs of life have gone,
+the ancient volcano may emit carbon dioxide as its dying breath.
+The springs of the region may long be charged with carbon dioxide,
+or carbonated, and where they rise through limestone may be
+expected to deposit large quantities of travertine. We should
+remember, however, that many carbonated springs, and many hot
+springs, are wholly independent of volcanoes.
+
+THE DESTRUCTION OF THE CONE. As soon as the volcanic cone ceases
+to grow by eruptions the agents of erosion begin to wear it down,
+and the length of time that has elapsed since the period of active
+growth may be roughly measured by the degree to which the cone has
+been dissected. We infer that Mount Shasta, whose conical shape is
+still preserved despite the gullies one thousand feet deep which
+trench its sides, is younger than Mount Hood, which erosive
+agencies have carved to a pyramidal form. The pile of materials
+accumulated about a volcanic vent, no matter how vast in bulk, is
+at last swept entirely away. The cone of the volcano, active or
+extinct, is not old as the earth counts time; volcanoes are short-
+lived geological phenomena.
+
+CRANDALL VOLCANO. This name is given to a dissected ancient
+volcano in the Yellowstone National Park, which once, it is
+estimated, reared its head thousands of feet above the surrounding
+country and greatly exceeded in bulk either Mount Shasta or Mount
+Etna. Not a line of the original mountain remains; all has been
+swept away by erosion except some four thousand feet of the base
+of the pile. This basal wreck now appears as a rugged region about
+thirty miles in diameter, trenched by deep valleys and cut into
+sharp peaks and precipitous ridges. In the center of the area is
+found the nucleus (N, Fig. 237),--a mass of coarsely crystalline
+rock that congealed deep in the old volcanic pipe. From it there
+radiate in all directions, like the spokes of a wheel, long dikes
+whose rock grows rapidly finer of grain as it leaves the vicinity
+of the once heated core. The remainder of the base of the ancient
+mountain is made of rudely bedded tuffs and volcanic breccia, with
+occasional flows of lava, some of the fragments of the breccia
+measuring as much as twenty feet in diameter. On the sides of
+canyons the breccia is carved by rain erosion to fantastic
+pinnacles. At different levels in the midst of these beds of tuff
+and lava are many old forest grounds. The stumps and trunks of the
+trees, now turned to stone, still in many cases stand upright
+where once they grew on the slopes of the mountain as it was
+building (Fig. 238). The great size and age of some of these trees
+indicate, the lapse of time between the eruption whose lavas or
+tuffs weathered to the soil on which they grew and the subsequent
+eruption which buried them beneath showers of stones and ashes.
+
+Near the edge of the area lies Death Gulch, in which carbon
+dioxide is given off in such quantities that in quiet weather it
+accumulates in a heavy layer along the ground and suffocates the
+animals which may enter it.
+
+
+
+
+
+CHAPTER XII
+
+UNDERGROUND STRUCTURES OF IGNEOUS ORIGIN
+
+
+It is because long-continued erosion lays bare the innermost
+anatomy of an extinct volcano, and even sweeps away the entire
+pile with much of the underlying strata, thus leaving the very
+roots of the volcano open to view, that we are able to study
+underground volcanic structures. With these we include, for
+convenience, intrusions of molten rock which have been driven
+upward into the crust, but which may not have succeeded in
+breaking way to the surface and establishing a volcano. All these
+structures are built of rock forced when in a fluid or pasty state
+into some cavity which it has found or made, and we may classify
+them therefore, according to the shape of the molds in which the
+molten rock has congealed, as (1) dikes, (2) volcanic necks, (3)
+intrusive sheets, and (4) intrusive masses.
+
+DIKES. The sheet of once molten rock with which a fissure has been
+filled is known as a dike. Dikes are formed when volcanic cones
+are rent by explosions or by the weight of the lava column in the
+duct, and on the dissection of the pile they appear as radiating
+vertical ribs cutting across the layers of lava and tuff of which
+the cone is built. In regions undergoing deformation rocks lying
+deep below the ground are often broken and the fissures are filled
+with molten rock from beneath, which finds no outlet to the
+surface. Such dikes are common in areas of the most ancient rocks,
+which have been brought to light by long erosion.
+
+In exceptional cases dikes may reach the length of fifty or one
+hundred miles. They vary in width from a fraction of a foot to
+even as much as three hundred feet.
+
+Dikes are commonly more fine of grain on the sides than in the
+center, and may have a glassy and crackled surface where they meet
+the inclosing rock. Can you account for this on any principle
+which you have learned?
+
+VOLCANIC NECKS. The pipe of a volcano rises from far below the
+base of the cone,--from the deep reservoir from which its
+eruptions are supplied. When the volcano has become extinct this
+great tube remains filled with hardened lava. It forms a
+cylindrical core of solid rock, except for some distance below the
+ancient crater, where it may contain a mass of fragments which had
+fallen back into the chimney after being hurled into the air.
+
+As the mountain is worn down, this central column known as the
+VOLCANIC NECK is left standing as a conical hill (Fig. 240). Even
+when every other trace of the volcano has been swept away, erosion
+will not have passed below this great stalk on which the volcano
+was borne as a fiery flower whose site it remains to mark. In
+volcanic regions of deep denudation volcanic necks rise solitary
+and abrupt from the surrounding country as dome-shaped hills. They
+are marked features in the landscape in parts of Scotland and in
+the St. Lawrence valley about Montreal (Fig. 241).
+
+INTRUSIVE SHEETS. Sheets of igneous rocks are sometimes found
+interleaved with sedimentary strata, especially in regions where
+the rocks have been deformed and have suffered from volcanic
+action. In some instances such a sheet is seen to be
+CONTEMPORANEOUS (p. 248). In other instances the sheet must be
+INTRUSIVE. The overlying stratum, as well as that beneath, has
+been affected by the heat of the once molten rock. We infer that
+the igneous rock when in a molten state was forced between the
+strata, much as a card may be pushed between the leaves of a
+closed book. The liquid wedged its way between the layers, lifting
+those above to make room for itself. The source of the intrusive
+sheet may often be traced to some dike (known therefore as the
+FEEDING DIKE), or to some mass of igneous rock.
+
+Intrusive sheets may extend a score and more of miles, and, like
+the longest surface flows, the most extensive sheets consist of
+the more fusible and fluid lavas,--those of the basic class of
+which basalt is an example. Intrusive sheets are usually harder
+than the strata in which they lie and are therefore often left in
+relief after long denudation of the region (Fig. 315).
+
+On the west bank of the Hudson there extends from New York Bay
+north for thirty miles a bold cliff several hundred feet high,--
+the PALISADES OF THE HUDSON. It is the outcropping edge of a sheet
+of ancient igneous rock, which rests on stratified sandstones and
+is overlain by strata of the same series. Sandstones and lava
+sheet together dip gently to the west arid the latter disappears
+from view two miles back from the river.
+
+It is an interesting question whether the Palisades sheet is
+CONTEMPORANEOUS or INTRUSIVE. Was it outpoured on the sandstones
+beneath it when they formed the floor of the sea, and covered
+forthwith by the sediments of the strata above, or was it intruded
+among these beds at a later date?
+
+The latter is the case: for the overlying stratum is intensely
+baked along the zone of contact. At the west edge of the sheet is
+found the dike in which the lava rose to force its way far and
+wide between the strata.
+
+ELECTRIC PEAK, one of the prominent mountains of the Yellowstone
+National Park, is carved out of a mass of strata into which many
+sheets of molten rock have been intruded. The western summit
+consists of such a sheet several hundred feet thick. Studying the
+section of Figure 244, what inference do you draw as to the source
+of these intrusive sheets?
+
+INTRUSIVE MASSES
+
+BOSSES. This name is generally applied to huge irregular masses of
+coarsely crystalline igneous rock lying in the midst of other
+formations. Bosses vary greatly in size and may reach scores of
+miles in extent. Seldom are there any evidences found that bosses
+ever had connection with the surface. On the other hand, it is
+often proved that they have been driven, or have melted their way,
+upward into the formations in which they lie; for they give off
+dikes and intrusive sheets, and have profoundly altered the rocks
+about them by their heat.
+
+The texture of the rock of bosses proves that consolidation
+proceeded slowly and at great depths, and it is only because of
+vast denudation that they are now exposed to view. Bosses are
+commonly harder than the rocks about them, and stand up,
+therefore, as rounded hills and mountainous ridges long after the
+surrounding country has worn to a low plain.
+
+The base of bosses is indefinite or undetermined, and in this
+respect they differ from laccoliths. Some bosses have broken and
+faulted the overlying beds; some have forced the rocks aside and
+melted them away.
+
+The SPANISH PEAKS of southeastern Colorado were formed by the
+upthrust of immense masses of igneous rock, bulging and breaking
+the overlying strata. On one side of the mountains the throw of
+the fault is nearly a mile, and fragments of deep-lying beds were
+dragged upward by the rising masses. The adjacent rocks were
+altered by heat to a distance of several thousand feet. No
+evidence appears that the molten rock ever reached the surface,
+and if volcanic eruptions ever took place either in lava flows or
+fragmental materials, all traces of them have been effaced. The
+rock of the intrusive masses is coarsely crystalline, and no doubt
+solidified slowly under the pressure of vast thicknesses of
+overlying rock, now mostly removed by erosion.
+
+A magnificent system of dikes radiates from the Peaks to a
+distance of fifteen miles, some now being left by long erosion as
+walls a hundred feet in height (Fig. 239). Intrusive sheets fed by
+the dikes penetrate the surrounding strata, and their edges are
+cut by canyons as much as twenty-five miles from the mountain. In
+these strata are valuable beds of lignite, an imperfect coal,
+which the heat of dikes and sheets has changed to coke.
+
+LACCOLITHS. The laccolith (Greek laccos, cistern; lithos, stone)
+is a variety of intrusive masses in which molten rock has spread
+between the strata, and, lifting the strata above it to a dome-
+shaped form, has collected beneath them in a lens-shaped body with
+a flat base.
+
+The HENRY MOUNTAINS, a small group of detached peaks in southern
+Utah, rise from a plateau of horizontal rocks. Some of the peaks
+are carved wholly in separate domelike uplifts of the strata of
+the plateau. In others, as Mount Hillers, the largest of the
+group, there is exposed on the summit a core of igneous rock from
+which the sedimentary rocks of the flanks dip steeply outward in
+all directions. In still others erosion has stripped off the
+covering strata and has laid bare the core to its base; and its
+shape is here seen to be that of a plano-convex lens or a baker's
+bun, its flat base resting on the undisturbed bedded rocks
+beneath. The structure of Mount Hillers is shown in Figure 248.
+The nucleus of igneous rock is four miles in diameter and more
+than a mile in depth.
+
+REGIONAL INTRUSIONS. These vast bodies of igneous rock, which may
+reach hundreds of miles in diameter, differ little from bosses
+except in their immense bulk. Like bosses, regional intrusions
+give off dikes and sheets and greatly change the rocks about them
+by their heat. They are now exposed to view only because of the
+profound denudation which has removed the upheaved dome of rocks
+beneath which they slowly cooled. Such intrusions are accompanied
+--whether as cause or as effect is still hardly known--by
+deformations, and their masses of igneous rock are thus found as
+the core of many great mountain ranges. The granitic masses of
+which the Bitter Root Mountains and the Sierra Nevadas have been
+largely carved are each more than three hundred miles in length.
+Immense regional intrusions, the cores of once lofty mountain
+ranges, are found upon the Laurentian peneplain.
+
+PHYSIOGRAPHIC EFFECTS OF INTRUSIVE MASSES. We have already seen
+examples of the topographic effects of intrusive masses in Mount
+Hillers, the Spanish Peaks, and in the great mountain ranges
+mentioned in the paragraph on regional intrusions, although in the
+latter instances these effects are entangled with the effects of
+other processes. Masses of igneous rock cannot be intruded within
+the crust without an accompanying deformation on a scale
+corresponding to the bulk of the intruded mass. The overlying
+strata are arched into hills or mountains, or, if the molten
+material is of great extent, the strata may conceivably be floated
+upward to the height of a plateau. We may suppose that the
+transference of molten matter from one region to another may be
+among the causes of slow subsidences and elevations. Intrusions
+give rise to fissures, dikes, and intrusive sheets, and these
+dislocations cannot fail to produce earthquakes. Where intrusive
+masses open communication with the surface, volcanoes are
+established or fissure eruptions occur such as those of Iceland.
+
+THE INTRUSIVE ROCKS
+
+The igneous rocks are divided into two general classes,--the
+VOLCANIC or ERUPTIVE rocks, which have been outpoured in open air
+or on the floor of the sea, and the INTRUSIVE rocks, which have
+been intruded within the rocks of the crust and have solidified
+below the surface. The two classes are alike in chemical
+composition and may be divided into acidic and basic groups. In
+texture the intrusive rocks differ from the volcanic rocks because
+of the different conditions under which they have solidified. They
+cooled far more slowly beneath the cover of the rocks into which
+they were pressed than is permitted to lava flows in open air.
+Their constituent minerals had ample opportunity to sort
+themselves and crystallize from the fluid mixture, and none of
+that mixture was left to congeal as a glassy paste.
+
+They consolidated also under pressure. They are never scoriaceous,
+for the steam with which they were charged was not allowed to
+expand and distend them with steam blebs. In the rocks of the
+larger intrusive masses one may see with a powerful microscope
+exceedingly minute cavities, to be counted by many millions to the
+cubic inch, in which the gaseous water which the mass contained
+was held imprisoned under the immense pressure of the overlying
+rocks.
+
+Naturally these characteristics are best developed in the
+intrusives which cooled most slowly, i.e. in the deepest-seated
+and largest masses; while in those which cooled more rapidly, as
+in dikes and sheets, we find gradations approaching the texture of
+surface flows.
+
+VARIETIES OF THE INTRUSIVE ROCKS. We will now describe a few of
+the varieties of rocks of deep-seated intrusions. All are even
+grained, consisting of a mass of crystalline grains formed during
+one continuous stage of solidification, and no porphyritic
+crystals appear as in lavas.
+
+GRANITE, as we have learned already, is composed of three
+minerals,--quartz, feldspar, and mica. According to the color of
+the feldspar the rock may be red, or pink, or gray. Hornblende--a
+black or dark green mineral, an iron-magnesian silicate, about as
+hard as feldspar--is sometimes found as a fourth constituent, and
+the rock is then known as HORNBLENDIC GRANITE. Granite is an
+acidic rock corresponding to rhyolite in chemical composition. We
+may believe that the same molten mass which supplies this acidic
+lava in surface flows solidifies as granite deep below ground in
+the volcanic reservoir.
+
+SYENITE, composed of feldspar and mica, has consolidated from a
+less siliceous mixture than has granite.
+
+DIORITE, still less siliceous, is composed of hornblende and
+feldspar,--the latter mineral being of different variety from the
+feldspar of granite and syenite.
+
+GABBRO, a typical basic rock, corresponds to basalt in chemical
+composition. It is a dark, heavy, coarsely crystalline aggregate
+of feldspar and AUGITE (a dark mineral allied to hornblende). It
+often contains MAGNETITE (the magnetic black oxide of iron) and
+OLIVINE (a greenish magnesian silicate).
+
+In the northern states all these types, and many others also of
+the vast number of varieties of intrusive rocks, can be found
+among the rocks of the drift brought from the areas of igneous
+rock in Canada and the states of our northern border.
+
+SUMMARY. The records of geology prove that since the earliest of
+their annals tremendous forces have been active in the earth. In
+all the past, under pressures inconceivably great, molten rock has
+been driven upward into the rocks of the crust. It has squeezed
+into fissures forming dikes; it has burrowed among the strata as
+intrusive sheets; it has melted the rocks away or lifted the
+overlying strata, filling the chambers which it has made with
+intrusive masses. During all geological ages molten rock has found
+way to the surface, and volcanoes have darkened the sky with
+clouds of ashes and poured streams of glowing lava down their
+sides. The older strata,--the strata which have been most deeply
+buried,--and especially those which have suffered most from
+folding and from fracture, show the largest amount of igneous
+intrusions. The molten rock which has been driven from the earth's
+interior to within the crust or to the surface during geologic
+time must be reckoned in millions of cubic miles.
+
+THE INTERIOR CONDITION OF THE EARTH AND CAUSES OF VULCANISM AND
+DEFORMATION
+
+The problems of volcanoes and of deformation are so closely
+connected with that of the earth's interior that we may consider
+them together. Few of these problems are solved, and we may only
+state some known facts and the probable conclusions which may be
+drawn as inferences from them.
+
+THE INTERIOR OF THE EARTH IS HOT. Volcanoes prove that in many
+parts of the earth there exist within reach of the surface regions
+of such intense heat that the rock is in a molten condition. Deep
+wells and mines show everywhere an increase in temperature below
+the surface shell affected by the heat of summer and the cold of
+winter,--a shell in temperate latitudes sixty or seventy feet
+thick. Thus in a boring more than a mile deep at Schladebach,
+Germany, the earth grows warmer at the rate of 1 degrees F. for
+every sixty-seven feet as we descend. Taking the average rate of
+increase at one degree for every sixty feet of descent, and
+assuming that this rate, observed at the moderate distances open
+to observation, continues to at least thirty-five miles, the
+temperature at that depth must be more than three thousand
+degrees,--a temperature at which all ordinary rocks would melt at
+the earth's surface. The rate of increase in temperature probably
+lessens as we go downward, and it may not be appreciable below a
+few hundred miles. But there is no reason to doubt that THE
+INTERIOR OF THE EARTH IS INTENSELY HOT. Below a depth of one or
+two score miles we may imagine the rocks everywhere glowing with
+heat.
+
+Although the heat of the interior is great enough to melt all
+rocks at atmospheric pressure, it does not follow that the
+interior is fluid. Pressure raises the fusing point of rocks, and
+the weight of the crust may keep the interior in what may be
+called a solid state, although so hot as to be a liquid or a gas
+were the pressure to be removed.
+
+THE INTERIOR OF THE EARTH IS RIGID AND HEAVY. The earth behaves as
+a globe more rigid than glass under the attractions of the sun and
+moon. It is not deformed by these stresses as is the ocean in the
+tides, proving that it is not a fluid ball covered with a yielding
+crust a few miles thick. Earthquakes pass through the earth faster
+than they would were it of solid steel. Hence the rocks of the
+interior are highly elastic, being brought by pressure to a
+compact, continuous condition unbroken by the cracks and vesicles
+of surface rocks. THE INTERIOR OF THE EARTH IS RIGID
+
+The common rocks of the crust are about two and a half times
+heavier than water, while the earth as a whole weighs five and
+six-tenths times as much as a globe of water of the same size. THE
+INTERIOR IS THEREFORE MUCH MORE HEAVY THAN THE CRUST. This may be
+caused in part by compression of the interior under the enormous
+weight of the crust, and in part also by an assortment of
+material, the heavier substances, such as the heavy metals, having
+gravitated towards the center.
+
+Between the crust, which is solid because it is cool, and the
+interior, which is hot enough to melt were it not for the pressure
+which keeps it dense and rigid, there may be an intermediate zone
+in which heat and pressure are so evenly balanced that here rock
+liquefies whenever and wherever the pressure upon it may be
+relieved by movements of the crust. It is perhaps from such a
+subcrustal layer that the lava of volcanoes is supplied.
+
+THE CAUSES OF VOLCANIC ACTION. It is now generally believed that
+the HEAT of volcanoes is that of the earth's interior. Other
+causes, such as friction and crushing in the making of mountains
+and the chemical reactions between oxidizing agents of the crust
+and the unoxidized interior, have been suggested, but to most
+geologists they seem inadequate.
+
+There is much difference of opinion as to the FORCE which causes
+molten rock to rise to the surface in the ducts of volcanoes.
+Steam is so evidently concerned in explosive eruptions that many
+believe that lava is driven upward by the expansive force of the
+steam with which it is charged, much as a viscid liquid rises and
+boils over in a test tube or kettle.
+
+But in quiet eruptions, and still more in the irruption of
+intrusive sheets and masses, there is little if any evidence that
+steam is the driving force. It is therefore believed by many
+geologists that it is PRESSURE DUE TO CRUSTAL MOVEMENTS AND
+INTERNAL STRESSES which squeezes molten rock from below into
+fissures and ducts in the crust. It is held by some that where
+considerable water is supplied to the rising column of lava, as
+from the ground water of the surrounding region, and where the
+lava is viscid so that steam does not readily escape, the eruption
+is of the explosive type; when these conditions do not obtain, the
+lava outwells quietly, as in the Hawaiian volcanoes. It is held by
+others not only that volcanoes are due to the outflow of the
+earth's deep-seated heat, but also that the steam and other
+emitted gases are for the most part native to the earth's interior
+and never have had place in the circulation of atmospheric and
+ground waters.
+
+VOLCANIC ACTION AND DEFORMATION. Volcanoes do not occur on wide
+plains or among ancient mountains. On the other hand, where
+movements of the earth's crust are in progress in the uplift of
+high plateaus, and still more in mountain making, molten rock may
+reach the surface, or may be driven upward toward it forming great
+intrusive masses. Thus extensive lava flows accompanied the
+upheaval of the block mountains of western North America and the
+uplift of the Colorado plateau. A line of recent volcanoes may be
+traced along the system of rift valleys which extends from the
+Jordan and Dead Sea through eastern Africa to Lake Nyassa. The
+volcanoes of the Andes show how conspicuous volcanic action may be
+in young rising ranges. Folded mountains often show a core of
+igneous rock, which by long erosion has come to form the axis and
+the highest peaks of the range, as if the molten rock had been
+squeezed up under the rising upfolds. As we decipher the records
+of the rocks in historical geology we shall see more fully how, in
+all the past, volcanic action has characterized the periods of
+great crustal movements, and how it has been absent when and where
+the earth's crust has remained comparatively at rest.
+
+THE CAUSES OF DEFORMATION. As the earth's interior, or nucleus, is
+highly heated it must be constantly though slowly losing its heat
+by conduction through the crust and into space; and since the
+nucleus is cooling it must also be contracting. The nucleus has
+contracted also because of the extrusion of molten matter, the
+loss of constituent gases given off in volcanic eruptions, and
+(still more important) the compression and consolidation of its
+material under gravity. As the nucleus contracts, it tends to draw
+away from the cooled and solid crust, and the latter settles,
+adapting itself to the shrinking nucleus much as the skin of a
+withering apple wrinkles down upon the shrunken fruit. The
+unsupported weight of the spherical crust develops enormous
+tangential pressures, similar to the stresses of an arch or dome,
+and when these lateral thrusts accumulate beyond the power of
+resistance the solid rock is warped and folded and broken.
+
+Since the planet attained its present mass it has thus been
+lessening in volume. Notwithstanding local and relative upheavals
+the earth's surface on the whole has drawn nearer and nearer to
+the center. The portions of the lithosphere which have been
+carried down the farthest have received the waters of the oceans,
+while those portions which have been carried down the least have
+emerged as continents.
+
+Although it serves our convenience to refer the movements of the
+crust to the sea level as datum plane, it is understood that this
+level is by no means fixed. Changes in the ocean basins increase
+or reduce their capacity and thus lower or raise the level of the
+sea. But since these basins are connected, the effect of any
+change upon the water level is so distributed that it is far less
+noticeable than a corresponding change would be upon the land.
+
+
+
+
+
+CHAPTER XIII
+
+METAMORPHISM AND MINERAL VEINS
+
+
+Under the action of internal agencies rocks of all kinds may be
+rendered harder, more firmly cemented, and more crystalline. These
+processes are known as METAMORPHISM, and the rocks affected,
+whether originally sedimentary or igneous, are called METAMORPHIC
+ROCKS. We may contrast with metamorphism the action of external
+agencies in weathering, which render rocks less coherent by
+dissolving their soluble parts and breaking down their crystalline
+grains.
+
+CONTACT METAMORPHISM. Rocks beneath a lava flow or in contact with
+igneous intrusions are found to be metamorphosed to various
+degrees by the heat of the cooling mass. The adjacent strata may
+be changed only in color, hardness, and texture. Thus, next to a
+dike, bituminous coal may be baked to coke or anthracite, and
+chalk and limestone to crystalline marble. Sandstone may be
+converted into quartzite, and shale into ARGILLITE, a compact,
+massive clay rock. New minerals may also be developed. In
+sedimentary rocks there may be produced crystals of mica and of
+GARNET (a mineral as hard as quartz, commonly occurring in red,
+twelve-sided crystals). Where the changes are most profound, rocks
+may be wholly made over in structure and mineral composition.
+
+In contact metamorphism, thin sheets of molten rock produce less
+effect than thicker ones. The strongest heat effects are naturally
+caused by bosses and regional intrusions, and the zone of change
+about them may be several miles in width. In these changes heated
+waters and vapors from the masses of igneous rocks undoubtedly
+play a very important part.
+
+Which will be more strongly altered, the rocks about a closed dike
+in which lava began to cool as soon as it filled the fissure, or
+the rocks about a dike which opened on the surface and through
+which the molten rock flowed for some time?
+
+Taking into consideration the part played by heated waters, which
+will produce the most far-reaching metamorphism, dikes which cut
+across the bedding planes or intrusive sheets which are thrust
+between the strata?
+
+REGIONAL METAMORPHISM. Metamorphic rocks occur wide-spread in many
+regions, often hundreds of square miles in area, where such
+extensive changes cannot be accounted for by igneous intrusions.
+Such are the dissected cores of lofty mountains, as the Alps, and
+the worn-down bases of ancient ranges, as in New England, large
+areas in the Piedmont Belt, and the Laurentian peneplain.
+
+In these regions the rocks have yielded to immense pressure. They
+have been folded, crumpled, and mashed, and even their minute
+grains, as one may see with a microscope, have often been
+puckered, broken, and crushed to powder. It is to these mechanical
+movements and strains which the rocks have suffered in every part
+that we may attribute their metamorphism, and the degree to which
+they have been changed is in direct proportion to the degree to
+which they have been deformed and mashed.
+
+Other factors, however, have played important parts. Rock crushing
+develops heat, and allows a freer circulation of heated waters and
+vapors. Thus chemical reactions are greatly quickened; minerals
+are dissolved and redeposited in new positions, or their chemical
+constituents may recombine in new minerals, entirely changing the
+nature of the rock, as when, for example, feldspar recrystallizes
+as quartz and mica.
+
+Early stages of metamorphism are seen in SLATE. Pressure has
+hardened the marine muds, the arkose, or the volcanic ash from
+which slates are derived, and has caused them to cleave by the
+rearrangement of their particles.
+
+Under somewhat greater pressure, slate becomes PHYLLITE, a clay
+slate whose cleavage surfaces are lustrous with flat-lying mica
+flakes. The same pressure which has caused the rock to cleave has
+set free some of its mineral constituents along the cleavage
+planes to crystallize there as mica.
+
+FOLIATION. Under still stronger pressure the whole structure of
+the rock is altered. The minerals of which it is composed, and the
+new minerals which develop by heat and pressure, arrange
+themselves along planes of cleavage or of shear in rudely parallel
+leaves, or FOLIA. Of this structure, called FOLIATION, we may
+distinguish two types,--a coarser feldspathic type, and a fine
+type in which other minerals than feldspar predominate.
+
+GNEISS is the general name under which are comprised coarsely
+foliated rocks banded with irregular layers of feldspar and other
+minerals. The gneisses appear to be due in many cases to the
+crushing and shearing of deep-seated igneous rocks, such as
+granite and gabbro.
+
+THE CRYSTALLINE SCHISTS, representing the finer types of
+foliation, consist of thin, parallel, crystalline leaves, which
+are often remarkably crumpled. These folia can be distinguished
+from the laminae of sedimentary rocks by their lenticular form and
+lack of continuity, and especially by the fact that they consist
+of platy, crystalline grains, and not of particles rounded by
+wear.
+
+MICA SCHIST, the most common of schists, and in fact of all
+metamorphic rocks, is composed of mica and quartz in alternating
+wavy folia. All gradations between it and phyllite may be traced,
+and in many cases we may prove it due to the metamorphism of
+slates and shales. It is widespread in New England and along the
+eastern side of the Appalachians. TALC SCHIST consists of quartz
+and TALC, a light-colored magnesian mineral of greasy feel, and so
+soft that it can be scratched with the thumb nail.
+
+HORNBLENDE SCHIST, resulting in many cases from the foliation of
+basic igneous rocks, is made of folia of hornblende alternating
+with bands of quartz and feldspar. Hornblende schist is common
+over large areas in the Lake Superior region.
+
+QUARTZ SCHIST is produced from quartzite by the development of
+fine folia of mica along planes of shear. All gradations may be
+found between it and unfoliated quartzite on the one hand and mica
+schist on the other.
+
+Under the resistless pressure of crustal movements almost any
+rocks, sandstones, shales, lavas of all kinds, granites, diorites,
+and gabbros may be metamorphosed into schists by crushing and
+shearing. Limestones, however, are metamorphosed by pressure into
+marble, the grains of carbonate of lime recrystallizing freely to
+interlocking crystals of calcite.
+
+These few examples must suffice of the great class of metamorphic
+rocks. As we have seen, they owe their origin to the alteration of
+both of the other classes of rocks--the sedimentary and the
+igneous--by heat and pressure, assisted usually by the presence of
+water. The fact of change is seen in their hardness arid
+cementation, their more or less complete recrystallization, and
+their foliation; but the change is often so complete that no trace
+of their original structure and mineral composition remains to
+tell whether the rocks from which they were derived were
+sedimentary or igneous, or to what variety of either of these
+classes they belonged.
+
+In many cases, however, the early history of a metamorphic rock
+can be deciphered. Fossils not wholly obliterated may prove it
+originally water-laid. Schists may contain rolled-out pebbles,
+showing their derivation from a conglomerate. Dikes of igneous
+rocks may be followed into a region where they have been foliated
+by pressure. The most thoroughly metamorphosed rocks may sometimes
+be traced out into unaltered sedimentary or igneous rocks, or
+among them may be found patches of little change where their
+history maybe read.
+
+Metamorphism is most common among rocks of the earlier geological
+ages, and most rare among rocks of recent formation. No doubt it
+is now in progress where deep-buried sediments are invaded
+by heat either from intrusive igneous masses or from the earth's
+interior, or are suffering slow deformation under the thrust of
+mountain-making forces.
+
+Suggest how rocks now in process of metamorphism may sometimes be
+exposed to view. Why do metamorphic rocks appear on the surface
+to-day?
+
+MINERAL VEINS
+
+In regions of folded and broken rocks fissures are frequently
+found to be filled with sheets of crystalline minerals deposited
+from solution by underground water, and fissures thus filled are
+known as mineral veins. Much of the importance of mineral veins is
+due to the fact that they are often metalliferous, carrying
+valuable native metals and metallic ores disseminated in fine
+particles, in strings, and sometimes in large masses in the midst
+of the valueless nonmetallic minerals which make up what is known
+as the VEIN STONE.
+
+The most common vein stones are QUARTZ and CALCITE. FLUORITE
+(calcium fluoride), a mineral harder than calcite and
+crystallizing in cubes of various colors, and BARITE (barium
+sulphate), a heavy white mineral, are abundant in many veins.
+
+The gold-bearing quartz veins of California traverse the
+metamorphic slates of the Sierra Nevada Mountains. Below the zone
+of solution (p. 45) these veins consist of a vein stone of quartz
+mingled with pyrite (p. 13), the latter containing threads and
+grains of native gold. But to the depth of about fifty feet from
+the surface the pyrite of the vein has been dissolved, leaving a
+rusty, cellular quartz with grains of the insoluble gold scattered
+through it.
+
+The PLACER DEPOSITS of California and other regions are gold-
+bearing deposits of gravel and sand in river beds. The heavy gold
+is apt to be found mostly near or upon the solid rock, and its
+grains, like those of the sand, are always rounded. How the gold
+came in the placers we may leave the pupil to suggest.
+
+Copper is found in a number of ores, and also in the native metal.
+Below the zone of surface changes the ore of a copper vein is
+often a double sulphide of iron and copper called CHALCOPYRITE, a
+mineral softer than pyrite--it can easily be scratched with a
+knife--and deeper yellow in color. For several score of feet below
+the ground the vein may consist of rusty quartz from which the
+metallic ores have been dissolved; but at the base of the zone of
+solution we may find exceedingly rich deposits of copper ores,--
+copper sulphides, red and black copper oxides, and green and blue
+copper carbonates, which have clearly been brought down in
+solution from the leached upper portion of the vein.
+
+ORIGIN OF MINERAL VEINS. Both vein stones and ores have been
+deposited slowly from solution in water, much as crystals of salt
+are deposited on the sides of a jar of saturated brine. In our
+study of underground water we learned that it is everywhere
+circulating through the permeable rocks of the crust, descending
+to profound depths under the action of gravity and again driven to
+the surface by hydrostatic pressure. Now fissures, wherever they
+occur, form the trunk channels of the underground circulation.
+Water descends from the surface along these rifts; it moves
+laterally from either side to the fissure plane, just as ground
+water seeps through the surrounding rocks from every direction to
+a well; and it ascends through these natural water ways as in an
+artesian well, whenever they intersect an aquifer in which water
+is under hydrostatic pressure.
+
+The waters which deposit vein stones and ores are commonly hot,
+and in many cases they have derived their heat from intrusions of
+igneous rock still uncooled within the crust. The solvent power of
+the water is thus greatly increased, and it takes up into solution
+various substances from the igneous and sedimentary rocks which it
+traverses. For various reasons these substances stances are
+deposited in the vein as ores and vein stones. On rising through
+the fissure the water cools and loses pressure, and its capacity
+to hold minerals in solution is therefore lessened. Besides, as
+different currents meet in the fissure, some ascending, some
+descending, and some coming in from the sides, the chemical
+reaction of these various weak solutions upon one another and upon
+the walls of the vein precipitates the minerals of vein stuffs and
+ores.
+
+As an illustration of the method of vein deposits we may cite the
+case of a wooden box pipe used in the Comstock mines, Nevada, to
+carry the hot water of the mine from one level to another, which
+in ten years was lined with calcium carbonate more than half an
+inch thick.
+
+The Steamboat Springs, Nevada, furnish examples of mineral veins
+in process of formation. The steaming water rises through fissures
+in volcanic rocks and is now depositing in the rifts a vein stone
+of quartz, with metallic ores of iron, mercury, lead, and other
+metals.
+
+RECONCENTRATION. Near the base of the zone of solution veins are
+often stored with exceptionally large and valuable ore deposits.
+This local enrichment of the vein is due to the reconcentration of
+its metalliferous ores. As the surface of the land is slowly
+lowered by weathering and running water, the zone of solution is
+lowered at an equal rate and encroaches constantly on the zone of
+cementation. The minerals of veins are therefore constantly being
+dissolved along their upper portions and carried down the fissures
+by ground water to lower levels, where they are redeposited.
+
+Many of the richest ore deposits are thus due to successive
+concentrations: the ores were leached originally from the rocks to
+a large extent by laterally seeping waters; they were concentrated
+in the ore deposits of the vein chiefly by ascending currents;
+they have been reconcentrated by descending waters in the way just
+mentioned.
+
+THE ORIGINAL SOURCE OF THE METALS. It is to the igneous rocks that
+we may look for the original source of the metals of veins. Lavas
+contain minute percentages of various metallic compounds, and no
+doubt this was the case also with the igneous rocks which formed
+the original earth crust. By the erosion of the igneous rocks the
+metals have been distributed among sedimentary strata, and even
+the sea has taken into solution an appreciable amount of gold and
+other metals, but in this widely diffused condition they are
+wholly useless to man. The concentration which has made them
+available is due to the interaction of many agencies. Earth
+movements fracturing deeply the rocks of the crust, the intrusion
+of heated masses, the circulation of underground waters, have all
+cooperated in the concentration of the metals of mineral veins.
+
+While fissure veins are the most important of mineral veins, the
+latter term is applied also to any water way which has been filled
+by similar deposits from solution. Thus in soluble rocks, such as
+limestones, joints enlarged by percolating water are sometimes
+filled with metalliferous deposits, as, for example, the lead and
+zinc deposits of the upper Mississippi valley. Even a porous
+aquifer may be made the seat of mineral deposits, as in the case
+of some copper-bearing and silver-bearing sandstones of New
+Mexico.
+
+
+
+
+
+PART III
+
+HISTORICAL GEOLOGY
+
+CHAPTER XIV
+
+THE GEOLOGICAL RECORD
+
+
+WHAT A FORMATION RECORDS. We have already learned that each
+individual body of stratified rock, or formation, constitutes a
+record of the time when it was laid. The structure and the
+character of the sediments of each formation tell whether the area
+was land or sea at the time when they were spread; and if the
+former, whether the land was river plain, or lake bed, or was
+covered with wind-blown sands, or by the deposits of an ice sheet.
+If the sediments are marine, we may know also whether they were
+laid in shoal water near the shore or in deeper water out at sea,
+and whether during a period of emergence, or during a period of
+subsidence when the sea transgressed the land. By the same means
+each formation records the stage in the cycle of erosion of the
+land mass from which its sediments were derived. An unconformity
+between two marine formations records the fact that between the
+periods when they were deposited in the sea the area emerged as
+land and suffered erosion. The attitude and structure of the
+strata tell also of the foldings and fractures, the deformation
+and the metamorphism, which they have suffered; and the igneous
+rocks associated with them as lava flows and igneous intrusions
+add other details to the story. Each formation is thus a separate
+local chapter in the geological history of the earth, and its
+strata are its leaves. It contains an authentic record of the
+physical conditions--the geography--of the time and place when and
+where its sediments were laid.
+
+PAST CYCLES OF EROSION. These chapters in the history of the
+planet are very numerous, although much of the record has been
+destroyed in various ways. A succession of different formations is
+usually seen in any considerable section of the crust, such as a
+deep canyon or where the edges of upturned strata are exposed to
+view on the flanks of mountain ranges; and in any extensive area,
+such as a state of the Union or a province of Canada, the number
+of formations outcropping on the surface is large.
+
+It is thus learned that our present continent is made up for. the
+most part of old continental deltas. Some, recently emerged as the
+strata of young coastal plains, are the records of recent cycles
+of erosion; while others were deposited in the early history of
+the earth, and in many instances have been crumpled into
+mountains, which afterwards were leveled to their bases and
+lowered beneath the sea to receive a cover of later sediments
+before they were again uplifted to form land.
+
+The cycle of erosion now in progress and recorded in the layers of
+stratified rock being spread beneath the sea in continental deltas
+has therefore been preceded by many similar cycles. Again and
+again movements of the crust have brought to an end one cycle--
+sometimes when only well under way, and sometimes when drawing
+toward its close--and have begun another. Again and again they
+have added to the land areas which before were sea, with all their
+deposition records of earlier cycles, or have lowered areas of
+land beneath the sea to receive new sediments.
+
+THE AGE OF THE EARTH. The thickness of the stratified rocks now
+exposed upon the eroded surface of the continents is very great.
+In the Appalachian region the strata are seven or eight miles
+thick, and still greater thicknesses have been measured in several
+other mountain ranges. The aggregate thickness of all the
+formations of the stratified rocks of the earth's crust, giving to
+each formation its maximum thickness wherever found, amounts to
+not less than forty miles. Knowing how slowly sediments accumulate
+upon the sea floor, we must believe that the successive cycles
+which the earth has seen stretch back into a past almost
+inconceivably remote, and measure tens of millions and perhaps
+even hundreds of millions of years.
+
+HOW THE FORMATIONS ARE CORRELATED AND THE GEOLOGICAL RECORD MADE
+UP. Arranged in the order of their succession, the formations of
+the earth's crust would constitute a connected record in which the
+geological history of the planet may be read, and therefore known
+as the GEOLOGICAL RECORD. But to arrange the formations in their
+natural order is not an easy task. A complete set of the volumes
+of the record is to be found in no single region. Their leaves and
+chapters are scattered over the land surface of the globe. In one
+area certain chapters may be found, though perhaps with many
+missing leaves, and with intervening chapters wanting, and these
+absent parts perhaps can be supplied only after long search
+through many other regions.
+
+Adjacent strata in any region are arranged according to the LAW OF
+SUPERPOSITION, i.e. any stratum is younger than that on which it
+was deposited, just as in a pile of paper, any sheet was laid
+later than that on which it rests. Where rocks have been
+disturbed, their original attitude must be determined before the
+law can be applied. Nor can the law of superposition be used in
+identifying and comparing the strata of different regions where
+the formations cannot be traced continuously from one region to
+the other.
+
+The formations of different regions are arranged in their true
+order by the LAW OF INCLUDED ORGANISMS; i.e. formations, however
+widely separated, which contain a similar assemblage of fossils
+are equivalent and belong to the same division of geological time.
+
+The correlation of formations by means of fossils may be explained
+by the formations now being deposited about the north Atlantic.
+Lithologically they are extremely various. On the continental
+shelf of North America limestones of different kinds are forming
+off Florida, and sandstones and shales from Georgia northward.
+Separated from them by the deep Atlantic oozes are other
+sedimentary deposits now accumulating along the west coast of
+Europe. If now all these offshore formations were raised to open
+air, how could they be correlated? Surely not by lithological
+likeness, for in this respect they would be quite diverse. All
+would be similar, however, in the fossils which they contain. Some
+fossil species would be identical in all these formations and
+others would be closely allied. Making all due allowance for
+differences in species due to local differences in climate and
+other physical causes, it would still be plain that plants and
+animals so similar lived at the same period of time, and that the
+formations in which their remains were imbedded were
+contemporaneous in a broad way. The presence of the bones of
+whales and other marine mammals would prove that the strata were
+laid after the appearance of mammals upon earth, and imbedded
+relics of man would give a still closer approximation to their
+age. In the same way we correlate the earlier geological
+formations.
+
+For example, in 1902 there were collected the first fossils ever
+found on the antarctic continent. Among the dozen specimens
+obtained were some fossil ammonites (a family of chambered shells)
+of genera which are found on other continents in certain
+formations classified as the Cretaceous system, and which occur
+neither above these formations nor below them. On the basis of
+these few fossils we may be confident that the strata in which
+they were found in the antarctic region were laid in the same
+period of geologic time as were the Cretaceous rocks of the United
+States and Canada.
+
+THE RECORD AS A TIME SCALE. By means of the law of included
+organisms and the law of superposition the formations of different
+countries and continents are correlated and arranged in their
+natural order. When the geological record is thus obtained it may
+be used as a universal time scale for geological history.
+Geological time is separated into divisions corresponding to the
+times during which the successive formations were laid. The
+largest assemblages of formations are known as groups, while the
+corresponding divisions of time are known as eras. Groups are
+subdivided into systems, and systems into series. Series are
+divided into stages and substages,--subdivisions which do not
+concern us in this brief treatise. The corresponding divisions of
+time are given in the following table.
+
+STRATA     TIME
+Group      Era
+System     Period
+Series     Epoch
+
+The geologist is now prepared to read the physical history--the
+geographical development--of any country or of any continent by
+means of its formations, when he has given each formation its true
+place in the geological record as a time scale.
+
+The following chart exhibits the main divisions of the record, the
+name given to each being given also to the corresponding time
+division. Thus we speak of the CAMBRIAN SYSTEM, meaning a certain
+succession of formations which are classified together because of
+broad resemblances in their included organisms; and of the
+CAMBRIAN PERIOD, meaning the time during which these rocks were
+deposited.
+
+Group and Era System and Period Series and Epoch
+
+               |Quaternary-----|Recent
+Cenozoic------|                |Pleistocene
+               |
+               |Tertiary-------|Pliocene
+                                |Miocene
+                                |Eocene
+               |Cretaceous
+Mesozoic------|Jurassic
+               |Triassic
+
+
+                                |Permian
+               |Carboniferous--|Pennsylvanian
+               |                |Mississippian
+Paleozoic-----|Devonian
+               |Silurian
+               |Ordovician
+               |Cambrian
+
+Algonkian
+Archean
+
+FOSSILS AND WHAT THEY TEACH
+
+The geological formations contain a record still more important
+than that of the geographical development of the continents; the
+fossils imbedded in the rocks of each formation tell of the kinds
+of animals and plants which inhabited the earth at that time, and
+from these fossils we are therefore able to construct the history
+of life upon the earth.
+
+FOSSILS. These remains of organisms are found in the strata in all
+degrees of perfection, from trails and tracks and fragmentary
+impressions, to perfectly preserved shells, wood, bones, and
+complete skeletons. As a rule, it is only the hard parts of
+animals and plants which have left any traces in the rocks.
+Sometimes the original hard substance is preserved, but more often
+it has been replaced by some less soluble material. Petrifaction,
+as this process of slow replacement is called, is often carried on
+in the most exquisite detail. When wood, for example, is
+undergoing petrifaction, the woody tissue may be replaced,
+particle by particle, by silica in solution through the action of
+underground waters, even the microscopic structures of the wood
+being perfectly reproduced. In shells originally made of
+ARAGONITE, a crystalline form of carbonate of lime, that mineral
+is usually replaced by CALCITE, a more stable form of the same
+substance. The most common petrifying materials are calcite,
+silica, and pyrite.
+
+Often the organic substance has neither been preserved nor
+replaced, but the FORM has been retained by means of molds and
+casts. Permanent impressions, or molds, may be made in sediments
+not only by the hard parts of organisms, but also by such soft and
+perishable parts as the leaves of plants, and, in the rarest
+instances, by the skin of animals and the feathers of birds. In
+fine-grained limestones even the imprints of jellyfish have been
+retained.
+
+The different kinds of molds and casts may be illustrated by means
+of a clam shell and some moist clay, the latter representing the
+sediments in which the remains of animals and plants are entombed.
+Imbedding the shell in the clay and allowing the clay to harden,
+we have a MOLD OF THE EXTERIOR of the shell, as is seen on cutting
+the clay matrix in two and removing the shell from it. Filling
+this mold with clay of different color, we obtain a CAST OF THE
+EXTERIOR, which represents accurately the original form and
+surface markings of the shell. In nature, shells and other relics
+of animals or plants are often removed by being dissolved by
+percolating waters, and the molds are either filled with sediments
+or with minerals deposited from solution.
+
+Where the fossil is hollow, a CAST OF THE INTERIOR is made in the
+same way. Interior casts of shells reproduce any markings on the
+inside of the valves, and casts of the interior of the skulls of
+ancient vertebrates show the form and size of their brains.
+
+IMPERFECTION OF THE LIFE RECORD. At the present time only the
+smallest fraction of the life on earth ever gets entombed in rocks
+now forming. In the forest great fallen tree trunks, as well as
+dead leaves, decay, and only add a little to the layer of dark
+vegetable mold from which they grew. The bones of land animals
+are, for the most part, left unburied on the surface and are soon
+destroyed by chemical agencies. Even where, as in the swamps of
+river, flood plains and in other bogs, there are preserved the
+remains of plants, and sometimes insects, together with the bones
+of some animal drowned or mired, in most cases these swamp and bog
+deposits are sooner or later destroyed by the shifting channels of
+the stream or by the general erosion of the land.
+
+In the sea the conditions for preservation are more favorable than
+on land; yet even here the proportion of animals and plants whose
+hard parts are fossilized is very small compared with those which
+either totally decay before they are buried in slowly accumulating
+sediments or are ground to powder by waves and currents.
+
+We may infer that during each period of the past, as at the
+present, only a very insignificant fraction of the innumerable
+organisms of sea and land escaped destruction and left in
+continental and oceanic deposits permanent records of their
+existence. Scanty as these original life records must have been,
+they have been largely destroyed by metamorphism of the rocks in
+which they were imbedded, by solution in underground waters, and
+by the vast denudation under which the sediments of earlier
+periods have been eroded to furnish materials for the sedimentary
+records of later times. Moreover, very much of what has escaped
+destruction still remains undiscovered. The immense bulk of the
+stratified rocks is buried and inaccessible, and the records of
+the past which it contains can never be known. Comparatively few
+outcrops have been thoroughly searched for fossils. Although new
+species are constantly being discovered, each discovery may be
+considered as the outcome of a series of happy accidents,--that
+the remains of individuals of this particular species happened to
+be imbedded and fossilized, that they happened to escape
+destruction during long ages, and that they happened to be exposed
+and found.
+
+SOME INFERENCES FROM THE RECORDS OF THE HISTORY OF LIFE UPON THE
+PLANET. Meager as are these records, they set forth plainly some
+important truths which we will now briefly mention.
+
+1. Each series of the stratified rocks, except the very deepest,
+contains vestiges of life. Hence THE EARTH WAS TENANTED BY LIVING
+CREATURES FOR AN UNCALCULATED LENGTH OF TIME BEFORE HUMAN HISTORY
+BEGAN.
+
+2. LIFE ON THE EARTH HAS BEEN EVERCHANGING. The youngest strata
+hold the remains of existing species of animals and plants and
+those of species and varieties closely allied to them. Strata
+somewhat older contain fewer existing species, and in strata of a
+still earlier, but by no means an ancient epoch, no existing
+species are to be found; the species of that epoch and of previous
+epochs have vanished from the living world. During all geological
+time since life began on earth old species have constantly become
+extinct and with them the genera and families to which they
+belong, and other species, genera, and families have replaced
+them. The fossils of each formation differ on the whole from those
+of every other. The assemblage of animals and plants (the FAUNA-
+FLORA) of each epoch differs from that of every other epoch.
+
+In many cases the extinction of a type has been gradual; in other
+instances apparently abrupt. There is no evidence that any
+organism once become extinct has ever reappeared. The duration of
+a species in time, or its "vertical range" through the strata,
+varies greatly. Some species are limited to a stratum a few feet
+in thickness; some may range through an entire formation and be
+found but little modified in still higher beds. A formation may
+thus often be divided into zones, each characterized by its own
+peculiar species. As a rule, the simpler organisms have a longer
+duration as species, though not as individuals, than the more
+complex.
+
+3. THE LARGER ZOOLOGICAL AND BOTANICAL GROUPINGS SURVIVE LONGER
+THAN THE SMALLER. Species are so short-lived that a single
+geological epoch may be marked by several more or less complete
+extinctions of the species of its fauna-flora and their
+replacement by other species. A genus continues with new species
+after all the species with which it began have become extinct.
+Families survive genera, and orders families. Classes are so long-
+lived that most of those which are known from the earliest
+formations are represented by living forms, and no sub-kingdom has
+ever become extinct.
+
+Thus, to take an example from the stony corals,--the ZOANTHARIA,--
+the particular characters--which constituted a certain SPECIES--
+Facosites niagarensis--of the order are confined to the Niagara
+series. Its GENERIC characters appeared in other species earlier
+in the Silurian and continued through the Devonian. Its FAMILY
+characters, represented in different genera and species, range
+from the Ordovician to the close of the Paleozoic; while the
+characters which it shares with all its order, the Zoantharia,
+began in the Cambrian and are found in living species.
+
+4. THE CHANGE IN ORGANISMS HAS BEEN GRADUAL. The fossils of each
+life zone and of each formation of a conformable series closely
+resemble, with some explainable exceptions, those of the beds
+immediately above and below. The animals and plants which tenanted
+the earth during any geological epoch are so closely related to
+those of the preceding and the succeeding epochs that we may
+consider them to be the descendants of the one and the ancestors
+of the other, thus accounting for the resemblance by heredity. It
+is therefore believed that the species of animals and plants now
+living on the earth are the descendants of the species whose
+remains we find entombed in the rocks, and that the chain of life
+has been unbroken since its beginning.
+
+5. THE CHANGE IN SPECIES HAS BEEN A GRADUAL DIFFERENTIATION.
+Tracing the lines of descent of various animals and plants of the
+present backward through the divisions of geologic time, we find
+that these lines of descent converge and unite in simpler and
+still simpler types. The development of life may be represented by
+a tree whose trunk is found in the earliest ages and whose
+branches spread and subdivide to the growing twigs of present
+species.
+
+6. THE CHANGE IN ORGANISMS THROUGHOUT GEOLOGIC TIME HAS BEEN A
+PROGRESSIVE CHANGE. In the earliest ages the only animals and
+plants on the earth were lowly forms, simple and generalized in
+structure; while succeeding ages have been characterized by the
+introduction of types more and more specialized and complex, and
+therefore of higher rank in the scale of being. Thus the Algonkian
+contains the remains of only the humblest forms of the
+invertebrates. In the Cambrian, Ordovician, and Silurian the
+invertebrates were represented in all their subkingdoms by a
+varied fauna. In the Devonian, fishes--the lowest of the
+vertebrates--became abundant. Amphibians made their entry on the
+stage in the Carboniferous, and reptiles came to rule the world in
+the Mesozoic. Mammals culminated in the Tertiary in strange forms
+which became more and more like those of the present as the long
+ages of that era rolled on; and latest of all appeared the noblest
+product of the creative process, man.
+
+Just as growth is characteristic of the individual life, so
+gradual, progressive change, or evolution, has characterized the
+history of life upon the planet. The evolution of the organic
+kingdom from its primitive germinal forms to the complex and
+highly organized fauna-flora of to-day may be compared to the
+growth of some noble oak as it rises from the acorn, spreading
+loftier and more widely extended branches as it grows.
+
+7. While higher and still higher types have continually been
+evolved, until man, the highest of all, appeared, THE LOWER AND
+EARLIER TYPES HAVE GENERALLY PERSISTED. Some which reached their
+culmination early in the history of the earth have since changed
+only in slight adjustments to a changing environment. Thus the
+brachiopods, a type of shellfish, have made no progress since the
+Paleozoic, and some of their earliest known genera are represented
+by living forms hardly to be distinguished from their ancient
+ancestors. The lowest and earliest branches of the tree of life
+have risen to no higher levels since they reached their climax of
+development long ago.
+
+8. A strange parallel has been found to exist between the
+evolution of organisms and the development of the individual. In
+the embryonic stages of its growth the individual passes swiftly
+through the successive stages through which its ancestors evolved
+during the millions of years of geologic time. THE DEVELOPMENT OF
+THE INDIVIDUAL RECAPITULATES THE EVOLUTION OF THE RACE.
+
+The frog is a typical amphibian. As a tadpole it passes through a
+stage identical in several well-known features with the maturity
+of fishes; as, for example, its aquatic life, the tail by which it
+swims, and the gills through which it breathes. It is a fair
+inference that the tadpole stage in the life history of the frog
+represents a stage in the evolution of its kind,--that the
+Amphibia are derived from fishlike ancestral forms. This inference
+is amply confirmed in the geological record; fishes appeared
+before Amphibia and were connected with them by transitional
+forms.
+
+THE GREAT LENGTH OF GEOLOGIC TIME INFERRED FROM THE SLOW CHANGE OF
+SPECIES. Life forms, like land forms, are thus subject to change
+under the influence of their changing environment and of forces
+acting from within. How slowly they change may be seen in the
+apparent stability of existing species. In the lifetime of the
+observer and even in the recorded history of man, species seem as
+stable as the mountain and the river. But life forms and land
+forms are alike variable, both in nature and still more under the
+shaping hand of man. As man has modified the face of the earth
+with his great engineering works, so he has produced widely
+different varieties of many kinds of domesticated plants and
+animals, such as the varieties of the dog and the horse, the apple
+and the rose, which may be regarded in some respects as new
+species in the making. We have assumed that land forms have
+changed in the past under the influence of forces now in
+operation. Assuming also that life forms have always changed as
+they are changing at present, we come to realize something of the
+immensity of geologic time required for the evolution of life from
+its earliest lowly forms up to man.
+
+It is because the onward march of life has taken the same general
+course the world over that we are able to use it as a UNIVERSAL
+TIME SCALE and divide geologic time into ages and minor
+subdivisions according to the ruling or characteristic organisms
+then living on the earth. Thus, since vertebrates appeared, we
+have in succession the Age of Fishes, the Age of Amphibians, the
+Age of Reptiles, and the Age of Mammals.
+
+The chart given on page 295 is thus based on the law of
+superposition and the law of the evolution of organisms. The first
+law gives the succession of the formations in local areas. The
+fossils which they contain demonstrate the law of the progressive
+appearance of organisms, and by means of this law the formations
+of different countries are correlated and set each in its place in
+a universal time scale and grouped together according to the
+affinities of their imbedded organic remains.
+
+GEOLOGIC TIME DIVISIONS COMPARED WITH THOSE OF HUMAN HISTORY. We
+may compare the division of geologic time into eras, periods, and
+other divisions according to the dominant life of the time, to the
+ill-defined ages into which human history is divided according to
+the dominance of some nation, ruler, or other characteristic
+feature. Thus we speak of the DARK AGES, the AGE OF ELIZABETH, and
+the AGE OF ELECTRICITY. These crude divisions would be of much
+value if, as in the case of geologic time, we had no exact
+reckoning of human history by years.
+
+And as the course of human history has flowed in an unbroken
+stream along quiet reaches of slow change and through periods of
+rapid change and revolution, so with the course of geologic
+history. Periods of quiescence, in which revolutionary forces are
+perhaps gathering head, alternate with periods of comparatively
+rapid change in physical geography and in organisms, when new and
+higher forms appear which serve to draw the boundary line of new
+epochs. Nevertheless, geological history is a continuous progress;
+its periods and epochs shade into one another by imperceptible
+gradations, and all our subdivisions must needs be vague and more
+or less arbitrary.
+
+HOW FOSSILS TELL OF THE GEOGRAPHY OF THE PAST. Fossils are used
+not only as a record of the development of life upon the earth,
+but also in testimony to the physical geography of past epochs.
+They indicate whether in any region the climate was tropical,
+temperate, or arctic. Since species spread slowly from some center
+of dispersion where they originate until some barrier limits their
+migration farther, the occurrence of the same species in rocks of
+the same system in different countries implies the absence of such
+barriers at the period. Thus in the collection of antarctic
+fossils referred to on page 294 there were shallow-water marine
+shells identical in species with Mesozoic shells found in India
+and in the southern extremity of South America. Since such
+organisms are not distributed by the currents of the deep sea and
+cannot migrate along its bottom, we infer a shallow-water
+connection in Mesozoic times between India, South America, and the
+antarctic region. Such a shallow-water connection would be offered
+along the marginal shelf of a continent uniting these now widely
+separated countries.
+
+
+
+
+
+CHAPTER XV
+
+THE PRE-CAMBRIAN SYSTEMS
+
+
+THE EARTH'S BEGINNINGS. The geological record does not tell us of
+the beginnings of the earth. The history of the planet, as we have
+every reason to believe, stretches far back beyond the period of
+the oldest stratified rocks, and is involved in the history of the
+solar system and of the nebula,--the cloud of glowing gases or of
+cosmic dust,--from which the sun and planets are believed to have
+been derived.
+
+THE NEBULAR HYPOTHESIS. It is possible that the earth began as a
+vaporous, shining sphere, formed by the gathering together of the
+material of a gaseous ring which had been detached from a cooling
+and shrinking nebula. Such a vaporous sphere would condense to a
+liquid, fiery globe, whose surface would become cold and solid,
+while the interior would long remain intensely hot because of the
+slow conductivity of the crust. Under these conditions the
+primeval atmosphere of the earth must have contained in vapor the
+water now belonging to the earth's crust and surface. It held also
+all the oxygen since locked up in rocks by their oxidation, and
+all the carbon dioxide which has since been laid away in
+limestones, besides that corresponding to the carbon of
+carbonaceous deposits, such as peat, coal, and petroleum. On this
+hypothesis the original atmosphere was dense, dark, and noxious,
+and enormously heavier than the atmosphere at present.
+
+THE ACCRETION HYPOTHESIS. On the other hand, it has been recently
+suggested that the earth may have grown to its present size by the
+gradual accretion of meteoritic masses. Such cold, stony bodies
+might have come together at so slow a rate that the heat caused by
+their impact would not raise sensibly the temperature of the
+growing planet. Thus the surface of the earth may never have been
+hot and luminous; but as the loose aggregation of stony masses
+grew larger and was more and more compressed by its own
+gravitation, the heat thus generated raised the interior to high
+temperatures, while from time to time molten rock was intruded
+among the loose, cold meteoritic masses of the crust and outpoured
+upon the surface.
+
+It is supposed that the meteorites of which the earth was built
+brought to it, as meteorites do now, various gases shut up within
+their pores. As the heat of the interior increased, these gases
+transpired to the surface and formed the primitive atmosphere and
+hydrosphere. The atmosphere has therefore grown slowly from the
+smallest beginnings. Gases emitted from the interior in volcanic
+eruptions and in other ways have ever added to it, and are adding
+to it now. On the other hand, the atmosphere has constantly
+suffered loss, as it has been robbed of oxygen by the oxidation of
+rocks in weathering, and of carbon dioxide in the making of
+limestones and carbonaceous deposits.
+
+While all hypotheses of the earth's beginnings are as yet unproved
+speculations, they serve to bring to mind one of the chief lessons
+which geology has to teach,--that the duration of the earth in
+time, like the extension of the universe in space, is vastly
+beyond the power of the human mind to realize. Behind the history
+recorded in the rocks, which stretches back for many million
+years, lies the long unrecorded history of the beginnings of the
+planet; and still farther in the abysses of the past are dimly
+seen the cycles of the evolution of the solar system and of the
+nebula which gave it birth.
+
+We pass now from the dim realm of speculation to the earliest era
+of the recorded history of the earth, where some certain facts may
+be observed and some sure inferences from them may be drawn.
+
+THE ARCHEAN.
+
+The oldest known sedimentary strata, wherever they are exposed by
+uplift and erosion, are found to be involved with a mass of
+crystalline rocks which possesses the same characteristics in all
+parts of the world. It consists of foliated rocks, gneisses, and
+schists of various kinds, which have been cut with dikes and other
+intrusions of molten rock, and have been broken, crumpled, and
+crushed, and left in interlocking masses so confused that their
+true arrangement can usually be made out only with the greatest
+difficulty if at all. The condition of this body of crystalline
+rocks is due to the fact that they have suffered not only from the
+faultings, foldings, and igneous intrusions of their time, but
+necessarily, also, from those of all later geological ages.
+
+At present three leading theories are held as to the origin of
+these basal crystalline rocks.
+
+1. They are considered by perhaps the majority of the geologists
+who have studied them most carefully to be igneous rocks intruded
+in a molten state among the sedimentary rocks involved with them.
+In many localities this relation is proved by the phenomena of
+contact; but for the most part the deformations which the rocks
+have since suffered again and again have been sufficient to
+destroy such evidence if it ever existed.
+
+2. An older view regards them as profoundly altered sedimentary
+strata, the most ancient of the earth.
+
+3. According to a third theory they represent portions of the
+earth's original crust; not, indeed, its original surface, but
+deeper portions uncovered by erosion and afterwards mantled with
+sedimentary deposits. All these theories agree that the present
+foliated condition of these rocks is due to the intense
+metamorphism which they have suffered.
+
+It is to this body of crystalline rocks and the stratified rocks
+involved with it, which form a very small proportion of its mass,
+that the term ARCHEAN (Greek, ARCHE, beginning) is applied by many
+geologists.
+
+THE ALGONKIAN
+
+In some regions there rests unconformably on the Archean an
+immense body of stratified rocks, thousands and in places even
+scores of thousands of feet thick, known as the ALGONKIAN. Great
+unconformities divide it into well-defined systems, but as only
+the scantiest traces of fossils appear here and there among its
+strata, it is as yet impossible to correlate the formations of
+different regions and to give them names of more than local
+application. We will describe the Algonkian rocks of two typical
+areas.
+
+THE GRAND CANYON OF THE COLORADO. We have already studied a very
+ancient peneplain whose edge is exposed to view deep on the walls
+of the Colorado Canyon. The formation of flat-lying sandstone
+which covers this buried land surface is proved by its fossils to
+belong to the Cambrian,--the earliest period of the Paleozoic era.
+The tilted rocks on whose upturned edges the Cambrian sandstone
+rests are far older, for the physical break which separates them
+from it records a time interval during which they were upheaved to
+mountainous ridges and worn down to a low plain. They are
+therefore classified as Algonkian. They comprise two immense
+series. The upper is more than five thousand feet thick and
+consists of shales and sandstones with some limestones. Separated
+from it by an unconformity which does not appear in Figure 207,
+the lower division, seven thousand feet thick, consists chiefly of
+massive reddish sandstones with seven or more sheets of lava
+interbedded. The lowest member is a basal conglomerate composed of
+pebbles derived from the erosion of the dark crumpled schists
+beneath,--schists which are supposed to be Archean. As shown in
+Figure 207, a strong unconformity parts the schists and the
+Algonkian. The floor on which the Algonkian rests is remarkably
+even, and here again is proved an interval of incalculable length,
+during which an ancient land mass of Archean rocks was baseleveled
+before it received the cover of the sediments of the later age.
+
+THE LAKE SUPERIOR REGION. In eastern Canada an area of pre-
+Cambrian rocks, Archean and Algonkian, estimated at two million
+square miles, stretches from the Great Lakes and the St. Lawrence
+River northward to the confines of the continent, inclosing Hudson
+Bay in the arms of a gigantic U. This immense area, which we have
+already studied as the Laurentian peneplain, extends southward
+across the Canadian border into northern Minnesota, Wisconsin, and
+Michigan. The rocks of this area are known to be pre-Cambrian; for
+the Cambrian strata, wherever found, lie unconformably upon them.
+
+The general relations of the formations of that portion of the
+area which lies about Lake Superior are shown in Figure 262. Great
+unconformities, UU' separate the Algonkian both from the Archean
+and from the Cambrian, and divide it into three distinct systems,
+--the LOWER HURONIAN, the UPPER HURONIAN, and the KEWEENAWAN. The
+Lower and the Upper Huronian consist in the main of old sea muds
+and sands and limy oozes now changed to gneisses, schists,
+marbles, quartzites, slates, and other metamorphic rocks. The
+Keweenawan is composed of immense piles of lava, such as those of
+Iceland, overlain by bedded sandstones. What remains of these rock
+systems after the denudation of all later geologic ages is
+enormous. The Lower Huronian is more than a mile thick, the Upper
+Huronian more than two miles thick, while the Keweenawan exceeds
+nine miles in thickness. The vast length of Algonkian time is
+shown by the thickness of its marine deposits and by the cycles of
+erosion which it includes. In Figure 262 the student may read an
+outline of the history of the Lake Superior region, the
+deformations which it suffered, their relative severity, the times
+when they occurred, and the erosion cycles marked by the
+successive unconformities.
+
+OTHER PRE-CAMBRIAN AREAS IN NORTH AMERICA. Pre-Cambrian rocks are
+exposed in various parts of the continent, usually by the erosion
+of mountain ranges in which their strata were infolded. Large
+areas occur in the maritime provinces of Canada. The core of the
+Green Mountains of Vermont is pre-Cambrian, and rocks of these
+systems occur in scattered patches in western Massachusetts. Here
+belong also the oldest rocks of the Highlands of the Hudson and of
+New Jersey. The Adirondack region, an outlier of the Laurentian
+region, exposes pre-Cambrian rocks, which have been metamorphosed
+and tilted by the intrusion of a great boss of igneous rock out of
+which the central peaks are carved. The core of the Blue Ridge and
+probably much of the Piedmont Belt are of this age. In the Black
+Hills the irruption of an immense mass of granite has caused or
+accompanied the upheaval of pre-Cambrian strata and metamorphosed
+them by heat and pressure into gneisses, schists, quartzites, and
+slates. In most of these mountainous regions the lowest strata are
+profoundly changed by metamorphism, and they can be assigned to
+the pre-Cambrian only where they are clearly overlain
+unconformably by formations proved to be Cambrian by their
+fossils. In the Belt Mountains of Montana, however, the Cambrian
+is underlain by Algonkian sediments twelve thousand feet thick,
+and but little altered.
+
+MINERAL WEALTH OF THE PRE-CAMBRIAN ROCKS. The pre-Cambrian rocks
+are of very great economic importance, because of their extensive
+metamorphism and the enormous masses of igneous rock which they
+involve. In many parts of the country they are the source of
+supply of granite, gneiss, marble, slate, and other such building
+materials. Still more valuable are the stores of iron and copper
+and other metals which they contain.
+
+At the present time the pre-Cambrian region about Lake Superior
+leads the world in the production of iron ore, its output for 1903
+being more than five sevenths of the entire output of the whole
+United States, and exceeding that of any foreign country. The ore
+bodies consist chiefly of the red oxide of iron (hematite) and
+occur in troughs of the strata, underlain by some impervious rock.
+A theory held by many refers the ultimate source of the iron to
+the igneous rocks of the Archean. When these rocks were upheaved
+and subjected to weathering, their iron compounds were decomposed.
+Their iron was leached out and carried away to be laid in the
+Algonkian water bodies in beds of iron carbonate and other iron
+compounds. During the later ages, after the Algonkian strata had
+been uplifted to form part of the continent, a second
+concentration has taken place. Descending underground waters
+charged with oxygen have decomposed the iron carbonate and
+deposited the iron, in the form of iron oxide, in troughs of the
+strata where their downward progress was arrested by impervious
+floors.
+
+The pre-Cambrian rocks of the eastern United States also are rich
+in iron. In certain districts, as in the Highlands of New Jersey,
+the black oxide of iron (magnetite) is so abundant in beds and
+disseminated grains that the ordinary surveyor's compass is
+useless.
+
+The pre-Cambrian copper mines of the Lake Superior region are
+among the richest on the globe. In the igneous rocks copper, next
+to iron, is the most common of all the useful metals, and it was
+especially abundant in the Keweenawan lavas. After the Keweenawan
+was uplifted to form land, percolating waters leached out much of
+the copper diffused in the lava sheets and deposited it within
+steam blebs as amygdules of native copper, in cracks and fissures,
+and especially as a cement, or matrix, in the interbedded gravels
+which formed the chief aquifers of the region. The famous Calumet
+and Hecla mine follows down the dip of the strata to the depth of
+nearly a mile and works such an ancient conglomerate whose matrix
+is pure copper.
+
+THE APPEARANCE OF LIFE. Sometime during the dim ages preceding the
+Cambrian, whether in the Archean or in the Algonkian we know not,
+occurred one of the most important events in the history of the
+earth. Life appeared for the first time upon the planet. Geology
+has no evidence whatever to offer as to whence or how life came.
+All analogies lead us to believe that its appearance must have
+been sudden. Its earliest forms are unknown, but analogy suggests
+that as every living creature has developed from a single cell, so
+the earliest organisms upon the globe--the germs from which all
+later life is supposed to have been evolved--were tiny,
+unicellular masses of protoplasm, resembling the amoeba of to-day
+in the simplicity of their structure.
+
+Such lowly forms were destitute of any hard parts and could leave
+no evidence of their existence in the record of the rocks. And of
+their supposed descendants we find so few traces in the pre-
+Cambrian strata that the first steps in organic evolution must be
+supplied from such analogies in embryology as the following. The
+fertilized ovum, the cell with which each animal begins its life,
+grows and multiplies by cell division, and develops into a hollow
+globe of cells called the BLASTOSPHERE. This stage is succeeded by
+the stage of the GASTRULA,--an ovoid or cup-shaped body with a
+double wall of cells inclosing a body cavity, and with an opening,
+the primitive mouth. Each of these early embryological stages is
+represented by living animals,--the undivided cell by the
+PROTOZOA, the blastosphere by some rare forms, and the gastrula in
+the essential structure of the COELENTERATES,--the subkingdom to
+which the fresh-water hydra and the corals belong. All forms of
+animal life, from the coelenterates to the mammals, follow the
+same path in their embryological development as far as the
+gastrula stage, but here their paths widely diverge, those of each
+subkingdom going their own separate ways.
+
+We may infer, therefore, that during the pre-Cambrian periods
+organic evolution followed the lines thus dimly traced. The
+earliest one-celled protozoa were probably succeeded by many-
+celled animals of the type of the blastosphere, and these by
+gastrula-like organisms. From the gastrula type the higher sub-
+divisions of animal life probably diverged, as separate branches
+from a common trunk. Much or all of this vast differentiation was
+accomplished before the opening of the next era; for all the
+subkingdoms are represented in the Cambrian except the
+vertebrates.
+
+EVIDENCES OF PRE-CAMBRIAN LIFE. An indirect evidence of life
+during the pre-Cambrian periods is found in the abundant and
+varied fauna of the next period; for, if the theory of evolution
+is correct, the differentiation of the Cambrian fauna was a long
+process which might well have required for its accomplishment a
+large part of pre-Cambrian time.
+
+Other indirect evidences are the pre-Cambrian limestones, iron
+ores, and graphite deposits, since such minerals and rocks have
+been formed in later times by the help of organisms. If the
+carbonate of lime of the Algonkian limestones and marbles was
+extracted from sea water by organisms, as is done at present by
+corals, mollusks, and other humble animals and plants, the life of
+those ancient seas must have been abundant. Graphite, a soft black
+mineral composed of carbon and used in the manufacture of lead
+pencils and as a lubricant, occurs widely in the metamorphic pre-
+Cambrian rocks. It is known to be produced in some cases by the
+metamorphism of coal, which itself is formed of decomposed vegetal
+tissues. Seams of graphite may therefore represent accumulations
+of vegetal matter such as seaweed. But limestone, iron ores, and
+graphite can be produced by chemical processes, and their presence
+in the pre-Cambrian makes it only probable, and not certain, that
+life existed at that time.
+
+PRE-CAMBRIAN FOSSILS. Very rarely has any clear trace of an
+organism been found in the most ancient chapters of the geological
+record, so many of their leaves have been destroyed and so far
+have their pages been defaced. Omitting structures whose organic
+nature has been questioned, there are left to mention a tiny
+seashell of one of the most lowly types,--a DISCINA from the pre-
+Cambrian rocks of the Colorado Canyon,--and from the pre-Cambrian
+rocks of Montana trails of annelid worms and casts of their
+burrows in ancient beaches, and fragments of the tests of
+crustaceans. These diverse forms indicate that before the
+Algonkian had closed, life was abundant and had widely
+differentiated. We may expect that other forms will be discovered
+as the rocks are closely searched.
+
+PRE-CAMBRIAN GEOGRAPHY. Our knowledge is far too meager to warrant
+an attempt to draw the varying outlines of sea and land during the
+Archean and Algonkian eras. Pre-Cambrian time probably was longer
+than all later geological time down to the present, as we may
+infer from the vast thicknesses of its rocks and the
+unconformities which part them. We know that during its long
+periods land masses again and again rose from the sea, were worn
+low, and were submerged and covered with the waste of other lands.
+But the formations of separated regions cannot be correlated
+because of the absence of fossils, and nothing more can be made
+out than the detached chapters of local histories, such as the
+outline given of the district about Lake Superior.
+
+The pre-Cambrian rocks show no evidence of any forces then at work
+upon the earth except the forces which are at work upon it now.
+The most ancient sediments known are so like the sediments now
+being laid that we may infer that they were formed under
+conditions essentially similar to those of the present time. There
+is no proof that the sands of the pre-Cambrian sandstones were
+swept by any more powerful waves and currents than are offshore
+sands to-day, or that the muds of the pre-Cambrian shales settled
+to the sea floor in less quiet water than such muds settle in at
+present. The pre-Cambrian lands were, no doubt, worn by wind and
+weather, beaten by rain, and furrowed by streams as now, and, as
+now, they fronted the ocean with beaches on which waves dashed and
+along which tidal currents ran.
+
+Perhaps the chief difference between the pre-Cambrian and the
+present was the absence of life upon the land. So far as we have
+any knowledge, no forests covered the mountain sides, no verdure
+carpeted the plains, and no animals lived on the ground or in the
+air. It is permitted to think of the most ancient lands as deserts
+of barren rock and rock waste swept by rains and trenched by
+powerful streams. We may therefore suppose that the processes of
+their destruction went on more rapidly than at present.
+
+
+
+
+
+CHAPTER XVI
+
+THE CAMBRIAN
+
+
+THE PALEOZOIC ERA. The second volume of the geological record,
+called the Paleozoic (Greek, PALAIOS, ancient; ZOE, life), has
+come down to us far less mutilated and defaced than has the first
+volume, which contains the traces of the most ancient life of the
+globe. Fossils are far more abundant in the Paleozoic than in the
+earlier strata, while the sediments in which they were entombed
+have suffered far less from metamorphism and other causes, and
+have been less widely buried from view, than the strata of the
+pre-Cambrian groups. By means of their fossils we can correlate
+the formations of widely separated regions from the beginning of
+the Paleozoic on, and can therefore trace some outline of the
+history of the continents.
+
+Paleozoic time, although shorter than the pre-Cambrian as measured
+by the thickness of the strata, must still be reckoned in millions
+of years. During this vast reach of time the changes in organisms
+were very great. It is according to the successive stages in the
+advance of life that the Paleozoic formations are arranged in five
+systems,--the CAMBRIAN, the ORDOVICIAN, the SILURIAN, the
+DEVONIAN, and the CARBONIFEROUS. On the same basis the first three
+systems are grouped together as the older Paleozoic, because they
+alike are characterized by the dominance of the invertebrates;
+while the last two systems are united in the later Paleozoic, and
+are characterized, the one by the dominance of fishes, and the
+other by the appearance of amphibians and reptiles.
+
+Each of these systems is world-wide in its distribution, and may
+be recognized on any continent by its own peculiar fauna. The
+names first given them in Great Britain have therefore come into
+general use, while their subdivisions, which often cannot be
+correlated in different countries and different regions, are
+usually given local names.
+
+The first three systems were named from the fact that their strata
+are well displayed in Wales. The Cambrian carries the Roman name
+of Wales, and the Ordovician and Silurian the names of tribes of
+ancient Britons which inhabited the same country. The Devonian is
+named from the English county Devon, where its rocks were early
+studied. The Carboniferous was so called from the large amount of
+coal which it was found to contain in Great Britain and
+continental Europe.
+
+THE CAMBRIAN
+
+DISTRIBUTION OF STRATA. The Cambrian rocks outcrop in narrow belts
+about the pre-Cambrian areas of eastern Canada and the Lake
+Superior region, the Adirondacks and the Green Mountains. Strips
+of Cambrian formations occupy troughs in the pre-Cambrian rocks of
+New England and the maritime provinces of Canada; a long belt
+borders on the west the crystalline rocks of the Blue Ridge; and
+on the opposite side of the continent the Cambrian reappears in
+the mountains of the Great Basin and the Canadian Rockies. In the
+Mississippi valley it is exposed in small districts where uplift
+has permitted the stripping off of younger rocks. Although the
+areas of outcrop are small, we may infer that Cambrian rocks were
+widely deposited over the continent of North America.
+
+PHYSICAL GEOGRAPHY. The Cambrian system of North America comprises
+three distinct series, the LOWER CAMBRIAN, the MIDDLE CAMBRIAN,
+and the UPPER CAMBRIAN, each of which is characterized by its own
+peculiar fauna. In sketching the outlines of the continent as it
+was at the beginning of the Paleozoic, it must be remembered that
+wherever the Lower Cambrian formations now are found was certainly
+then sea bottom, and wherever the Lower Cambrian are wanting, and
+the next formations rest directly on pre-Cambrian rocks, was
+probably then land.
+
+EARLY CAMBRIAN GEOGRAPHY. In this way we know that at the opening
+of the Cambrian two long, narrow mediterranean seas stretched from
+north to south across the continent. The eastern sea extended from
+the Gulf of St. Lawrence down the Champlain-Hudson valley and
+thence along the western base of the Blue Ridge south at least to
+Alabama. The western sea stretched from the Canadian Rockies over
+the Great Basin and at least as far south as the Grand Canyon of
+the Colorado in Arizona.
+
+Between these mediterraneans lay a great central land which
+included the pre-Cambrian U-shaped area of the Laurentian
+peneplain, and probably extended southward to the latitude of New
+Orleans. To the east lay a land which we may designate as
+APPALACHIA, whose western shore line was drawn along the site of
+the present Blue Ridge, but whose other limits are quite unknown.
+The land of Appalachia must have been large, for it furnished a
+great amount of waste during the entire Paleozoic era, and its
+eastern coast may possibly have lain even beyond the edge of the
+present continental shelf. On the western side of the continent a
+narrow land occupied the site of the Sierra Nevada Mountains.
+
+Thus, even at the beginning of the Paleozoic, the continental
+plateau of North America had already been left by crustal
+movements in relief above the abysses of the great oceans on
+either side. The mediterraneans which lay upon it were shallow, as
+their sediments prove. They were EPICONTINENTAL SEAS; that is,
+they rested UPON (Greek, EPI) the submerged portion of the
+continental plateau. We have no proof that the deep ocean ever
+occupied any part of where North America now is.
+
+The Middle and Upper Cambrian strata are found together with the
+Lower Cambrian over the area of both the eastern and the western
+mediterraneans, so that here the sea continued during the entire
+period. The sediments throughout are those of shoal water. Coarse
+cross-bedded sandstones record the action of strong shifting
+currents which spread coarse waste near shore and winnowed it of
+finer stuff. Frequent ripple marks on the bedding planes of the
+strata prove that the loose sands of the sea floor were near
+enough to the surface to be agitated by waves and tidal currents.
+Sun cracks show that often the outgoing tide exposed large muddy
+flats to the drying action of the sun. The fossils, also, of the
+strata are of kinds related to those which now live in shallow
+waters near the shore.
+
+The sediments which gathered in the mediterranean seas were very
+thick, reaching in places the enormous depth of ten thousand feet.
+Hence the bottoms of these seas were sinking troughs, ever filling
+with waste from the adjacent land as fast as they subsided.
+
+LATE CAMBRIAN GEOGRAPHY. The formations of the Middle and Upper
+Cambrian are found resting unconformably on the pre-Cambrian rocks
+from New York westward into Minnesota and at various points in the
+interior, as in Missouri and in Texas. Hence after earlier
+Cambrian time the central land subsided, with much the same effect
+as if the Mississippi valley were now to lower gradually, and the
+Gulf of Mexico to spread northward until it entered Lake Superior.
+The Cambrian seas transgressed the central land and strewed far
+and wide behind their advancing beaches the sediments of the later
+Cambrian upon an eroded surface of pre-Cambrian rocks.
+
+The succession of the Cambrian formations in North America records
+many minor oscillations and varying conditions of physical
+geography; yet on the whole it tells of widening seas and lowering
+lands. Basal conglomerates and coarse sandstones which must have
+been laid near shore are succeeded by shaly sandstones, sandy
+shales, and shales. Toward the top of the series heavy beds of
+limestone, extending from the Blue Ridge to Missouri, speak of
+clear water, and either of more distant shores or of neighboring
+lands which were worn or sunk so low that for the most part their
+waste was carried to the sea in solution.
+
+In brief, the Cambrian was a period of submergence. It began with
+the larger part of North America emerged as great land masses. It
+closed with most of the interior of the continental plateau
+covered with a shallow sea.
+
+THE LIFE OF THE CAMBRIAN PERIOD
+
+It is now for the first time that we find preserved in the
+offshore deposits of the Cambrian seas enough remains of animal
+life to be properly called a fauna. Doubtless these remains are
+only the most fragmentary representation of the life of the time,
+for the Cambrian rocks are very old and have been widely
+metamorphosed. Yet the five hundred and more species already
+discovered embrace all the leading types of invertebrate life, and
+are so varied that we must believe that their lines of descent
+stretch far back into the pre-Cambrian past.
+
+PLANTS. No remains of plants have been found in Cambrian strata,
+except some doubtful markings, as of seaweed.
+
+SPONGES. The sponges, the lowest of the multicellular animals,
+were represented by several orders. Their fossils are recognized
+by the siliceous spicules, which, as in modern sponges, either
+were scattered through a mass of horny fibers or were connected in
+a flinty framework.
+
+COELENTERATES. This subkingdom includes two classes of interest to
+the geologist,--the HYDROZOA, such as the fresh-water hydra and
+the jellyfish, and the CORALS. Both classes existed in the
+Cambrian.
+
+The Hydrozoa were represented not only by jellyfish but also by
+the GRAPTOLITE, which takes its name from a fancied resemblance of
+some of its forms to a quill pen. It was a composite animal with a
+horny framework, the individuals of the colony living in cells
+strung on one or both sides along a hollow stem, and communicating
+by means of a common flesh in this central tube. Some graptolites
+were straight, and some curved or spiral; some were single
+stemmed, and others consisted of several radial stems united.
+Graptolites occur but rarely in the Upper Cambrian. In the
+Ordovician and Silurian they are very plentiful, and at the close
+of the Silurian they pass out of existence, never to return.
+
+CORALS are very rarely found in the Cambrian, and the description
+of their primitive types is postponed to later chapters treating
+of periods when they became more numerous.
+
+ECHINODERMS. This subkingdom comprises at present such familiar
+forms as the crinoid, the starfish, and the sea urchin. The
+structure of echinoderms is radiate. Their integument is hardened
+with plates or particles of carbonate of lime.
+
+Of the free echinoderms, such as the starfish and the sea urchin,
+the former has been found in the Cambrian rocks of Europe, but
+neither have so far been discovered in the strata of this period
+in North America. The stemmed and lower division of the
+echinoderms was represented by a primitive type, the CYSTOID, so
+called from its saclike form, A small globular or ovate "calyx" of
+calcareous plates, with an aperture at the top for the mouth,
+inclosed the body of the animal, and was attached to the sea
+bottom by a short flexible stalk consisting of disks of carbonate
+of lime held together by a central ligament.
+
+ARTHOPODS. These segmented animals with "jointed feet," as their
+name suggests, may be divided in a general way into water
+breathers and air breathers. The first-named and lower division
+comprises the class of the CRUSTACEA,--arthropods protected by a
+hard exterior skeleton, or "crust,"--of which crabs, crayfish, and
+lobsters are familiar examples. The higher division, that of the
+air breathers, includes the following classes: spiders, scorpions,
+centipedes, and insects.
+
+THE TRILOBITE. The aquatic arthropods, the Crustacea, culminated
+before the air breathers; and while none of the latter are found
+in the Cambrian, the former were the dominant life of the time in
+numbers, in size, and in the variety of their forms. The leading
+crustacean type is the TRILOBITE, which takes its name from the
+three lobes into which its shell is divided longitudinally. There
+are also three cross divisions,--the head shield, the tail shield,
+and between the two the thorax, consisting of a number of distinct
+and unconsolidated segments. The head shield carries a pair of
+large, crescentic, compound eyes, like those of the insect. The
+eye varies greatly in the number of its lenses, ranging from
+fourteen in some species to fifteen thousand in others. Figure
+268, C, is a restoration of the trilobite, and shows the
+appendages, which are found preserved only in the rarest cases.
+
+During the long ages of the Cambrian the trilobite varied greatly.
+Again and again new species and genera appeared, while the older
+types became extinct. For this reason and because of their
+abundance, trilobites are used in the classification of the
+Cambrian system. The Lower Cambrian is characterized by the
+presence of a trilobitic fauna in which the genus Olenellus is
+predominant. This, the OLENELLUS ZONE, is one of the most
+important platforms in the entire geological series; for, the
+world over, it marks the beginning of Paleozoic time, while all
+underlying strata are classified as pre-Cambrian. The Middle
+Cambrian is marked by the genus Paradoxides, and the Upper
+Cambrian by the genus Olenus. Some of the Cambrian trilobites were
+giants, measuring as much as two feet long, while others were the
+smallest of their kind, a fraction of an inch in length.
+
+Another type of crustacean which lived in the Cambrian and whose
+order is still living is illustrated in Figure 269.
+
+WORMS. Trails and burrows of worms have been left on the sea
+beaches and mud flats of all geological times from the Algonkian
+to the present.
+
+BRACHIOPODS. These soft-bodied animals, with bivalve shells and
+two interior armlike processes which served for breathing,
+appeared in the Algonkian, and had now become very abundant. The
+two valves of the brachiopod shell are unequal in size, and in
+each valve a line drawn from the beak to the base divides the
+valve into two equal parts. It may thus be told from the pelecypod
+mollusk, such as the clam, whose two valves are not far from equal
+in size, each being divided into unequal parts by a line dropped
+from the beak.
+
+Brachiopods include two orders. In the most primitive order--that
+of the INARTICULATE brachiopods--the two valves are held together
+only by muscles of the animal, and the shell is horny or is
+composed of phosphate of lime. The DISCINA, which began in the
+Algonkian, is of this type, as is also the LINGULELLA of the
+Cambrian. Both of these genera have lived on during the millions
+of years of geological time since their introduction, handing down
+from generation to generation with hardly any change to their
+descendants now living off our shores the characters impressed
+upon them at the beginning.
+
+The more highly organized ARTICULATE brachiopods have valves of
+carbonate of lime more securely joined by a hinge with teeth and
+sockets (Fig. 270). In the Cambrian the inarticulates predominate,
+though the articulates grow common toward the end of the period.
+
+MOLLUSKS. The three chief classes of mollusks--the PELECYPODS
+(represented by the oyster and clam of to-day), the GASTROPODS
+(represented now by snails, conches, and periwinkles), and the
+CEPHALOPODS (such as the nautilus, cuttlefish, and squids)--were
+all represented in the Cambrian, although very sparingly.
+
+Pteropods, a suborder of the gastropods, appeared in this age.
+Their papery shells of carbonate of lime are found in great
+numbers from this time on.
+
+Cephalopods, the most highly organized of the mollusks, started
+into existence, so far as the record shows, toward, the end of the
+Cambrian, with the long extinct ORTHOCERAS (STRAIGHTHORN) and the
+allied genera of its family. The Orthoceras had a long, straight,
+and tapering shell, divided by cross partitions into chambers. The
+animal lived in the "body chamber" at the larger end, and walled
+off the other chambers from it in succession during the growth of
+the shell. A central tube, the SIPHUNCLE, passed through from the
+body chamber to the closed tip of the cone.
+
+The seashells, both brachiopods and mollusks, are in some respects
+the most important to the geologist of all fossils. They have been
+so numerous, so widely distributed, and so well preserved because
+of their durable shells and their station in growing sediments,
+that better than any other group of organisms they can be used to
+correlate the strata of different regions and to mark by their
+slow changes the advance of geological time.
+
+CLIMATE. The life of Cambrian times in different countries
+contains no suggestion of any marked climatic zones, and as in
+later periods a warm climate probably reached to the polar
+regions.
+
+
+
+
+
+CHAPTER XVII
+
+THE ORDOVICIAN AND SILURIAN
+[Footnote: Often known as the Lower Silurian.]
+
+THE ORDOVICIAN
+
+
+In North America the Ordovician rocks lie conformably on the
+Cambrian. The two periods, therefore, were not parted by any
+deformation, either of mountain making or of continental uplift.
+The general submergence which marked the Cambrian continued into
+the succeeding period with little interruption.
+
+SUBDIVISIONS AND DISTRIBUTION OF STRATA. The Ordovician series, as
+they have been made out in New York, are given for reference in
+the following table, with the rocks of which they are chiefly
+composed:
+
+    5 Hudson . . . . . . . . shales
+    4 Utica  . . . . . . . . shales
+    3 Trenton  . . . . . . . limestones
+    2 Chazy  . . . . . . . . limestones
+    1 Calciferous  . . . . . sandy limestones
+
+These marine formations of the Ordovician outcrop about the
+Cambrian and pre-Cambrian areas, and, as borings show, extend far
+and wide over the interior of the continent beneath more recent
+strata. The Ordovician sea stretched from Appalachia across the
+Mississippi valley. It seems to have extended to California,
+although broken probably by several mountainous islands in the
+west.
+
+PHYSICAL GEOGRAPHY. The physical history of the period is recorded
+in the succession of its formations. The sandstones of the Upper
+Cambrian, as we have learned, tell of a transgressing sea which
+gradually came to occupy the Mississippi valley and the interior
+of North America. The limestones of the early and middle
+Ordovician show that now the shore had become remote and the lands
+had become more low. The waters now had cleared. Colonies of
+brachiopods and other lime-secreting animals occupied the sea
+bottom, and their debris mantled it with sheets of limy ooze. The
+sandy limestones of the Calciferous record the transition stage
+from the Cambrian when some sand was still brought in from shore.
+The highly fossiliferous limestones of the Trenton tell of clear
+water and abundant life. We need not regard this epicontinental
+sea as deep. No abysmal deposits have been found, and the
+limestones of the period are those which would be laid in clear,
+warm water of moderate depth like that of modern coral seas.
+
+The shales of the Utica and Hudson show that the waters of the sea
+now became clouded with mud washed in from land. Either the land
+was gradually uplifted, or perhaps there had arrived one of those
+periodic crises which, as we may imagine, have taken place
+whenever the crust of the shrinking earth has slowly given way
+over its great depressions, and the ocean has withdrawn its waters
+into deepening abysses. The land was thus left relatively higher
+and bordered with new coastal plains. The epicontinental sea was
+shoaled and narrowed, and muds were washed in from the adjacent
+lands.
+
+THE TACONIC DEFORMATION. The Ordovician was closed by a
+deformation whose extent and severity are not yet known. From the
+St. Lawrence River to New York Bay, along the northwestern and
+western border of New England, lies a belt of Cambrian-Ordovician
+rocks more than a mile in total thickness, which accumulated
+during the long ages of those periods in a gradually subsiding
+trough between the Adirondacks and a pre-Cambrian range lying west
+of the Connecticut River. But since their deposition these ancient
+sediments have been crumpled and crushed, broken with great
+faults, and extensively metamorphosed. The limestones have
+recrystallized into marbles, among them the famous marbles of
+Vermont; the Cambrian sandstones have become quartzites, and the
+Hudson shale has been changed to a schist exposed on Manhattan
+Island and northward.
+
+In part these changes occurred at the close of the Ordovician, for
+in several places beds of Silurian age rest unconformably on the
+upturned Ordovician strata; but recent investigations have made it
+probable that the crustal movements recurred at later times, and
+it was perhaps in the Devonian and at the close of the
+Carboniferous that the greater part of the deformation and
+metamorphism was accomplished. As a result of these movements,--
+perhaps several times repeated,--a great mountain range was
+upridged, which has been long since leveled by erosion, but whose
+roots are now visible in the Taconic Mountains of western New
+England.
+
+THE CINCINNATI ANTICLINE. Over an oval area in Ohio, Indiana, and
+Kentucky, whose longer axis extends from north to south through
+Cincinnati, the Ordovician strata rise in a very low, broad swell,
+called the Cincinnati anticline. The Silurian and Devonian strata
+thin out as they approach this area and seem never to have
+deposited upon it. We may regard it, therefore, as an island
+upwarped from the sea at the close of the Ordovician or shortly
+after.
+
+PETROLEUM AND NATURAL GAS. These valuable illuminants and fuels
+are considered here because, although they are found in traces in
+older strata, it is in the Ordovician that they occur for the
+first time in large quantities. They range throughout later
+formations down to the most recent.
+
+The oil horizons of California and Texas are Tertiary; those of
+Colorado, Cretaceous; those of West Virginia, Carboniferous; those
+of Pennsylvania, Kentucky, and Canada, Devonian; and the large
+field of Ohio and Indiana belongs to the Ordovician and higher
+systems.
+
+Petroleum and natural gas, wherever found, have probably
+originated from the decay of organic matter when buried in
+sedimentary deposits, just as at present in swampy places the
+hydrogen and carbon of decaying vegetation combine to form marsh
+gas. The light and heat of these hydrocarbons we may think of,
+therefore, as a gift to the civilized life of our race from the
+humble organisms, both animal and vegetable, of the remote past,
+whose remains were entombed in the sediments of the Ordovician and
+later geological ages.
+
+Petroleum is very widely disseminated throughout the stratified
+rocks. Certain limestones are visibly greasy with it, and others
+give off its characteristic fetid odor when struck with a hammer.
+Many shales are bituminous, and some are so highly charged that
+small flakes may be lighted like tapers, and several gallons of
+oil to the ton may be obtained by distillation.
+
+But oil and gas are found in paying quantities only when certain
+conditions meet:
+
+1. A SOURCE below, usually a bituminous shale, from whose organic
+matter they have been derived by slow change.
+
+2. A RESERVOIR above, in which they have gathered. This is either
+a porous sandstone or a porous or creviced limestone.
+
+3. Oil and gas are lighter than water, and are usually under
+pressure owing to artesian water. Hence, in order to hold them
+from escaping to the surface, the reservoir must have the shape of
+an ANTICLINE, DOME, or LENS.
+
+4. It must also have an IMPERVIOUS COVER, usually a shale. In
+these reservoirs gas is under a pressure which is often enormous,
+reaching in extreme cases as high as a thousand five hundred
+pounds to the square inch. When tapped it rushes out with a
+deafening roar, sometimes flinging the heavy drill high in air. In
+accounting for this pressure we must remember that the gas has
+been compressed within the pores of the reservoir rock by artesian
+water, and in some cases also by its own expansive force. It is
+not uncommon for artesian water to rise in wells after the
+exhaustion of gas and oil.
+
+LIFE OF THE ORDOVICIAN
+
+During the ages of the Ordovician, life made great advances. Types
+already present branched widely into new genera and species, and
+new and higher types appeared.
+
+Sponges continued from the Cambrian. Graptolites now reached their
+climax.
+
+STROMATOPORA--colonies of minute hydrozoans allied to corals--grew
+in places on the sea floor, secreting stony masses composed of
+thin, close, concentric layers, connected by vertical rods. The
+Stromatopora are among the chief limestone builders of the
+Silurian and Devonian periods.
+
+CORALS developed along several distinct lines, like modern corals
+they secreted a calcareous framework, in whose outer portions the
+polyps lived. In the Ordovician, corals were represented chiefly
+by the family of the CHOETETES, all species of which are long
+since extinct. The description of other types of corals will be
+given under the Silurian, where they first became abundant.
+
+ECHINODERMS. The cystoid reaches its climax, but there appear now
+two higher types of echinoderms,--the crinoid and the starfish.
+The CRINOID, named from its resemblance to the lily, is like the
+cystoid in many respects, but has a longer stem and supports a
+crown of plumose arms. Stirring the water with these arms, it
+creates currents by which particles of food are wafted to its
+mouth. Crinoids are rare at the present time, but they grew in the
+greatest profusion in the warm Ordovician seas and for long ages
+thereafter. In many places the sea floor was beautiful with these
+graceful, flowerlike forms, as with fields of long-stemmed lilies.
+Of the higher, free-moving classes of the echinoderms, starfish
+are more numerous than in the Cambrian, and sea urchins make their
+appearance in rare archaic forms.
+
+CRUSTACEANS. Trilobites now reach their greatest development and
+more than eleven hundred species have been described from the
+rocks of this period. It is interesting to note that in many
+species the segments of the thorax have now come to be so shaped
+that they move freely on one another. Unlike their Cambrian
+ancestors, many of the Ordovician trilobites could roll themselves
+into balls at the approach of danger. It is in this attitude,
+taken at the approach of death, that trilobites are often found in
+the Ordovician and later rocks. The gigantic crustaceans called
+the EURYPTERIDS were also present in this period.
+
+The arthropods had now seized upon the land. Centipedes and
+insects of a low type, the earliest known land animals, have been
+discovered in strata of this system.
+
+BRYOZOANS. No fossils are more common in the limestones of the
+time than the small branching stems and lacelike mats of the
+bryozoans,--the skeletons of colonies of a minute animal allied in
+structure to the brachiopod.
+
+BRACHIOPODS. These multiplied greatly, and in places their shells
+formed thick beds of coquina. They still greatly surpassed the
+mollusks in numbers.
+
+CEPHALOPODS. Among the mollusks we must note the evolution of the
+cephalopods. The primitive straight Orthoceras has now become
+abundant. But in addition to this ancestral type there appears a
+succession of forms more and more curved and closely coiled, as
+illustrated in Figure 285. The nautilus, which began its course in
+this period, crawls on the bottom of our present seas.
+
+VERTEBRATES. The most important record of the Ordovician is that
+of the appearance of a new and higher type, with possibilities of
+development lying hidden in its structure that the mollusk and the
+insect could never hope to reach. Scales and plates of minute
+fishes found in the Ordovician rocks near Canon City, Colorado,
+show that the humblest of the vertebrates had already made its
+appearance. But it is probable that vertebrates had been on the
+earth for ages before this in lowly types, which, being destitute
+of hard parts, would leave no record.
+
+THE SILURIAN
+
+The narrowing of the seas and the emergence of the lands which
+characterized the closing epoch of the Ordovician in eastern North
+America continue into the succeeding period of the Silurian. New
+species appear and many old species now become extinct.
+
+THE APPALACHIAN REGION. Where the Silurian system is most fully
+developed, from New York southward along the Appalachian
+Mountains, it comprises four series:
+
+    4 Salina  . . . shales, impure limestones, gypsum, salt
+    3 Niagara . . . chiefly limestones
+    2 Clinton . . . sandstones, shales, with some limestones
+    1 Medina  . . . conglomerates, sandstones
+
+The rocks of these series are shallow-water deposits and reach the
+total thickness of some five thousand feet. Evidently they were
+laid over an area which was on the whole gradually subsiding,
+although with various gentle oscillations which are recorded in
+the different formations. The coarse sands of the heavy Medina
+formations record a period of uplift of the oldland of Appalachia,
+when erosion went on rapidly and coarse waste in abundance was
+brought down from the hills by swift streams and spread by the
+waves in wide, sandy flats. As the lands were worn lower the waste
+became finer, and during an epoch of transition--the Clinton--
+there were deposited various formations of sandstones, shales, and
+limestones. The Niagara limestones testify to a long epoch of
+repose, when low-lying lands sent little waste down to the sea.
+
+The gypsum and salt deposits of the Salina show that toward the
+close of the Silurian period a slight oscillation brought the sea
+floor nearer to the surface, and at the north cut off extensive
+tracts from the interior sea. In these wide lagoons, which now and
+then regained access to the open sea and obtained new supplies of
+salt water, beds of salt and gypsum were deposited as the briny
+waters became concentrated by evaporation under a desert climate.
+Along with these beds there were also laid shales and impure
+limestones.
+
+In New York the "salt pans" of the Salina extended over an area
+one hundred and fifty miles long from east to west and sixty miles
+wide, and similar salt marshes occurred as far west as Cleveland,
+Ohio, and Goderich on Lake Huron. At Ithaca, New York, the series
+is fifteen hundred feet thick, and is buried beneath an equal
+thickness of later strata. It includes two hundred and fifty feet
+of solid salt, in several distinct beds, each sealed within the
+shales of the series.
+
+Would you expect to find ancient beds of rock salt inclosed in
+beds of pervious sandstone?
+
+The salt beds of the Salina are of great value. They are reached
+by well borings, and their brines are evaporated by solar heat and
+by boiling. The rock salt is also mined from deep shafts.
+
+Similar deposits of salt, formed under like conditions, occur in
+the rocks of later systems down to the present. The salt beds of
+Texas are Permian, those of Kansas are Permian, and those of
+Louisiana are Tertiary.
+
+THE MISSISSIPPI VALLEY. The heavy near-shore formations of the
+Silurian in the Appalachian region thin out toward the west. The
+Medina and the Clinton sandstones are not found west of Ohio,
+where the first passes into a shale and the second into a
+limestone. The Niagara limestone, however, spreads from the Hudson
+River to beyond the Mississippi, a distance of more than a
+thousand miles. During the Silurian period the Mississippi valley
+region was covered with a quiet, shallow, limestone-making sea,
+which received little waste from the low lands which bordered it.
+
+The probable distribution of land and sea in eastern North America
+and western Europe is shown in Figure 287. The fauna of the
+interior region and of eastern Canada are closely allied with that
+of western Europe, and several species are identical. We can
+hardly account for this except by a shallow-water connection
+between the two ancient epicontinental seas. It was perhaps along
+the coastal shelves of a northern land connecting America and
+Europe by way of Greenland and Iceland that the migration took
+place, so that the same species came to live in Iowa and in
+Sweden.
+
+THE WESTERN UNITED STATES. So little is found of the rocks of the
+system west of the Missouri River that it is quite probable that
+the western part of the United States had for the most part
+emerged from the sea at the close of the Ordovician and remained
+land during the Silurian. At the same time the western land was
+perhaps connected with the eastern land of Appalachia across
+Arkansas and Mississippi; for toward the south the Silurian
+sediments indicate an approach to shore.
+
+LIFE OF THE SILURIAN
+
+In this brief sketch it is quite impossible to relate the many
+changes of species and genera during the Silurian.
+
+CORALS. Some of the more common types are familiarly known as cup
+corals, honeycomb corals, and chain corals. In the CUP CORALS the
+most important feature is the development of radiating vertical
+partitions, or SEPTA, in the cell of the polyp. Some of the cup
+corals grew in hemispherical colonies (Fig. 288), while many were
+separate individuals (Fig. 289), building a single conical, or
+horn-shaped cell, which sometimes reached the extreme size of a
+foot in length and two or three inches in diameter.
+
+HONEYCOMB CORALS consist of masses of small, close-set prismatic
+cells, each crossed by horizontal partitions, or TABULAE, while
+the septa are rudimentary, being represented by faintly projecting
+ridges or rows of spines.
+
+CHAIN CORALS are also marked by tabulae. Their cells form
+elliptical tubes, touching each other at the edges, and appearing
+in cross section like the links of a chain. They became extinct at
+the end of the Silurian.
+
+The corals of the SYRINGOPORA family are similar in structure to
+chain corals, but the tubular columns are connected only in
+places.
+
+To the echinoderms there is now added the BLASTOID (bud-shaped).
+The blastoid is stemmed and armless, and its globular "head" or
+"calyx," with its five petal-like divisions, resembles a flower
+bud. The blastoids became more abundant in the Devonian,
+culminated in the Carboniferous, and disappeared at the end of the
+Paleozoic.
+
+The great eurypterids--some of which were five or six feet in
+length--and the cephalopods were still masters of the seas. Fishes
+were as yet few and small; trilobites and graptolites had now
+passed their prime and had diminished greatly in numbers.
+Scorpions are found in this period both in Europe and in America.
+The limestone-making seas of the Silurian swarmed with corals,
+crinoids, and brachiopods.
+
+With the end of the Silurian period the AGE OF INVERTEBRATES comes
+to a close, giving place to the Devonian, the AGE OF FISHES.
+
+
+
+
+
+CHAPTER XVIII
+
+THE DEVONIAN
+
+
+In America the Silurian is not separated from the Devonian by any
+mountain-making deformation or continental uplift. The one period
+passed quietly into the other. Their conformable systems are so
+closely related, and the change in their faunas is so gradual,
+that geologists are not agreed as to the precise horizon which
+divides them.
+
+SUBDIVISIONS AND PHYSICAL GEOGRAPHY. The Devonian is represented
+in New York and southward by the following five series. We add the
+rocks of which they are chiefly composed.
+
+    5 Chemung     . . . . . . sandstones and sandy shales
+    4 Hamilton    . . . . . . shales and sandstones
+    3 Corniferous . . . . . . limestones
+    2 Oriskany    . . . . . . sandstones
+    1 Helderberg  . . . . . . limestones
+
+The Helderberg is a transition epoch referred by some geologists
+to the Silurian. The thin sandstones of the Oriskany mark an epoch
+when waves worked over the deposits of former coastal plains. The
+limestones of the Corniferous testify to a warm and clear wide sea
+which extended from the Hudson to beyond the Mississippi. Corals
+throve luxuriantly, and their remains, with those of mollusks and
+other lime-secreting animals, built up great beds of limestone.
+The bordering continents, as during the later Silurian, must now
+have been monotonous lowlands which sent down little of even the
+finest waste to the sea.
+
+In the Hamilton the clear seas of the previous epoch became
+clouded with mud. The immense deposits of coarse sandstones and
+sandy shales of the Chemung, which are found off what was at the
+time the west coast of Appalachia, prove an uplift of that ancient
+continent.
+
+The Chemung series extends from the Catskill Mountains to
+northeastern Ohio and south to northeastern Tennessee, covering an
+area of not less than a hundred thousand square miles. In eastern
+New York it attains three thousand feet in thickness; in
+Pennsylvania it reaches the enormous thickness of two miles; but
+it rapidly thins to the west. Everywhere the Chemung is made of
+thin beds of rapidly alternating coarse and fine sands and clays,
+with an occasional pebble layer, and hence is a shallow-water
+deposit. The fine material has not been thoroughly winnowed from
+the coarse by the long action of strong waves and tides. The sands
+and clays have undergone little more sorting than is done by
+rivers. We must regard the Chemung sandstones as deposits made at
+the mouths of swift, turbid rivers in such great amount that they
+could be little sorted and distributed by waves.
+
+Over considerable areas the Chemung sandstones bear little or no
+trace of the action of the sea. The Catskill Mountains, for
+example, have as their summit layers some three thousand feet of
+coarse red sandstones of this series, whose structure is that of
+river deposits, and whose few fossils are chiefly of fresh-water
+types. The Chemung is therefore composed of delta deposits, more
+or less worked over by the sea. The bulk of the Chemung equals
+that of the Sierra Nevada Mountains. To furnish this immense
+volume of sediment a great mountain range, or highland, must have
+been upheaved where the Appalachian lowland long had been. To what
+height the Devonian mountains of Appalachia attained cannot be
+told from the volume of the sediments wasted from them, for they
+may have risen but little faster than they were worn down by
+denudation. We may infer from the character of the waste which
+they furnished to the Chemung shores that they did not reach an
+Alpine height. The grains of the Chemung sandstones are not those
+which would result from mechanical disintegration, as by frost on
+high mountain peaks, but are rather those which would be left from
+the long chemical decay of siliceous crystalline rocks; for the
+more soluble minerals are largely wanting. The red color of much
+of the deposits points to the same conclusion. Red residual clays
+accumulated on the mountain sides and upland summits, and were
+washed as ocherous silt to mingle with the delta sands. The iron-
+bearing igneous rocks of the oldland also contributed by their
+decay iron in solution to the rivers, to be deposited in films of
+iron oxide about the quartz grains of the Chemung sandstones,
+giving them their reddish tints.
+
+LIFE OF THE DEVONIAN
+
+PLANTS. The lands were probably clad with verdure during Silurian
+times, if not still earlier; for some rare remains of ferns and
+other lowly types of vegetation have been found in the strata of
+that system. But it is in the Devonian that we discover for the
+first time the remains of extensive and luxuriant forests. This
+rich flora reached its climax in the Carboniferous, and it will be
+more convenient to describe its varied types in the next chapter.
+
+RHIZOCARPS. In the shales of the Devonian are found microscopic
+spores of rhizocarps in such countless numbers that their weight
+must be reckoned in hundreds of millions of tons. It would seem
+that these aquatic plants culminated in this period, and in widely
+distant portions of the earth swampy flats and shallow lagoons
+were filled with vegetation of this humble type, either growing
+from the bottom or floating free upon the surface. It is to the
+resinous spores of the rhizocarps that the petroleum and natural
+gas from Devonian rocks are largely due. The decomposition of the
+spores has made the shales highly bituminous, and the oil and gas
+have accumulated in the reservoirs of overlying porous sandstones.
+
+INVERTEBRATES. We must pass over the ever-changing groups of the
+invertebrates with the briefest notice. Chain corals became
+extinct at the close of the Silurian, but other corals were
+extremely common in the Devonian seas. At many places corals
+formed thin reefs, as at Louisville, Kentucky, where the hardness
+of the reef rock is one of the causes of the Falls of the Ohio.
+
+Sponges, echinoderms, brachiopods, and mollusks were abundant. The
+cephalopods take a new departure. So far in all their various
+forms, whether straight, as the Orthoceras, or curved, or close-
+coiled as in the nautilus, the septum, or partition dividing the
+chambers, met the inner shell along a simple line, like that of
+the rim of a saucer. There now begins a growth of the septum by
+which its edges become sharply corrugated, and the suture, or line
+of juncture of the septum and the shell, is thus angled. The group
+in which this growth of the septum takes place is called the
+GONIATITE (Greek GONIA, angle).
+
+VERTEBRATES. It is with the greatest interest that we turn now to
+study the backboned animals of the Devonian; for they are believed
+to be the ancestors of the hosts of vertebrates which have since
+dominated the earth. Their rudimentary structures foreshadowed
+what their descendants were to be, and give some clue to the
+earliest vertebrates from which they sprang. Like those whose
+remains are found in the lower Paleozoic systems, all of these
+Devonian vertebrates were aquatic and go under the general
+designation of fishes.
+
+The lowest in grade and nearest, perhaps, to the ancestral type of
+vertebrates, was the problematic creature, an inch or so long, of
+Figure 297. Note the circular mouth not supplied with jaws, the
+lack of paired fins, and the symmetric tail fin, with the column
+of cartilaginous, ringlike vertebrae running through it to the
+end. The animal is probably to be placed with the jawless lampreys
+and hags,--a group too low to be included among true fishes.
+
+OSTRACODERMS. This archaic group, long since extinct, is also too
+lowly to rank among the true fishes, for its members have neither
+jaws nor paired fins. These small, fishlike forms were cased in
+front with bony plates developed in the skin and covered in the
+rear with scales. The vertebrae were not ossified, for no trace of
+them has been found.
+
+DEVONIAN FISHES. The TRUE FISHES of the Devonian can best be
+understood by reference to their descendants now living. Modern
+fishes are divided into several groups: SHARKS and their allies;
+DIPNOANS; GANOIDS, such as the sturgeon and gar; and TELEOSTS,--
+most common fishes, such as the perch and cod.
+
+SHARKS. Of all groups of living fishes the sharks are the oldest
+and still retain most fully the embryonic characters of their
+Paleozoic ancestors. Such characters are the cartilaginous
+skeleton, and the separate gill slits with which the throat wall
+is pierced and which are arranged in line like the gill openings
+of the lamprey. The sharks of the Silurian and Devonian are known
+to us chiefly by their teeth and fin spines, for they were
+unprotected by scales or plates, and were devoid of a bony
+skeleton. Figure 299 is a restoration of an archaic shark from a
+somewhat higher horizon. Note the seven gill slits and the
+lappetlike paired fins. These fins seem to be remnants of the
+continuous fold of skin which, as embryology teaches, passed from
+fore to aft down each side of the primitive vertebrate.
+
+Devonian sharks were comparatively small. They had not evolved
+into the ferocious monsters which were later to be masters of the
+seas.
+
+DIPNOANS, OR LUNG FISHES. These are represented to-day by a
+few peculiar fishes and are distinguished by some high structures
+which ally them with amphibians. An air sac with cellular spaces
+is connected with the gullet and serves as a rudimentary lung. It
+corresponds with the swim bladder of most modern fishes, and
+appears to have had a common origin with it. We may conceive that
+the primordial fishes not only had gills used in breathing air
+dissolved in water, but also developed a saclike pouch off the
+gullet. This sac evolved along two distinct lines. On the line of
+the ancestry of most modern fishes its duct was closed and it
+became the swim bladder used in flotation and balancing. On
+another line of descent it was left open, air was swallowed into
+it, and it developed into the rudimentary lung of the dipnoans and
+into the more perfect lungs of the amphibians and other air-
+breathing vertebrates.
+
+One of the ancient dipnoans is illustrated in Figure 300. Some of
+the members of this order were, like the ostracoderms, cased in
+armor, but their higher rank is shown by their powerful jaws and
+by other structures. Some of these armored fishes reached twenty-
+five feet in length and six feet across the head. They were the
+tyrants of the Devonian seas.
+
+GANOIDS. These take their name from their enameled plates or
+scales of bone. The few genera now surviving are the descendants
+of the tribes which swarmed in the Devonian seas. A restoration of
+one of a leading order, the FRINGE-FINNED ganoids, is given in
+Figure 301. The side fins, which correspond to the limbs of the
+higher vertebrates, are quite unlike those of most modern fishes.
+Their rays, instead of radiating from a common base, fringe a
+central lobe which contains a cartilaginous axis. The teeth of the
+Devonian ganoids show a complicated folded structure.
+
+GENERAL CHARACTERISTICS OF DEVONIAN FISHES. THE NOTOCHORD IS
+PERSISTENT. The notochord is a continuous rod of cartilage, or
+gristle, which in the embryological growth of vertebrate animals
+supports the spinal nerve cord before the formation of the
+vertebrae. In most modern fishes and in all higher vertebrates the
+notochord is gradually removed as the bodies of the vertebrae are
+formed about it; but in the Devonian fishes it persists through
+maturity and the vertebrae remain incomplete.
+
+THE SKELETON IS CARTILAGINOUS. This also is an embryological
+characteristic. In the Devonian fishes the vertebrae, as well as
+the other parts of the skeleton, have not ossified, or changed to
+bone, but remain in their primitive cartilaginous condition.
+
+THE TAIL FIN IS VERTEBRATED. The backbone runs through the fin and
+is fringed above and below with its vertical rays. In some fishes
+with vertebrated tail fins the fin is symmetric, and this seems to
+be the primitive type. In others the tail fin is unsymmetric: the
+backbone runs into the upper lobe, leaving the two lobes of
+unequal size. In most modern fishes (the teleosts) the tail fin is
+not vertebrated: the spinal column ends in a broad plate, to which
+the diverging fin rays are attached.
+
+But along with these embryonic characters, which were common to
+all Devonian fishes, there were other structures in certain groups
+which foreshadowed the higher structures of the land vertebrates
+which were yet to come: air sacs which were to develop into lungs,
+and cartilaginous axes in the side fins which were a prophecy of
+limbs. The vertebrates had already advanced far enough to prove
+the superiority of their type of structure to all others. Their
+internal skeleton afforded the best attachment for muscles and
+enabled them to become the largest and most powerful creatures of
+the time. The central nervous system, with the predominance given
+to the ganglia at the fore end of the nerve cord,--the brain,--
+already endowed them with greater energy than the invertebrates;
+and, still more important, these structures contained the
+possibility of development into the more highly organized land
+vertebrates which were to rule the earth.
+
+TELEOSTS. The great group of fishes called the teleosts, or those
+with complete bony skeletons, to which most modern fishes belong,
+may be mentioned here, although in the Devonian they had not yet
+appeared. The teleosts are a highly specialized type, adapted most
+perfectly to their aquatic environment. Heavy armor has been
+discarded, and reliance is placed instead on swiftness. The
+skeleton is completely ossified and the notochord removed. The
+vertebrae have been economically withdrawn from the tail, and the
+cartilaginous axis of the side fins has been fotfoid unnecessary.
+The air sac has become a swim bladder. In this complete
+specialization they have long since lost the possibility of
+evolving into higher types.
+
+It is interesting to note that the modern teleosts in their
+embryological growth pass through the stages which characterized
+the maturity of their Devonian ancestors; their skeleton is
+cartilaginous and their tail fin vertebrated.
+
+
+
+
+
+CHAPTER XIX
+
+THE CARBONIFEROUS
+
+
+The Carboniferous system is so named from the large amount of
+coal which it contains. Other systems, from the Devonian on, are
+coal bearing also, but none so richly and to so wide an extent.
+Never before or since have the peculiar conditions been so
+favorable for the formation of extensive coal deposits.
+
+With few exceptions the Carboniferous strata rest on those of the
+Devonian without any marked unconformity; the one period passed
+quietly into the other, with no great physical disturbances.
+
+The Carboniferous includes three distinct series. The lower is
+called the MISSISSIPPIAN, from the outcrop of its formations along
+the Mississippi River in central and southern Illinois and the
+adjacent portions of Iowa and Missouri. The middle series is
+called the PENNSYLVANIAN (or Coal Measures), from its wide
+occurrence over Pennsylvania. The upper series is named the
+PERMIAN, from the province of Perm in Russia.
+
+THE MISSISSIPPIAN SERIES. In the interior the Mississippian is
+composed chiefly of limestones, with some shales, which tell of a
+clear, warm, epicontinental sea swarming with crinoids, corals,
+and shells, and occasionally clouded with silt from the land.
+
+In the eastern region, New York had been added by uplift to the
+Appalachian land which now was united to the northern area. From
+eastern Pennsylvania southward there were laid in a subsiding
+trough, first, thick sandstones (the Pocono sandstone), and later
+still heavier shales,--the two together reaching the thickness of
+four thousand feet and more. We infer a renewed uplift of
+Appalachia similar to that of the later epochs of the Devonian,
+but as much less in amount as the volume of sediments is smaller.
+
+THE PENNSYLVANIAN SERIES
+
+The Mississippian was brought to an end by a quiet oscillation
+which lifted large areas slightly above the sea, and the
+Pennsylvanian began with a movement in the opposite direction. The
+sea encroached on the new land, and spread far and wide a great
+basal conglomerate and coarse sandstones. On this ancient beach
+deposit a group of strata rests which we must now interpret. They
+consist of alternating shales and sandstones, with here and there
+a bed of limestone and an occasional seam of coal. A stratum of
+fire clay commonly underlies a coal seam, and there occur also
+beds of iron ore. We give a typical section of a very small
+portion of the series at a locality in Pennyslvania. Although some
+of the minor changes are omitted, the section shows the rapid
+alternation of the strata:
+
+                                          Feet
+    9 Sandstone and shale . . . . . . . . 25
+    8 Limestone . . . . . . . . . . . . . 18
+    7 Sandstone . . . . . . . . . . . . . 10
+    6 Coal  . . . . . . . . . . . . . . .  1-6
+    5 Shale . . . . . . . . . . . . . . .  0-2
+    4 Sandstone . . . . . . . . . . . . . 40
+    3 Limestone . . . . . . . . . . . . . 10
+    2 Coal  . . . . . . . . . . . . . . .  5-12
+    1 Fire clay . . . . . . . . . . . . .  3
+
+This section shows more coal than is usual; on the whole, coal
+seams do not take up more than one foot in fifty of the Coal
+Measures. They vary also in thickness more than is seen in the
+section, some exceptional seams reaching the thickness of fifty
+feet.
+
+HOW COAL WAS MADE.
+
+1. Coal is of vegetable origin. Examined under the microscope even
+anthracite, or hard coal, is seen to contain carbonized vegetal
+tissues. There are also all gradations connecting the hardest
+anthracite--through semibituminous coal, bituminous or soft coal,
+lignite (an imperfect coal in which sometimes woody fibers may be
+seen little changed)--with peat and decaying vegetable tissues.
+Coal is compressed and mineralized vegetal matter. Its varieties
+depend on the perfection to which the peculiar change called
+bituminization has been carried, and also, as shown in the table
+below, on the degree to which the volatile substances and water
+have escaped, and on the per cent of carbon remaining.
+
+                       Peat      Lignite   Bituminous Coal
+Anthracite
+                   Dismal Swamp   Texas         Penn.
+Penn.
+    Moisture  . . . . 78.89       14.67          1.30           2.74
+    Volatile matter . 13.84       37.32         20.87           4.25
+    Fixed carbon  . .  6.49       41.07         67.20          81.51
+    Ash . . . . . . .  0.78        6.69          8.80          10.87
+
+2. The vegetable remains associated with coal are those of land
+plants.
+
+3. Coal accumulated in the presence of water; for it is only when
+thus protected from the air that vegetal matter is preserved.
+
+4. The vegetation of coal accumulated for the most part where it
+grew; it was not generally drifted and deposited by waves and
+currents. Commonly the fire clay beneath the seam is penetrated
+with roots, and the shale above is packed with leaves of ferns and
+other plants as beautifully pressed as in a herbarium. There often
+is associated with the seam a fossil forest, with the stumps,
+which are still standing where they grew, their spreading roots,
+and the soil beneath, all changed to stone. In the Nova Scotia
+field, out of seventy-six distinct coal seams, twenty are
+underlain by old forest grounds.
+
+The presence of fire clay beneath a seam points in the same
+direction. Such underclays withstand intense heat and are used in
+making fire brick, because their alkalies have been removed by the
+long-continued growth of vegetation.
+
+Fuel coal is also too pure to have been accumulated by driftage.
+In that case we should expect to find it mixed with mud, while in
+fact it often contains no more ash than the vegetal matter would
+furnish from which it has been compressed.
+
+These conditions are fairly met in the great swamps of river
+plains and deltas and of coastal plains, such as the great Dismal
+Swamp, where thousands of generations of forests with their
+undergrowths contribute their stems and leaves to form thick beds
+of peat. A coal seam is a fossil peat bed.
+
+GEOGRAPHICAL CONDITIONS DURING THE PENNSYLVANIAN. The
+Carboniferous peat swamps were of vast extent. A map of the Coal
+Measures (Fig. 260) shows that the coal marshes stretched, with
+various interruptions of higher ground and straits of open water,
+from eastern Pennsylvania into Alabama, Texas, and Kansas. Some
+individual coal beds may still be traced over a thousand square
+miles, despite the erosion which they have suffered. It taxes the
+imagination to conceive that the varied region included within
+these limits was for hundreds of thousands of years a marshy plain
+covered with tropical jungles such as that pictured in Figure 304.
+
+On the basis that peat loses four fifths of its bulk in changing
+to coal, we may reckon the thickness of these ancient peat beds.
+Coal seams six and ten feet thick, which are not uncommon,
+represent peat beds thirty and fifty feet in thickness, while
+mammoth coal seams fifty feet thick have been compressed from peat
+beds two hundred and fifty feet deep.
+
+At the same time, the thousands of feet of marine and freshwater
+sediments, with their repeated alternations of limestones,
+sandstones, and shales, in which the seams of coal occur, prove a
+slow subsidence, with many changes in its rate, with halts when
+the land was at a stillstand, and with occasional movements
+upward.
+
+When subsidence was most rapid and long continued the sea
+encroached far and wide upon the lowlands and covered the coal
+swamps with sands and muds and limy oozes. When subsidence
+slackened or ceased the land gained on the sea. Bays were barred,
+and lagoons as they gradually filled with mud became marshes.
+River deltas pushed forward, burying with their silts the sunken
+peat beds of earlier centuries, and at the surface emerged in
+broad, swampy flats,--like those of the deltas of the Mississippi
+and the Ganges,--which soon were covered with luxuriant forests.
+At times a gentle uplift brought to sea level great coastal
+plains, which for ages remained mantled with the jungle, their
+undeveloped drainage clogged with its debris, and were then again
+submerged.
+
+PHYSICAL GEOGRAPHY OF THE SEVERAL REGIONS. THE ACADIAN REGION lay
+on the eastern side of the northern land, where now are New
+Brunswick and Nova Scotia, and was an immense river delta. Here
+river deposits rich in coal accumulated to a depth of sixteen
+thousand feet. The area of this coal field is estimated at about
+thirty-six thousand square miles.
+
+THE APPALACHIAN REGION skirts the Appalachian oldland on the west
+from the southern boundary of New York to northern Alabama,
+extending west into eastern Ohio. The Cincinnati anticline was now
+a peninsula, and the broad gulf which had lain between it and
+Appalachia was transformed at the beginning of the Pennsylvanian
+into wide marshy plains, now sinking beneath the sea and now
+emerging from it. This area subsided during the Carboniferous
+period to a depth of nearly ten thousand feet.
+
+THE CENTRAL REGION lay west of the peninsula of the Cincinnati
+anticline, and extended from Indiana west into eastern Nebraska,
+and from central Iowa and Illinois southward about the ancient
+island in Missouri and Arkansas into Oklahoma and Texas. On the
+north the subsidence in this area was comparatively slight, for
+the Carboniferous strata scarcely exceed two thousand feet in
+thickness. But in Arkansas and Indian Territory the downward
+movement amounted to four and five miles, as is proved by shoal
+water deposits of that immense thickness.
+
+The coal fields of Indiana, and Illinois are now separated by
+erosion from those lying west of the Mississippi River. At the
+south the Appalachian land seems still to have stretched away to
+the west across Louisiana and Mississippi into Texas, and this
+westward extension formed the southern boundary of the coal
+marshes of the continent.
+
+The three regions just mentioned include the chief Carboniferous
+coal fields of North America. Including a field in central
+Michigan evidently formed in an inclosed basin (Fig. 260), and one
+in Rhode Island, the total area of American coal fields has been
+reckoned at not less than two hundred thousand square miles. We
+can hardly estimate the value of these great stores of fossil fuel
+to an industrial civilization. The forests of the coal swamps
+accumulated in their woody tissues the energy which they received
+from the sun in light and heat, and it is this solar energy long
+stored in coal seams which now forms the world's chief source of
+power in manufacturing.
+
+THE WESTERN AREA. On the Great Plains beyond the Missouri River
+the Carboniferous strata pass under those of more recent systems.
+Where they reappear, as about dissected mountain axes or on
+stripped plateaus, they consist wholly of marine deposits and are
+devoid of coal. The rich coal fields of the West are of later
+date.
+
+On the whole the Carboniferous seems to have been a time of
+subsidence in the West. Throughout the period a sea covered the
+Great Basin and the plateaus of the Colorado River. At the time of
+the greatest depression the sites of the central chains of the
+Rockies were probably islands, but early in the period they may
+have been connected with the broad lands to the south and east.
+Thousands of feet of Carboniferous sediments were deposited where
+the Sierra Nevada Mountains now stand.
+
+THE PERMIAN. As the Carboniferous period drew toward its close the
+sea gradually withdrew from the eastern part of the continent.
+Where the sea lingered in the deepest troughs, and where inclosed
+basins were cut off from it, the strata of the Permian were
+deposited. Such are found in New Brunswick, in Pennsylvania and
+West Virginia, in Texas, and in Kansas. In southwestern Kansas
+extensive Permian beds of rock salt and gypsum show that here lay
+great salt lakes in which these minerals were precipitated as
+their brines grew dense and dried away.
+
+In the southern hemisphere the Permian deposits are so
+extraordinary that they deserve a brief notice, although we have
+so far omitted mention of the great events which characterized the
+evolution of other continents than our own. The Permian fauna-
+flora of Australia, India, South Africa, and the southern part of
+South America are so similar that the inference is a reasonable
+one that these widely separated regions were then connected
+together, probably as extensions of a great antarctic continent.
+
+Interbedded with the Permian strata of the first three countries
+named are extensive and thick deposits of a peculiar nature which
+are clearly ancient ground moraines. Clays and sand, now hardened
+to firm rock, are inset with unsorted stones of all sizes, which
+often are faceted and scratched. Moreover, these bowlder clays
+rest on rock pavements which are polished and scored with glacial
+markings. Hence toward the close of the Paleozoic the southern
+lands of the eastern hemisphere were invaded by great glaciers or
+perhaps by ice sheets like that which now shrouds Greenland.
+
+These Permian ground moraines are not the first traces of the work
+of glaciers met with in the geological record. Similar deposits
+prove glaciation in Norway succeeding the pre-Cambrian stage of
+elevation, and Cambrian glacial drift has recently been found in
+China.
+
+THE APPALACHIAN DEFORMATION. We have seen that during Paleozoic
+times a long, narrow trough of the sea lay off the western coast
+of the ancient land of Appalachia, where now are the Appalachian
+Mountains. During the long ages of this era the trough gradually
+subsided, although with many stillstands and with occasional
+slight oscillations upward. Meanwhile the land lying to the east
+was gradually uplifted at varying rates and with long pauses. The
+waste of the rising land was constantly transferred to the sinking
+marginal sea bottom, and on the whole the trough was filled with
+sediments as rapidly as it subsided. The sea was thus kept
+shallow, and at times, especially toward the close of the era,
+much of the area was upbuilt or raised to low, marshy, coastal
+plains. When the Carboniferous was ended the waste which had been
+removed from the land and laid along its margin in the successive
+formations of the Paleozoic had reached a thickness of between
+thirty and forty thousand feet.
+
+Both by sedimentation and by subsidence the trough had now become
+a belt of weakness in the crust of the earth. Here the crust was
+now made of layers to the depth of six or seven miles. In
+comparison with the massive crystalline rocks of Appalachia on the
+east, the layered rock of the trough was weak to resist lateral
+pressure, as a ream of sheets of paper is weak when compared with
+a solid board of the same thickness. It was weaker also than the
+region to the west, since there the sediments were much thinner.
+Besides, by the long-continued depression the strata of the trough
+had been bent from the flat-lying attitude in which they were laid
+to one in which they were less able to resist a horizontal thrust.
+
+There now occurred one of the critical stages in the history of
+the planet, when the crust crumples under its own weight and
+shrinks down upon a nucleus which is diminishing in volume and no
+longer able to support it. Under slow but resistless pressure the
+strata of the Appalachian trough were thrust against the rigid
+land, and slowly, steadily bent into long folds whose axes ran
+northeast-southwest parallel to the ancient coast line. It was on
+the eastern side next the buttress of the land that the
+deformation was the greatest, and the folds most steep and close.
+In central Pennsylvania and West Virginia the folds were for the
+most part open. South of these states the folds were more closely
+appressed, the strata were much broken, and the great thrust
+faults were formed which have been described already. In eastern
+Pennsylvania seams of bituminous coal were altered to anthracite,
+while outside the region of strong deformation, as in western
+Pennyslvania, they remained unchanged. An important factor in the
+deformation was the massive limestones of the Cambrian-Ordovician.
+Because of these thick, resistant beds the rocks were bent into
+wide folds and sheared in places with great thrust faults. Had the
+strata been weak shales, an equal pressure would have crushed and
+mashed them.
+
+Although the great earth folds were slowly raised, and no doubt
+eroded in their rising, they formed in all probability a range of
+lofty mountains, with a width of from fifty to a hundred and
+twenty-five miles, which stretched from New York to central
+Alabama.
+
+From their bases lowlands extended westward to beyond the Missouri
+River. At the same time ranges were upridged out of thick
+Paleozoic sediments both in the Bay of Fundy region and in the
+Indian Territory. The eastern portion of the North American
+continent was now well-nigh complete.
+
+The date of the Appalachian deformation is told in the usual way.
+The Carboniferous strata, nearly two miles thick, are all infolded
+in the Appalachian ridges, while the next deposits found in this
+region--those of the later portion of the first period (the Trias)
+of the succeeding era--rest unconformably on the worn edges of the
+Appalachian folded strata. The deformation therefore took place
+about the close of the Paleozoic. It seems to have begun in the
+Permian, in, eastern Pennsylvania,--for here the Permian strata
+are wanting,--and to have continued into the Trias, whose earlier
+formations are absent over all the area.
+
+With this wide uplift the subsidence of the sea floor which had so
+long been general in eastern North America came to an end.
+Deposition now gave place to erosion. The sedimentary record of
+the Paleozoic was closed, and after an unknown lapse of time, here
+unrecorded, the annals of the succeeding era were written under
+changed conditions.
+
+In western North America the closing stages of the Paleozoic were
+marked by important oscillations. The Great Basin, which had long
+been a mediterranean sea, was converted into land over western
+Utah and eastern Nevada, while the waves of the Pacific rolled
+across California and western Nevada.
+
+The absence of tuffs and lavas among the Carboniferous strata of
+North America shows that here volcanic action was singularly
+wanting during the entire period. Even the Appalachian deformation
+was not accompanied by any volcanic outbursts.
+
+LIFE OF THE CARBONIFEROUS
+
+PLANTS. The gloomy forests and dense undergrowths of the
+Carboniferous jungles would appear unfamiliar to us could we see
+them as they grew, and even a botanist would find many of their
+forms perplexing and hard to classify. None of our modern trees
+would meet the eye. Plants with conspicuous flowers of fragrance
+and beauty were yet to come. Even mosses and grasses were still
+absent.
+
+Tree ferns lifted their crowns of feathery fronds high in air on
+trunks of woody tissue; and lowly herbaceous ferns, some belonging
+to existing families, carpeted the ground. Many of the fernlike
+forms, however, have distinct affinities with the cycads, of which
+they may be the ancestors, and some bear seeds and must be classed
+as gymnosperms.
+
+Dense thickets, like cane or bamboo brakes, were composed of thick
+clumps of CALAMITES, whose slender, jointed stems shot up to a
+height of forty feet, and at the joints bore slender branches set
+with whorls of leaves. These were close allies of the Equiseta or
+"horsetails," of the present; but they bore characteristics of
+higher classes in the woody structures of their stems.
+
+There were also vast monotonous forests, composed chiefly of trees
+belonging to the lycopods, and whose nearest relatives to-day are
+the little club mosses of our eastern woods. Two families of
+lycopods deserve special mention,--the Lepidodendrons and the
+Sigillaria.
+
+The LEPIDODENDRON, or "scale tree," was a gigantic club moss fifty
+and seventy-five feet high, spreading toward the top into stout
+branches, at whose ends were borne cone-shaped spore cases. The
+younger parts of the tree were clothed with stiff needle-shaped
+leaves, but elsewhere the trunk and branches were marked with
+scalelike scars, left by the fallen leaves, and arranged in spiral
+rows.
+
+The SIGILLARIA, or "seal tree," was similar to the Lepidodendron,
+but its fluted trunk divided into even fewer branches, and was
+dotted with vertical rows of leaf scars, like the impressions of a
+seal.
+
+Both Lepidodendron and Sigillaria were anchored by means of great
+cablelike underground stems, which ran to long distances through
+the marshy ground. The trunks of both trees had a thick woody
+rind, inclosing loose cellular tissue and a pith. Their hollow
+stumps, filled with sand and mud, are common in the Coal Measures,
+and in them one sometimes finds leaves and stems, land shells, and
+the bones of little reptiles of the time which made their home
+there.
+
+It is important to note that some of these gigantic lycopods,
+which are classed with the CRYPTOGAMS, or flowerless plants, had
+pith and medullary rays dividing their cylinders into woody
+wedges. These characters connect them with the PHANEROGAMS, or
+flowering plants. Like so many of the organisms of the remote
+past, they were connecting types from which groups now widely
+separated have diverged.
+
+Gymnosperms, akin to the cycads, were also present in the
+Carboniferous forests. Such were the different species of
+CORDAITES, trees pyramidal in shape, with strap-shaped leaves and
+nutlike fruit. Other gymnosperms were related to the yews, and it
+was by these that many of the fossil nuts found in the Coal
+Measures were borne. It is thought by some that the gymnosperms
+had their station on the drier plains and higher lands.
+
+The Carboniferous jungles extended over parts of Europe and of
+Asia, as well as eastern North America, and reached from the
+equator to within nine degrees of the north pole. Even in these
+widely separated regions the genera and species of coal plants are
+close akin and often identical.
+
+INVERTEBRATES. Among the echinoderms, crinoids are now exceedingly
+abundant, sea urchins are more plentiful, and sea cucumbers are
+found now for the first time. Trilobites are rapidly declining,
+and pass away forever with the close of the period. Eurypterids
+are common; stinging scorpions are abundant; and here occur the
+first-known spiders.
+
+We have seen that the arthropods were the first of all animals to
+conquer the realm of the air, the earliest insects appearing in
+the Ordovician. Insects had now become exceedingly abundant, and
+the Carboniferous forests swarmed with the ancestral types of
+dragon flies,--some with a spread of wing of more than two feet,--
+May flies, crickets, and locusts. Cockroaches infested the swamps,
+and one hundred and thirty-three species of this ancient order
+have been discovered in the Carboniferous of North America. The
+higher flower-loving insects are still absent; the reign of the
+flowering plants has not yet begun. The Paleozoic insects were
+generalized types connecting the present orders. Their fore wings
+were still membranous and delicately veined, and used in flying;
+they had not yet become thick, and useful only as wing covers, as
+in many of their descendants.
+
+FISHES still held to the Devonian types, with the exception that
+the strange ostracoderms now had perished.
+
+AMPHIBIANS. The vertebrates had now followed the arthropods and
+the mollusks upon the land, and had evolved a higher type adapted
+to the new environment. Amphibians--the class to which frogs and
+salamanders belong--now appear, with lungs for breathing air and
+with limbs for locomotion on the land. Most of the Carboniferous
+amphibians were shaped like the salamander, with weak limbs
+adapted more for crawling than for carrying the body well above
+the ground. Some legless, degenerate forms were snakelike in
+shape.
+
+The earliest amphibians differ from those of to-day in a number of
+respects. They were connecting types linking together fishes, from
+which they were descended, with reptiles, of which they were the
+ancestors. They retained the evidence of their close relationship
+with the Devonian fishes in their cold blood, their gills and
+aquatic habit during their larval stage, their teeth with dentine
+infolded like those of the Devonian ganoids but still more
+intricately, and their biconcave vertebrae which never completely
+ossified. These, the highest vertebrates of the time, had not yet
+advanced beyond the embryonic stage of the more or less
+cartilaginous skeleton and the persistent notochord.
+
+On the other hand, the skull of the Carboniferous amphibians was
+made of close-set bony plates, like the skull of the reptile,
+rather than like that of the frog, with its open spaces (Figs. 313
+and 314). Unlike modern amphibians, with their slimy skin, the
+Carboniferous amphibians wore an armor of bony scales over the
+ventral surface and sometimes over the back as well.
+
+It is interesting to notice from the footprints and skeletons of
+these earliest-known vertebrates of the land what was the
+primitive number of digits. The Carboniferous amphibians had five-
+toed feet, the primitive type of foot, from which their
+descendants of higher orders, with a smaller number of digits,
+have diverged.
+
+The Carboniferous was the age of lycopods and amphibians, as the
+Devonian had been the age of rhizocarps and fishes.
+
+LIFE OF THE PERMIAN. The close of the Paleozoic was, as we have
+seen, a time of marked physical changes. The upridging of the
+Appalachians had begun and a wide continental uplift--proved by
+the absence of Permian deposits over large areas where
+sedimentation had gone on before--opened new lands for settlement
+to hordes of air-breathing animals. Changes of climate compelled
+extensive migrations, and the fauna of different regions were thus
+brought into conflict. The Permian was a time of pronounced
+changes in plant and animal life, and a transitional period
+between two great eras. The somber forests of the earlier
+Carboniferous, with their gigantic club mosses, were now replaced
+by forests of cycads, tree ferns, and conifers. Even in the lower
+Permian the Lepidodendron and Sigillaria were very rare, and
+before the end of the epoch they and the Calamites also had become
+extinct. Gradually the antique types of the Paleozoic fauna died
+out, and in the Permian rocks are found the last survivors of the
+cystoid, the trilobite, and the eurypterid, and of many long-lived
+families of brachiopods, mollusks, and other invertebrates. The
+venerable Orthoceras and the Goniatite linger on through the epoch
+and into the first period of the succeeding era. Forerunners of
+the great ammonite family of cephalopod mollusks now appear. The
+antique forms of the earlier Carboniferous amphibians continue,
+but with many new genera and a marked increase in size.
+
+A long forward step had now been taken in the evolution of the
+vertebrates. A new and higher type, the reptiles, had appeared,
+and in such numbers and variety are they found in the Permian
+strata that their advent may well have occurred in a still earlier
+epoch. It will be most convenient to describe the Permian reptiles
+along with their descendants of the Mesozoic.
+
+
+
+
+
+CHAPTER XX
+
+THE MESOZOIC
+
+
+With the close of the Permian the world of animal and vegetable
+life had so changed that the line is drawn here which marks the
+end of the old order and the beginning of the new and separates
+the Paleozoic from the succeeding era,--the Mesozoic, the Middle
+Age of geological history. Although the Mesozoic era is shorter
+than the Paleozoic, as measured by the thickness of their strata,
+yet its duration must be reckoned in millions of years. Its
+predominant life features are the culmination and the beginning of
+the decline of reptiles, amphibians, cephalopod mollusks, and
+cycads, and the advent of marsupial mammals, birds, teleost
+fishes, and angiospermous plants. The leading events of the long
+ages of the era we can sketch only in the most summary way.
+
+The Mesozoic comprises three systems,--the TRIASSIC, named from
+its threefold division in Germany; the JURASSIC, which is well
+displayed in the Jura Mountains; and the CRETACEOUS, which
+contains the extensive chalk (Latin, creta) deposits of Europe.
+
+In eastern North America the Mesozoic rocks are much less
+important than the Paleozoic, for much of this portion of the
+continent was land during the Mesozoic era, and the area of the
+Mesozoic rocks is small. In western North America, on the other
+hand, the strata of the Mesozoic--and of the Cenozoic also--are
+widely spread. The Paleozoic rocks are buried quite generally from
+view except where the mountain makings and continental uplifts of
+the Mesozoic and Cenozoic have allowed profound erosion to bring
+them to light, as in deep canyons and about mountain axes. The
+record of many of the most important events in the development of
+the continent during the Mesozoic and Cenozoic eras is found in
+the rocks of our western states.
+
+THE TRIASSIC AND JURASSIC
+
+EASTERN NORTH AMERICA. The sedimentary record interrupted by the
+Appalachian deformation was not renewed in eastern North America
+until late in the Triassic. Hence during this long interval the
+land stood high, the coast was farther out than now, and over our
+Atlantic states geological time was recorded chiefly in erosion
+forms of hill and plain which have long since vanished. The area
+of the later Triassic rocks of this region, which take up again
+the geological record, is seen in the map of Figure 260. They lie
+on the upturned and eroded edges of the older rocks and occupy
+long troughs running for the most part parallel to the Atlantic
+coast. Evidently subsidence was in progress where these rocks were
+deposited. The eastern border of Appalachia was now depressed. The
+oldland was warping, and long belts of country lying parallel to
+the shore subsided, forming troughs in which thousands of feet of
+sediment now gathered.
+
+These Triassic rocks, which are chiefly sandstones, hold no marine
+fossils, and hence were not laid in open arms of the sea. But
+their layers are often ripple-marked, and contain many tracks of
+reptiles, imprints of raindrops, and some fossil wood, while an
+occasional bed of shale is filled with the remains of fishes. We
+may conceive, then, of the Connecticut valley and the larger
+trough to the southwest as basins gradually sinking at a rate
+perhaps no faster than that of the New Jersey coast to-day, and as
+gradually aggraded by streams from the neighboring uplands. Their
+broad, sandy flats were overflowed by wandering streams, and when
+subsidence gained on deposition shallow lakes overspread the
+alluvial plains. Perhaps now and then the basins became long,
+brackish estuaries, whose low shores were swept by the incoming
+tide and were in turn left bare at its retreat to receive the rain
+prints of passing showers and the tracks of the troops of reptiles
+which inhabited these valleys.
+
+The Triassic rocks are mainly red sandstones,--often feldspathic,
+or arkose, with some conglomerates and shales. Considering the
+large amount of feldspathic material in these rocks, do you infer
+that they were derived from the adjacent crystalline and
+metamorphic rocks of the oldland of Appalachia, or from the
+sedimentary Paleozoic rocks which had been folded into mountains
+during the Appalachian deformation? If from the former, was the
+drainage of the northern Appalachian mountain region then, as now,
+eastward and southeastward toward the Atlantic? The Triassic
+sandstones are voluminous, measuring at least a mile in thickness,
+and are largely of coarse waste. What do you infer as to the
+height of the lands from which the waste was shed, or the
+direction of the oscillation which they were then undergoing? In
+the southern basins, as about Richmond, Virginia, are valuable
+beds of coal; what was the physical geography of these areas when
+the coal was being formed?
+
+Interbedded with the Triassic sandstones are contemporaneous lava
+beds which were fed from dikes. Volcanic action, which had been
+remarkably absent in eastern North America during Paleozoic times,
+was well-marked in connection with the warping now in progress.
+Thick intrusive sheets have also been driven in among the strata,
+as, for example, the sheet of the Palisades of the Hudson,
+described on page 269.
+
+The present condition of the Triassic sandstones of the
+Connecticut valley is seen in Figure 315. Were the beds laid in
+their present attitude? What was the nature of the deformation
+which they have suffered? When did the intrusion of lava sheets
+take place relative to the deformation? What effect have these
+sheets on the present topography, and why? Assuming that the
+Triassic deformation went on more rapidly than denudation, what
+was its effect on the topography of the time? Are there any of its
+results remaining in the topography of to-day? Do the Triassic
+areas now stand higher or lower than the surrounding country, and
+why? How do the Triassic sandstones and shales compare in hardness
+with the igneous and metamorphic rocks about them? The Jurassic
+strata are wanting over the Triassic areas and over all of eastern
+North America. Was this region land or sea, an area of erosion or
+sedimentation, during the Jurassic period? In New Jersey,
+Pennsylvania, and farther southwest the lowest strata of the next
+period, the Cretaceous, rest on the eroded edges of the earlier
+rocks. The surface on which they lie is worn so even that we must
+believe that at the opening of the Cretaceous the oldland of
+Appalachia, including the Triassic areas, had been baseleveled at
+least near the coast. When, therefore, did the deformation of the
+Triassic rocks occur?
+
+WESTERN NORTH AMERICA. Triassic strata infolded in the Sierra
+Nevada Mountains carry marine fossils and reach a thickness of
+nearly five thousand feet. California was then under water, and
+the site of the Sierra was a subsiding trough slowly filling with
+waste from the Great Basin land to the east.
+
+Over a long belt which reaches from Wyoming across Colorado into
+New Mexico no Triassic sediments are found, nor is there any
+evidence that they were ever present; hence this area was high
+land suffering erosion during the Triassic. On each side of it, in
+eastern Colorado and about the Black Hills, in western Texas, in
+Utah, over the site of the Wasatch Mountains, and southward into
+Arizona over the plateaus trenched by the Colorado River, are
+large areas of Triassic rocks, sandstones chiefly, with some rock
+salt and gypsum. Fossils are very rare and none of them marine.
+Here, then, lay broad shallow lakes often salt, and warped basins,
+in which the waste of the adjacent uplands gathered. To this
+system belong the sandstones of the Garden of the Gods in
+Colorado, which later earth movements have upturned with the
+uplifted mountain flanks.
+
+The Jurassic was marked with varied oscillations and wide changes
+in the outline of sea and land.
+
+Jurassic shales of immense thickness--now metamorphosed into
+slates--are found infolded into the Sierra Nevada Mountains. Hence
+during Jurassic times the Sierra trough continued to subside, and
+enormous deposits of mud were washed into it from the land lying
+to the east. Contemporaneous lava flows interbedded with the
+strata show that volcanic action accompanied the downwarp, and
+that molten rock was driven upward through fissures in the crust
+and outspread over the sea floor in sheets of lava.
+
+THE SIERRA DEFORMATION. Ever since the middle of the Silurian, the
+Sierra trough had been sinking, though no doubt with halts and
+interruptions, until it contained nearly twenty-five thousand feet
+of sediment. At the close of the Jurassic it yielded to lateral
+pressure and the vast pile of strata was crumpled and upheaved
+into towering mountains. The Mesozoic muds were hardened and
+squeezed into slates. The rocks were wrenched and broken, and
+underground waters began the work of filling their fissures with
+gold-bearing quartz, which was yet to wait millions of years
+before the arrival of man to mine it. Immense bodies of molten
+rock were intruded into the crust as it suffered deformation, and
+these appear in the large areas of granite which the later
+denudation of the range has brought to light.
+
+The same movements probably uplifted the rocks of the Coast Range
+in a chain of islands. The whole western part of the continent was
+raised and its seas and lakes were for the most part drained away.
+
+THE BRITISH ISLES. The Triassic strata of the British Isles are
+continental, and include breccia beds of cemented talus, deposits
+of salt and gypsum, and sandstones whose rounded and polished
+grains are those of the wind-blown sands of deserts. In Triassic
+times the British Isles were part of a desert extending over much
+of northwestern Europe.
+
+THE CRETACEOUS
+
+The third great system of the Mesozoic includes many formations,
+marine and continental, which record a long and complicated
+history marked by great oscillations of the crust and wide changes
+in the outlines of sea and land.
+
+EARLY CRETACEOUS. In eastern North America the lowest Cretaceous
+series comprises fresh-water formations which are traced from
+Nantucket across Martha's Vineyard and Long Island, and through
+New Jersey southward into Georgia. They rest unconformably on the
+Triassic sandstones and the older rocks of the region. The
+Atlantic shore line was still farther out than now in the northern
+states. Again, as during the Triassic, a warping of the crust
+formed a long trough parallel to the coast and to the Appalachian
+ridges, but cut off from the sea; and here the continental
+deposits of the early Cretaceous were laid.
+
+Along the Gulf of Mexico the same series was deposited under like
+conditions over the area known as the Mississippi embayment,
+reaching from Georgia northwestward into Tennessee and thence
+across into Arkansas and southward into Texas.
+
+In the Southwest the subsidence continued until the transgressing
+sea covered most of Mexico and Texas and extended a gulf northward
+into Kansas. In its warm and quiet waters limestones accumulated
+to a depth of from one thousand to five thousand feet in Texas,
+and of more than ten thousand feet in Mexico. Meanwhile the
+lowlands, where the Great Plains are now, received continental
+deposits; coal swamps stretched from western Montana into British
+Columbia.
+
+THE MIDDLE CRETACEOUS. This was a land epoch. The early Cretaceous
+sea retired from Texas and Mexico, for its sediments are overlain
+unconformably by formations of the Upper Cretaceous. So long was
+the time gap between the two series that no species found in the
+one occurs in the other.
+
+THE UPPER CRETACEOUS. There now began one of the most remarkable
+events in all geological history,--the great Cretaceous
+subsidence. Its earlier warpings were recorded in continental
+deposits,--wide sheets of sandstone, shale, and some coal,--which
+were spread from Texas to British Columbia. These continental
+deposits are overlain by a succession of marine formations whose
+vast area is shown on the map, Figure 260. We may infer that as
+the depression of the continent continued the sea came in far and
+wide over the coast lands and the plains worn low during the
+previous epochs. Upper Cretaceous formations show that south of
+New England the waters of the Atlantic somewhat overlapped the
+crystalline rocks of the Piedmont Belt and spread their waste over
+the submerged coastal plain. The Gulf of Mexico again covered the
+Mississippi embayment, reaching as far north as southern Illinois,
+and extended over Texas.
+
+A mediterranean sea now stretched from the Gulf to the arctic
+regions and from central Iowa to the eastern shore of the Great
+Basin land at about the longitude of Salt Lake City, the Colorado
+Mountains rising from it in a chain of islands. Along with minor
+oscillations there were laid in the interior sea various
+formations of sandstones, shales, and limestones, and from Kansas
+to South Dakota beds of white chalk show that the clear, warm
+waters swarmed at times with foraminiferal life whose
+disintegrating microscopic shells accumulated in this rare
+deposit.
+
+At this epoch a wide sea, interrupted by various islands,
+stretched across Eurasia from Wales and western Spain to China,
+and spread southward over much of the Sahara. To the west its
+waters were clear and on its floor the crumbled remains of
+foraminifers gathered in heavy accumulations of calcareous ooze,--
+the white chalk of France and England. Sea urchins were also
+abundant, and sponges contributed their spicules to form nodules
+of flint.
+
+THE LARAMIE. The closing stage of the Cretaceous was marked in
+North America by a slow uplift of the land. As the interior sea
+gradually withdrew, the warping basins of its floor were filled
+with waste from the rising lands about them, and over this wide
+area there were spread continental deposits in fresh-water lakes
+like the Great Lakes of the present, in brackish estuaries, and in
+river plains, while occasional oscillations now and again let in
+the sea. There were vast marshes in which there accumulated the
+larger part of the valuable coal seams of the West. The Laramie is
+the coal-bearing series of the West, as the Pennsylvanian is of
+the eastern part of our country.
+
+THE ROCKY MOUNTAIN DEFORMATION. At the close of the Cretaceous we
+enter upon an epoch of mountain-making far more extensive than any
+which the continent had witnessed. The long belt lying west of the
+ancient axes of the Colorado Islands and east of the Great Basin
+land had been an area of deposition for many ages, and in its
+subsiding troughs Paleozoic and Mesozoic sediments had gathered to
+the depth of many thousand feet. And now from Mexico well-nigh to
+the Arctic Ocean this belt yielded to lateral pressure. The
+Cretaceous limestones of Mexico were folded into lofty mountains.
+A massive range was upfolded where the Wasatch Mountains now are,
+and various ranges of the Rockies in Colorado and other states
+were upridged. However slowly these deformations were effected
+they were no doubt accompanied by world-shaking earthquakes, and
+it is known that volcanic eruptions took place on a magnificent
+scale. Outflows of lava occurred along the Wasatch, the laccoliths
+of the Henry Mountains were formed, while the great masses of
+igneous rock which constitute the cores of the Spanish Peaks and
+other western mountains were thrust up amid the strata. The high
+plateaus from which many of these ranges rise had not yet been
+uplifted, and the bases of the mountains probably stood near the
+level of the sea.
+
+North America was now well-nigh completed. The mediterranean seas
+which so often had occupied the heart of the land were done away
+with, and the continent stretched unbroken from the foot of the
+Sierras on the west to the Fall Line of the Atlantic coastal plain
+on the east.
+
+THE MESOZOIC PENEPLAIN. The immense thickness of the Mesozoic
+formations conveys to our minds some idea of the vast length of
+time involved in the slow progress of its successive ages. The
+same lesson is taught as plainly by the amount of denudation which
+the lands suffered during the era.
+
+The beginning of the Mesozoic saw a system of lofty mountain
+ranges stretching from New York into central Alabama. The end of
+this long era found here a wide peneplain crossed by sluggish
+wandering rivers and overlooked by detached hills as yet unreduced
+to the general level. The Mesozoic era was long enough for the
+Appalachian Mountains, upridged at its beginning, to have been
+weathered and worn away and carried grain by grain to the sea. The
+same plain extended over southern New England. The Taconic range,
+uplifted partially at least at the close of the Ordovician, and
+the block mountains of the Triassic, together with the pre-
+Cambrian mountains of ancient Appalachia, had now all been worn to
+a common level with the Allegheny ranges. The Mesozoic peneplain
+has been upwarped by later crustal movements and has suffered
+profound erosion, but the remnants of it which remain on the
+upland of southern New England and the even summits of the
+Allegheny ridges suffice to prove that it once existed. The age of
+the Mesozoic peneplain is determined from the fact that the lower
+Tertiary sediments were deposited on its even surface when at the
+close of the era the peneplain was depressed along its edges
+beneath the sea.
+
+LIFE OF THE MESOZOIC
+
+PLANT LIFE OF THE TRIASSIC AND JURASSIC. The Carboniferous forests
+of lepidodendrons and sigillafids had now vanished from the earth.
+The uplands were clothed with conifers, like the Araucarian pines
+of South America and Australia. Dense forests of tree ferns throve
+in moist regions, and canebrakes of horsetails of modern type, but
+with stems reaching four inches in thickness, bordered the lagoons
+and marshes. Cycads were exceedingly abundant. These gymnosperms,
+related to the pines and spruces in structure and fruiting, but
+palmlike in their foliage, and uncoiling their long leaves after
+the manner of ferns, culminated in the Jurassic. From the view
+point of the botanist the Mesozoic is the Age of Cycads, and after
+this era they gradually decline to the small number of species now
+existing in tropical latitudes.
+
+PLANT LIFE OF THE CRETACEOUS. In the Lower Cretaceous the
+woodlands continued of much the same type as during the Jurassic.
+The forerunners now appeared of the modern dicotyls (plants with
+two seed leaves), and in the Middle Cretaceous the
+monocotyledonous group of palms came in. Palms are so like cycads
+that we may regard them as the descendants of some cycad type.
+
+In the UPPER CRETACEOUS, cycads become rare. The highest types of
+flowering plants gain a complete ascendency, and forests of modern
+aspect cover the continent from the Gulf of Mexico to the Arctic
+Ocean. Among the kinds of forest trees whose remains are found in
+the continental deposits of the Cretaceous are the magnolia, the
+myrtle, the laurel, the fig, the tulip tree, the chestnut, the
+oak, beech, elm, poplar, willow, birch, and maple. Forests of
+Eucalyptus grew along the coast of New England, and palms on the
+Pacific shores of British Columbia. Sequoias of many varieties
+ranged far into northern Canada. In northern Greenland there were
+luxuriant forests of magnolias, figs, and cycads; and a similar
+flora has been disinterred from the Cretaceous rocks of Alaska and
+Spitzbergen. Evidently the lands within the Arctic Circle enjoyed
+a warm and genial climate, as they had done during the Paleozoic.
+Greenland had the temperature of Cuba and southern Florida, and
+the time was yet far distant when it was to be wrapped in glacier
+ice.
+
+INVERTEBRATES. During the long succession of the ages of the
+Mesozoic, with their vast geographical changes, there were many
+and great changes in organisms. Species were replaced again and
+again by others better fitted to the changing environment. During
+the Lower Cretaceous alone there were no less than six successive
+changes in the faunas which inhabited the limestone-making sea
+which then covered Texas. We shall disregard these changes for the
+most part in describing the life of the era, and shall confine our
+view to some of the most important advances made in the leading
+types.
+
+Stromatopora have disappeared. Protozoans and sponges are
+exceedingly abundant, and all contribute to the making of Mesozoic
+strata. Corals have assumed a more modern type. Sea urchins have
+become plentiful; crinoids abound until the Cretaceous, where they
+begin their decline to their present humble station.
+
+Trilobites and eurypterids are gone. Ten-footed crustaceans abound
+of the primitive long-tailed type (represented by the lobster and
+the crayfish), and in the Jurassic there appears the modern short-
+tailed type represented by the crabs. The latter type is higher in
+organization and now far more common. In its embryological
+development it passes through the long-tailed stage; connecting
+links in the Mesozoic also indicate that the younger type is the
+offshoot of the older.
+
+Insects evolve along diverse lines, giving rise to beetles, ants,
+bees, and flies.
+
+Brachiopods have dwindled greatly in the number of their species,
+while mollusks have correspondingly increased. The great oyster
+family dates from here.
+
+Cephalopods are now to have their day. The archaic Orthoceras
+lingers on into the Triassic and becomes extinct, but a remarkable
+development is now at hand for the more highly organized
+descendants of this ancient line. We have noticed that in the
+Devonian the sutures of some of the chambered shells become
+angled, evolving the Goniatite type. The sutures now become lobed
+and corrugated in Ceratites. The process was carried still
+farther, and the sutures were elaborately frilled in the great
+order of the Ammonites. It was in the Jurassic that the Ammonites
+reached their height. No fossils are more abundant or
+characteristic of their age. Great banks of their shells formed
+beds of limestone in warm seas the world over.
+
+The ammonite stem branched into a most luxuriant variety of forms.
+The typical form was closely coiled like a nautilus. In others the
+coil was more or less open, or even erected into a spiral. Some
+were hook-shaped, and there were members of the order in which the
+shell was straight, and yet retained all the internal structures
+of its kind. At the end of the Mesozoic the entire tribe of
+ammonites became extinct.
+
+The Belemnite (Greek, belemnon, a dart) is a distinctly higher
+type of cephalopod which appeared in the Triassic, became numerous
+and varied in the Jurassic and Cretaceous, and died out early in
+the Tertiary. Like the squids and cuttlefish, of which it was the
+prototype, it had an internal calcareous shell. This consisted of
+a chambered and siphuncled cone, whose point was sheathed in a
+long solid guard somewhat like a dart. The animal carried an ink
+sac, and no doubt used it as that of the modern cuttlefish is
+used,--to darken the water and make easy an escape from foes.
+Belemnites have sometimes been sketched with fossil sepia, or
+india ink, from their own ink sacs. In the belemnites and their
+descendants, the squids and cuttlefish, the cephalopods made the
+radical change from external to the internal shell. They abandoned
+the defensive system of warfare and boldly took up the offensive.
+No doubt, like their descendants, the belemnites were exceedingly
+active and voracious creatures.
+
+FISHES AND AMPHIBIANS. In the Triassic and Jurassic, little
+progress was made among the fishes, and the ganoid was still the
+leading type. In the Cretaceous the teleosts, or bony fishes, made
+their appearance, while ganoids declined toward their present
+subordinate place.
+
+The amphibians culminated in the Triassic, some being formidable
+creatures as large as alligators. They were still of the primitive
+Paleozoic types. Their pygmy descendants of more modern types are
+not found until later, salamanders appearing first in the
+Cretaceous, and frogs at the beginning of the Cenozoic.
+
+No remains of amphibians have been discovered in the Jurassic. Do
+you infer from this that there were none in existence at that
+time?
+
+REPTILES OF THE MESOZOIC
+
+The great order of Reptiles made its advent in the Permian,
+culminated in the Triassic and Jurassic, and began to decline in
+the Cretaceous. The advance from the amphibian to the reptile was
+a long forward step in the evolution of the vertebrates. In the
+reptile the vertebrate skeleton now became completely ossified.
+Gills were abandoned and breathing was by lungs alone. The
+development of the individual from the egg to maturity was
+uninterrupted by any metamorphosis, such as that of the frog when
+it passes from the tadpole stage. Yet in advancing from the
+amphibian to the reptile the evolution of the vertebrate was far
+from finished. The cold-blooded, clumsy and sluggish, small-
+brained and unintelligent reptile is as far inferior to the higher
+mammals, whose day was still to come, as it is superior to the
+amphibian and the fish.
+
+The reptiles of the Permian, the earliest known, were much like
+lizards in form of body. Constituting a transition type between
+the amphibians on the one hand, and both the higher reptiles and
+the mammals on the other, they retained the archaic biconcave
+vertebra of the fish and in some cases the persistent notochord,
+while some of them, the theromorphs, possessed characters allying
+them with mammals. In these the skull was remarkably similar to
+that of the carnivores, or flesh-eating mammals, and the teeth,
+unlike the teeth of any later reptiles, were divisible into
+incisors, canines, and molars, as are the teeth of mammals.
+
+At the opening of the Mesozoic era reptiles were the most highly
+organized and powerful of any animals on the earth. New ranges of
+continental extent were opened to them, food was abundant, the
+climate was congenial, and they now branched into very many
+diverse types which occupied and ruled all fields,--the land, the
+air, and the sea. The Mesozoic was the Age of Reptiles.
+
+THE ANCESTRY OF SURVIVING REPTILIAN TYPES. We will consider first
+the evolution of the few reptilian types which have survived to
+the present.
+
+Crocodiles, the highest of existing reptiles, are a very ancient
+order, dating back to the lower Jurassic, and traceable to earlier
+ancestral, generalized forms, from which sprang several other
+orders also.
+
+Turtles and tortoises are not found until the early Jurassic, when
+they already possessed the peculiar characteristics which set them
+off so sharply from other reptiles. They seem to have lived at
+first in shallow water and in swamps, and it is not until after
+the end of the Mesozoic that some of the order became adapted to
+life on the land.
+
+The largest of all known turtles, Archelon, whose home was the
+great interior Cretaceous sea, was fully a dozen feet in length
+and must have weighed at least two tons. The skull alone is a yard
+long.
+
+Lizards and snakes do not appear until after the close of the
+Mesozoic, although their ancestral lines may be followed back into
+the Cretaceous.
+
+We will now describe some of the highly specialized orders
+peculiar to the Mesozoic.
+
+LAND REPTILES. The DINOSAURS (terrible reptiles) are an extremely
+varied order which were masters of the land from the late Trias
+until the close of the Mesozoic era. Some were far larger than
+elephants, some were as small as cats; some walked on all fours,
+some were bipedal; some fed on the luxuriant tropical foliage, and
+others on the flesh of weaker reptiles. They may be classed in
+three divisions,--the FLESH-EATING DINOSAURS, the REPTILE-FOOTED
+DINOSAURS, and the BEAKED DINOSAURS,--the latter two divisions
+being herbivorous.
+
+The FLESH-EATING DINOSAURS are the oldest known division of the
+order, and their characteristics are shown in Figure 329. As a
+class, reptiles are egg layers (oviparous); but some of the flesh-
+eating dinosaurs are known to have been VIVIPAROUS, i.e. to have
+brought forth their young alive. This group was the longest-lived
+of any of the three, beginning in the Trias and continuing to the
+close of the Mesozoic era.
+
+Contrast the small fore limbs, used only for grasping, with the
+powerful hind limbs on which the animal stalked about. Some of the
+species of this group seem to have been able to progress by
+leaping in kangaroo fashion. Notice the sharp claws, the ponderous
+tail, and the skull set at right angles with the spinal column.
+The limb bones are hollow. The ceratosaurs reached a length of
+some fifteen feet, and were not uncommon in Colorado and the
+western lands in Jurassic times.
+
+The REPTILE-FOOTED DINOSAURS (Sauropoda) include some of the
+biggest brutes which ever trod the ground. One of the largest,
+whose remains are found entombed in the Jurassic rocks of Wyoming
+and Colorado, is shown in Figure 330.
+
+Note the five digits on the hind feet, the quadrupedal gait, the
+enormous stretch of neck and tail, the small head aligned with the
+vertebral column. Diplodocus was fully sixty-five feet long and
+must have weighed about twenty tons. The thigh bones of the
+Sauropoda are the largest bones which ever grew. That of a genus
+allied to the Diplodocus measures six feet and eight inches, and
+the total length of the animal must have been not far from eighty
+feet, the largest land animal known.
+
+The Sauropoda became extinct when their haunts along the rivers
+and lakes of the western plains of Jurassic times were invaded by
+the Cretaceous interior sea.
+
+The BEAKED DINOSAURS(Predentata) were distinguished by a beak
+sheathed with horn carried in front of the tooth-set jaw, and
+used, we may imagine, in stripping the leaves and twigs of trees
+and shrubs. We may notice only two of the most interesting types.
+
+STEGOSAURUS (plated reptile) takes its name from the double row of
+bony plates arranged along its back. The powerful tail was armed
+with long spines, and the thick skin was defended with irregular
+bits of bone implanted in it. The brain of the stegosaur was
+smaller than that of any land vertebrate, while in the sacrum the
+nerve canal was enlarged to ten times the capacity of the brain
+cavity of the skull. Despite their feeble wits, this well-armored
+family lived on through millions of years which intervened between
+their appearance, at the opening of the Jurassic, and the close of
+the Cretaceous, when they became extinct.
+
+A less stupid brute than the stegosaur was TRICERATOPS, the
+dinosaur of the three horns,--one horn carried on the nose, and a
+massive pair set over the eyes. Note the enormous wedge-shaped
+skull, with its sharp beak, and the hood behind resembling a
+fireman's helmet. Triceratops was fully twenty-five feet long, and
+of twice the bulk of an elephant. The family appeared in the Upper
+Cretaceous and became extinct at its close. Their bones are found
+buried in the fresh-water deposits of the time from Colorado to
+Montana and eastward to the Dakotas.
+
+MARINE REPTILES. In the ocean, reptiles occupied the place now
+held by the aquatic mammals, such as whales and dolphins, and
+their form and structure were similarly modified to suit their
+environment. In the Ichthyosaurus (fish reptile), for example, the
+body was fishlike in form, with short neck and large, pointed head
+(Fig. 333).
+
+A powerful tail, whose flukes were set vertical, and the lower one
+of which was vertebrated, served as propeller, while a large
+dorsal fin was developed as a cutwater. The primitive biconcave
+vertebrae of the fish and of the early land vertebrates were
+retained, and the limbs degenerated into short paddles. The skin
+of the ichthyosaur was smooth like that of a whale, and its food
+was largely fish and cephalopods, as the fossil contents of its
+stomach prove.
+
+These sea monsters disported along the Pacific shore over northern
+California in Triassic times, and the bones of immense members of
+the family occur in the Jurassic strata of Wyoming. Like whales
+and seals, the ichthyosaurs were descended from land vertebrates
+which had become adapted to a marine habitat.
+
+PLESIOSAURS were another order which ranged throughout the
+Mesozoic. Descended from small amphibious animals, they later
+included great marine reptiles, characterized in the typical genus
+by long neck, snakelike head, and immense paddles. They swam in
+the Cretaceous interior sea of western North America.
+
+MOSASAURS belong to the same order as do snakes and lizards, and
+are an offshoot of the same ancestral line of land reptiles. These
+snakelike creatures--which measured as much as forty-five feet in
+length--abounded in the Cretaceous seas. They had large conical
+teeth, and their limbs had become stout paddles.
+
+The lower jaw of the mosasaur was jointed; the quadrate bone,
+which in all reptiles connects the bone of the lower jaw with the
+skull, was movable, and as in snakes the lower jaw could be used
+in thrusting prey down the throat. The family became extinct at
+the end of the Mesozoic, and left no descendants. One may imitate
+the movement of the lower jaw of the mosasaur by extending the
+arms, clasping the hands, and bending the elbows.
+
+FLYING REPTILES. The atmosphere, which had hitherto been tenanted
+only by insects, was first conquered by the vertebrates in the
+Mesozoic. Pterosaurs, winged reptiles, whose whole organism was
+adapted for flight through the air, appeared in the Jurassic and
+passed off the stage of existence before the end of the
+Cretaceous. The bones were hollow, as are those of birds. The
+sternum, or breastbone, was given a keel for the attachment of the
+wing muscles. The fifth finger, prodigiously lengthened, was
+turned backward to support a membrane which was attached to the
+body and extended to the base of the tail. The other fingers were
+free, and armed with sharp and delicate claws, as shown in Figures
+336 and 337.
+
+These "dragons of the air" varied greatly in size; some were as
+small as sparrows, while others surpassed in stretch of wing the
+largest birds of the present day. They may be divided into two
+groups. The earliest group comprises genera with jaws set with
+teeth, and with long tails sometimes provided with a rudderlike
+expansion at the end. In their successors of the later group the
+tail had become short, and in some of the genera the teeth had
+disappeared. Among the latest of the flying reptiles was
+ORNITHOSTOMA (bird beak), the largest creature which ever flew,
+and whose remains are imbedded in the offshore deposits of the
+Cretaceous sea which held sway over our western plains.
+Ornithostoma's spread of wings was twenty feet. Its bones were a
+marvel of lightness, the entire skeleton, even in its petrified
+condition, not weighing more than five or six pounds. The sharp
+beak, a yard long, was toothless and bird-like, as its name
+suggests
+
+BIRDS. The earliest known birds are found in the Jurassic, and
+during the remainder of the Mesozoic they contended with the
+flying reptiles for the empire of the air. The first feathered
+creatures were very different from the birds of to-day. Their
+characteristics prove them an offshoot of the dinosaur line of
+reptiles. ARCHAEOPTERYX (ANCIENT BIRD) (Fig. 338) exhibits a
+strange mingling of bird and reptile. Like birds, it was fledged
+with perfect feathers, at least on wings and tail, but it retained
+the teeth of the reptile, and its long tail was vertebrated, a
+pair of feathers springing from each joint. Throughout the
+Jurassic and Cretaceous the remains of birds are far less common
+than those of flying reptiles, and strata representing hundreds of
+thousands of years intervene between Archaeopteryx and the next
+birds of which we know, whose skeletons occur in the Cretaceous
+beds of western Kansas.
+
+MAMMALS. So far as the entries upon the geological record show,
+mammals made their advent in a very humble way during the Trias.
+These earliest of vertebrates which suckle their young were no
+bigger than young kittens, and their strong affinities with the
+theromorphs suggest that their ancestors are to be found among
+some generalized types of that order of reptiles.
+
+During the long ages of the Mesozoic, mammals continued small and
+few, and were completely dominated by the reptiles. Their remains
+are exceedingly rare, and consist of minute scattered teeth,--with
+an occasional detached jaw,--which prove them to have been flesh
+or insect eaters. In the same way their affinities are seen to be
+with the lowest of mammals,--the MONOTREMES and MARSUPIALS. The
+monotremes,--such as the duckbill mole and the spiny ant-eater of
+Australia, reproduce by means of eggs resembling those of
+reptiles; the marsupials, such as the opossum and the kangaroo,
+bring forth their young alive, but in a very immature condition,
+and carry them for some time after birth in the marsupium, a pouch
+on the ventral side of the body.
+
+
+
+
+
+CHAPTER XXI
+
+THE TERTIARY
+
+
+THE CENOZOIC ERA. The last stages of the Cretaceous are marked by
+a decadence of the reptiles. By the end of that period the
+reptilian forms characteristic of the time had become extinct one
+after another, leaving to represent the class only the types of
+reptiles which continue to modern times. The day of the ammonite
+and the belemnite also now drew to a close, and only a few of
+these cephalopods were left to survive the period. It is therefore
+at the close of the Cretaceous that the line is drawn which marks
+the end of the Middle Age of geology and the beginning of the
+Cenozoic era, the era of modern life,--the Age of Mammals.
+
+In place of the giant reptiles, mammals now become masters of the
+land, appearing first in generalized types which, during the long
+ages of the era, gradually evolve to higher forms, more
+specialized and ever more closely resembling the mammals of the
+present. In the atmosphere the flying dragons of the Mesozoic give
+place to birds and bats. In the sea, whales, sharks, and teleost
+fishes of modern types rule in the stead of huge swimming
+reptiles. The lower vertebrates, the invertebrates of land and
+sea, and the plants of field and forest take on a modern aspect,
+and differ little more from those of to-day than the plants and
+animals of different countries now differ from one another. From
+the beginning of the Cenozoic era until now there is a steadily
+increasing number of species of animals and plants which have
+continued to exist to the present time.
+
+The Cenozoic era comprises two divisions,--the TERTIARY period and
+the QUATERNARY period.
+
+In the early days of geology the formations of the entire
+geological record, so far as it was then known, were divided into
+three groups,--the PRIMARY, the SECONDARY (now known as the
+Mesozoic), and the TERTIARY, When the third group was subdivided
+into two systems, the term Tertiary was retained for the first
+system of the two, while the term QUATERNARY was used to designate
+the second.
+
+DIVISIONS OF THE TERTIARY. The formations of the Tertiary are
+grouped in three divisions,--the PLIOCENE (more recent), the
+MIOCENE (less recent), and the EOCENE (the dawn of the recent).
+Each of these epochs is long and complex. Their various sub-
+divisions are distinguished each by its own peculiar organisms,
+and the changes of physical geography recorded in their strata. In
+the rapid view which we are compelled to take we can note only a
+few of the most conspicuous events of the period.
+
+PHYSICAL GEOGRAPHY OF THE TERTIARY IN EASTERN NORTH AMERICA. The
+Tertiary rocks of eastern North America are marine deposits and
+occupy the coastal lowlands of the Atlantic and Gulf states (Fig.
+260). In New England, Tertiary beds occur on the island of
+Martha's Vineyard, but not on the mainland; hence the shore line
+here stood somewhat farther out than now. From New Jersey
+southward the earliest Tertiary sands and clays, still
+unconsolidated, leave only a narrow strip of the edge of the
+Cretaceous between them and the Triassic and crystalline rocks of
+the Piedmont oldland; hence the Atlantic shore here stood farther
+in than now, and at the beginning of the period the present
+coastal plain was continental delta. A broad belt of Tertiary sea-
+laid limestones, sandstones, and shales surrounds the Gulf of
+Mexico and extends northward up the Mississippi embayment to the
+mouth of the Ohio River; hence the Gulf was then larger than at
+present, and its waters reached in a broad bay far up the
+Mississippi valley.
+
+Along the Atlantic coast the Mesozoic peneplain may be traced
+shoreward to where it disappears from view beneath an
+unconformable cover of early Tertiary marine strata. The beginning
+of the Tertiary was therefore marked by a subsidence. The wide
+erosion surface which at the close of the Mesozoic lay near sea
+level where the Appalachian Mountains and their neighboring
+plateaus and uplands now stand was lowered gently along its
+seaward edge beneath the Tertiary Atlantic to receive a cover of
+its sediments.
+
+As the period progressed slight oscillations occurred from time to
+time. Strips of coastal plain were added to the land, and as early
+as the close of the Miocene the shore lines of the Atlantic and
+Gulf states had reached well-nigh their present place. Louisiana
+and Florida were the last areas to emerge wholly from the sea,--
+Florida being formed by a broad transverse upwarp of the
+continental delta at the opening of the Miocene, forming first an
+island, which afterwards was joined to the mainland.
+
+THE PACIFIC COAST. Tertiary deposits with marine fossils occur
+along the western foothills of the Sierra Nevadas, and are
+crumpled among the mountain masses of the Coast Ranges; it is
+hence inferred that the Great Valley of California was then a
+border sea, separated from the ocean by a chain of mountainous
+islands which were upridged into the Coast Ranges at a still later
+time. Tertiary marine strata are spread over the lower Columbia
+valley and that of Puget Sound, showing that the Pacific came in
+broadly there.
+
+THE INTERIOR OF THE WESTERN UNITED STATES. The closing stages of
+the Mesozoic were marked, as we have seen, by the upheaval of the
+Rocky Mountains and other western ranges. The bases of the
+mountains are now skirted by widespread Tertiary deposits, which
+form the highest strata of the lofty plateaus from the level of
+whose summits the mountains rise. Like the recent alluvium of the
+Great Valley of California, these deposits imply low-lying lands
+when they were laid, and therefore at that time the mountains rose
+from near sea level. But the height at which the Tertiary strata
+now stand--five thousand feet above the sea at Denver, and twice
+that height in the plateaus of southern Utah--proves that the
+plateaus of which the Tertiary strata form a part have been
+uplifted during the Cenozoic. During their uplift, warping formed
+extensive basins both east and west of the Rockies, and in these
+basins stream-swept and lake-laid waste gathered to depths of
+hundreds and thousands of feet, as it is accumulating at present
+in the Great Valley of California and on the river plains of
+Turkestan. The Tertiary river deposits of the High Plains have
+already been described. How widespread are these ancient river
+plains and beds of fresh-water lakes may be seen in the map of
+Figure 260.
+
+THE BAD LANDS. In several of the western states large areas of
+Tertiary fresh-water deposits have been dissected to a maze of
+hills whose steep sides are cut with innumerable ravines. The
+deposits of these ancient river plains and lake beds are little
+cemented and because of the dryness of the climate are unprotected
+by vegetation; hence they are easily carved by the wet-weather
+rills of scanty and infrequent rains. These waterless, rugged
+surfaces were named by the early French explorers the BAD LANDS
+because they were found so difficult to traverse. The strata of
+the Bad Lands contain vast numbers of the remains of the animals
+of Tertiary times, and the large amount of barren surface exposed
+to view makes search for fossils easy and fruitful. These desolate
+tracts are therefore frequently visited by scientific collecting
+expeditions.
+
+MOUNTAIN MAKING IN THE TERTIARY. The Tertiary period included
+epochs when the earth's crust was singularly unquiet. From time to
+time on all the continents subterranean forces gathered head, and
+the crust was bent and broken and upridged in lofty mountains.
+
+The Sierra Nevada range was formed, as we have seen, by strata
+crumpling at the end of the Jurassic. But since that remote time
+the upfolded mountains had been worn to plains and hilly uplands,
+the remnants of whose uplifted erosion surfaces may now be traced
+along the western mountain slopes. Beginning late in the Tertiary,
+the region was again affected by mountain-making movements. A
+series of displacements along a profound fault on the eastern side
+tilted the enormous earth block of the Sierras to the west,
+lifting its eastern edge to form the lofty crest and giving to the
+range a steep eastern front and a gentle descent toward the
+Pacific.
+
+The Coast Ranges also have had a complex history with many
+vicissitudes. The earliest foldings of their strata belong to the
+close of the Jurassic, but it was not until the end of the Miocene
+that the line of mountainous islands and the heavy sediments which
+had been deposited on their submerged flanks were crushed into a
+continuous mountain chain. Thick Pliocene beds upon their sides
+prove that they were depressed to near sea level during the later
+Tertiary. At the close of the Pliocene the Coast Ranges rose along
+with the upheaval of the Sierra, and their gradual uplift has
+continued to the present time.
+
+The numerous north-south ranges of the Great Basin and the Mount
+Saint Elias range of Alaska were also uptilted during the
+Tertiary.
+
+During the Tertiary period many of the loftiest mountains of the
+earth--the Alps, the Apennines, the Pyrenees, the Atlas, the
+Caucasus, and the Himalayas--received the uplift to which they owe
+most of their colossal bulk and height, as portions of the
+Tertiary sea beds now found high upon their flanks attest. In the
+Himalayas, Tertiary marine limestones occur sixteen thousand five
+hundred feet above sea level.
+
+VOLCANIC ACTIVITY IN THE TERTIARY. The vast deformations of the
+Tertiary were accompanied on a corresponding scale by outpourings
+of lava, the outburst of volcanoes, and the intrusion of molten
+masses within the crust. In the Sierra Nevadas the Miocene river
+gravels of the valleys of the western slope, with their placer
+deposits of gold, were buried beneath streams of lava and beds of
+tuff. Volcanoes broke forth along the Rocky Mountains and on the
+plateaus of Utah, New Mexico, and Arizona.
+
+Mount Shasta and the immense volcanic piles of the Cascades date
+from this period. The mountain basin of the Yellowstone Park was
+filled to a depth of several thousand feet with tuffs and lavas,
+the oldest dating as far back as the beginning of the Tertiary.
+Crandall volcano was reared in the Miocene and the latest
+eruptions of the Park are far more recent.
+
+THE COLUMBIA AND SNAKE RIVER LAVAS. Still more important is the
+plateau of lava, more than two hundred thousand square miles in
+area, extending from the Yellowstone Park to the Cascade
+Mountains, which has been built from Miocene times to the present.
+
+Over this plateau, which occupies large portions of Idaho,
+Washington, and Oregon, and extends into northern California and
+Nevada, the country rock is basaltic lava. For thousands of square
+miles the surface is a lava plain which meets the boundary
+mountains as a lake or sea meets a rugged and deeply indented
+coast. The floods of molten rock spread up the mountain valleys
+for a score of miles and more, the intervening spurs rising above
+the lava like long peninsulas, while here and there an isolated
+peak was left to tower above the inundation like an island off a
+submerged shore.
+
+The rivers which drain the plateau--the Snake, the Columbia, and
+their tributaries--have deeply trenched it, yet their canyons,
+which reach the depth of several thousand feet, have not been worn
+to the base of the lava except near the margin and where they cut
+the summits of mountains drowned beneath the flood. Here and there
+the plateau has been deformed. It has been upbent into great
+folds, and broken into immense blocks of bedded lava, forming
+mountain ranges, which run parallel with the Pacific coast line.
+On the edges of these tilted blocks the thickness of the lava is
+seen to be fully five thousand feet. The plateau has been built,
+like that of Iceland, of innumerable overlapping sheets of lava.
+On the canyon walls they weather back in horizontal terraces and
+long talus slopes. One may distinguish each successive flow by its
+dense central portion, often jointed with large vertical columns,
+and the upper portion with its mass of confused irregular columns
+and scoriaceous surface. The average thickness of the flows seems
+to be about seventy-five feet.
+
+The plateau was long in building. Between the layers are found in
+places old soil beds and forest grounds and the sediments of
+lakes. Hence the interval between the flows in any locality was
+sometimes long enough for clays to gather in the lakes which
+filled depressions in the surface. Again and again the surface of
+the black basalt was reddened by oxidation and decayed to soil,
+and forests had time to grow upon it before the succeeding
+inundation sealed the sediments and soils away beneath a sheet of
+stone. Near the edges of the lava plain, rivers from the
+surrounding mountains spread sheets of sand and gravel on the
+surface of one flow after another. These pervious sands,
+interbedded with the lava, become the aquifers of artesian wells.
+
+In places the lavas rest on extensive lake deposits, one thousand
+feet deep, and Miocene in age as their fossils prove. It is to the
+middle Tertiary, then, that the earliest flows and the largest
+bulk of the great inundation belong. So ancient are the latest
+floods in the Columbia basin that they have weathered to a
+residual yellow clay from thirty to sixty feet in depth and
+marvelously rich in the mineral substances on which plants feed.
+
+In the Snake River valley the latest lavas are much younger. Their
+surfaces are so fresh and undecayed that here the effusive
+eruptions may well have continued to within the period of human
+history. Low lava domes like those of Iceland mark where last the
+basalt outwelled and spread far and wide before it chilled (Fig.
+341). In places small mounds of scoria show that the eruptions
+were accompanied to a slight degree by explosions of steam. So
+fluid was this superheated lava that recent flows have been traced
+for more than fifty miles.
+
+The rocks underlying the Columbia lavas, where exposed to view,
+are seen to be cut by numerous great dikes of dense basalt, which
+mark the fissures through which the molten rock rose to the
+surface.
+
+The Tertiary included times of widespread and intense volcanic
+action in other continents as well as in North America. In Europe,
+Vesuvius and Etna began their career as submarine volcanoes in
+connection with earth movements which finally lifted Pliocene
+deposits in Sicily to their present height,--four thousand feet
+above the sea. Volcanoes broke forth in central France and
+southern Germany, in Hungary and the Carpathians. Innumerable
+fissures opened in the crust from the north of Ireland and the
+western islands of Scotland to the Faroes, Iceland, and even to
+arctic Greenland; and here great plateaus were built of flows of
+basalt similar to that of the Columbia River. In India, at the
+opening of the Tertiary, there had been an outwelling of basalt,
+flooding to a depth of thousands of feet two hundred thousand
+square miles of the northwestern part of the peninsula, and
+similar inundations of lava occurred where are now the table-lands
+of Abyssinia. From the middle Tertiary on, Asia Minor, Arabia, and
+Persia were the scenes of volcanic action. In Palestine the rise
+of the uplands of Judea at the close of the Eocene, and the
+downfaulting of the Jordan valley were followed by volcanic
+outbursts. In comparison with the middle Tertiary, the present is
+a time of volcanic inactivity and repose.
+
+EROSION OF TERTIARY MOUNTAINS AND PLATEAUS. The mountains and
+plateaus built at various times during the Tertiary and at its
+commencement have been profoundly carved by erosive agents. The
+Sierra Nevada Mountains have been dissected on the western slope
+by such canyons as those of King's River and the Yosemite. Six
+miles of strata have been denuded from parts of the Wasatch
+Mountains since their rise at the beginning of the era. From the
+Colorado plateaus, whose uplift dates from the same time, there
+have been stripped off ten thousand feet of strata over thousands
+of square miles, and the colossal canyon of the Colorado has been
+cut after this great denudation had been mostly accomplished.
+
+On the eastern side of the continent, as we have seen, a broad
+peneplain had been developed by the close of the Cretaceous. The
+remnants of this old erosion surface are now found upwarped to
+various heights in different portions of its area. In southern New
+England it now stands fifteen hundred feet above the sea in
+western Massachusetts, declining thence southward and eastward to
+sea level at the coast. In southwestern Virginia it has been
+lifted to four thousand feet above the sea. Manifestly this upwarp
+occurred since the peneplain was formed; it is later than the
+Mesozoic, and the vast dissection which the peneplain has suffered
+since its uplift must belong to the successive cycles of Cenozoic
+time.
+
+Revived by the uplift, the streams of the area trenched it as
+deeply as its elevation permitted, and reaching grade, opened up
+wide valleys and new peneplains in the softer rocks. The
+Connecticut valley is Tertiary in age, and in the weak Triassic
+sandstones has been widened in places to fifteen miles. Dating
+from the same time are the valleys of the Hudson, the Susquehanna,
+the Delaware, the Potomac, and the Shenandoah.
+
+In Pennsylvania and the states lying to the south the Mesozoic
+peneplain lies along the summits of the mountain ridges. On the
+surface of this ancient plain, Tertiary erosion etched out the
+beautifully regular pattern of the Allegheny mountain ridges and
+their intervening valleys. The weaker strata of the long, regular
+folds were eroded into longitudinal valleys, while the hard
+Paleozoic sandstones, such as the Medina and the Pocono, were left
+in relief as bold mountain walls whose even crests rise to the
+common level of the ancient plain. From Virginia far into Alabama
+the great Appalachian valley was opened to a width in places of
+fifty miles and more, along a belt of intensely folded and faulted
+strata where once was the heart of the Appalachian Mountains. In
+Figure 70 the summit of the Cumberland plateau (ab) marks the
+level of the Mesozoic peneplain, while the lower erosion levels
+are Tertiary and Quaternary in age.
+
+LIFE OF THE TERTIARY PERIOD
+
+VEGETATION AND CLIMATE. The highest plants in structure, the
+DICOTYLS (such as our deciduous forest trees) and the MONOCOTYLS
+(represented by the palms), were introduced during the Cretaceous.
+The vegetable kingdom reached its culmination before the animal
+kingdom, and if the dividing line between the Mesozoic and the
+Cenozoic were drawn according to the progress of plant life, the
+Cretaceous instead of the Tertiary would be made the opening
+period of the modern era.
+
+The plants of the Tertiary belonged, for the most part, to genera
+now living; but their distribution was very different from that of
+the flora of to-day. In the earlier Tertiary, palms flourished
+over northern Europe, and in the northwestern United States grew
+the magnolia and laurel, along with the walnut, oak, and elm. Even
+in northern Greenland and in Spitzbergen there were lakes covered
+with water lilies and surrounded by forests of maples, poplars,
+limes, the cypress of our southern states, and noble sequoias
+similar to the "big trees" and redwoods of California. A warm
+climate like that of the Mesozoic, therefore, prevailed over North
+America and Europe, extending far toward the pole. In the later
+Tertiary the climate gradually became cooler. Palms disappeared
+from Europe, and everywhere the aspect of forests and open lands
+became more like that of to-day. Grasses became abundant,
+furnishing a new food for herbivorous animals.
+
+ANIMAL LIFE OF THE TERTIARY. Little needs to be said of the
+Tertiary invertebrates, so nearly were they like the invertebrates
+of the present. Even in the Eocene, about five per cent of marine
+shells were of species still living, and in the Pliocene the
+proportion had risen to more than one half.
+
+Fishes were of modern types. Teleosts were now abundant. The ocean
+teemed with sharks, some of them being voracious monsters seventy-
+five feet and even more in length, with a gape of jaw of six feet,
+as estimated by the size of their enormous sharp-edged teeth.
+
+Snakes are found for the first time in the early Tertiary. These
+limbless reptiles, evolved by degeneration from lizardlike
+ancestors, appeared in nonpoisonous types scarcely to be
+distinguished from those of the present day.
+
+MAMMALS OF THE EARLY TERTIARY. The fossils of continental deposits
+of the earliest Eocene show that a marked advance had now been
+made in the evolution of the Mammalia. The higher mammals had
+appeared, and henceforth the lower mammals--the monotremes and
+the marsupials--are reduced to a subordinate place.
+
+These first true mammals were archaic and generalized in
+structure. Their feet were of the primitive type, with five toes
+of about equal length. They were also PLANTIGRADES,--that is, they
+touched the ground with the sole of the entire foot from toe to
+heel. No foot had yet become adapted to swift running by a
+decrease in the number of digits and by lifting the heel and sole
+so that only the toes touch the ground,--a tread called
+DIGITIGRADE. Nor was there yet any foot like that of the cats,
+with sharp retractile claws adapted to seizing and tearing the
+prey. The forearm and the lower leg each had still two separate
+bones (ulna and radius, fibula and tibia), neither pair having
+been replaced with a single strong bone, as in the leg of the
+horse. The teeth also were primitive in type and of full number.
+The complex heavy grinders of the horse and elephant, the sharp
+cutting teeth of the carnivores, and the cropping teeth of the
+grass eaters were all still to come.
+
+Phenacodus is a characteristic genus of the early Eocene, whose
+species varied in size from that of a bulldog to that of an animal
+a little larger than a sheep. Its feet were primitive, and their
+five toes bore nails intermediate in form between a claw and a
+hoof. The archaic type of teeth indicates that the animal was
+omnivorous in diet. A cast of the brain cavity shows that, like
+its associates of the time, its brain was extremely small and
+nearly smooth, having little more than traces of convolutions.
+
+The long ages of the Eocene and the following epochs of the
+Tertiary were times of comparatively rapid evolution among the
+Mammalia. The earliest forms evolved along diverging lines toward
+the various specialized types of hoofed mammals, rodents,
+carnivores, proboscidians, the primates, and the other mammalian
+orders as we know them now. We must describe the Tertiary mammals
+very briefly, tracing the lines of descent of only a few of the
+more familiar mammals of the present.
+
+THE HORSE. The pedigree of the horse runs back into the early
+Eocene through many genera and species to a five-toed, [Footnote:
+Or, more accurately, with four perfect toes and a rudimentary
+fifth corresponding to the thumb.] short-legged ancestor little
+bigger than a cat. Its descendants gradually increased in stature
+and became better and better adapted to swift running to escape
+their foes. The leg became longer, and only the tip of the toes
+struck the ground. The middle toe (digit number three), originally
+the longest of the five, steadily enlarged, while the remaining
+digits dwindled and disappeared. The inner digit, corresponding to
+the great toe and thumb, was the first to go. Next number five,
+the little finger, was also dropped. By the end of the Eocene a
+three-toed genus of the horse family had appeared, as large as a
+sheep. The hoof of digit number three now supported most of the
+weight, but the slender hoofs of digits two and four were still
+serviceable. In the Miocene the stature of the ancestors of the
+horse increased to that of a pony. The feet were still three-toed,
+but the side hoofs were now mere dewclaws and scarcely touched the
+ground. The evolution of the family was completed in the Pliocene.
+
+The middle toe was enlarged still more, the side toes were
+dropped, and the palm and foot bones which supported them were
+reduced to splints.
+
+While these changes were in progress the radius and ulna of the
+fore limb became consolidated to a single bone; and in the hind
+limb the fibula dwindled to a splint, while the tibia was
+correspondingly enlarged. The molars, also gradually lengthened,
+and became more and more complex on their grinding surface; the
+neck became longer; the brain steadily increased in size and its
+convolutions became more abundant. The evolution of the horse has
+made for greater fleetness and intelligence.
+
+THE RHINOCEROS AND TAPIR. These animals, which are grouped with
+the horse among the ODD-TOED (perissodactyl) mammals, are now
+verging toward extinction. In the rhinoceros, evolution seems to
+have taken the opposite course from that of the horse. As the
+animal increased in size it became more clumsy, its limbs became
+shorter and more massive, and, perhaps because of its great
+weight, the number of digits were not reduced below the number
+three. Like other large herbivores, the rhinoceros, too slow to
+escape its enemies by flight, learned to withstand them. It
+developed as its means of defense a nasal horn.
+
+Peculiar offshoots of the line appeared at various times in the
+Tertiary. A rhinoceros, semiaquatic in habits, with curved tusks,
+resembling in aspect the hippopotamus, lived along the water
+courses of the plains east of the Rockies, and its bones are now
+found by the thousands in the Miocene of Kansas. Another developed
+along a line parallel to that of the horse, and herds of these
+light-limbed and swift-footed running rhinoceroses ranged the
+Great Plains from the Dakotas southward.
+
+The tapirs are an ancient family which has changed but little
+since it separated from the other perissodactyl stocks in the
+early Tertiary. At present, tapirs are found only in South America
+and southern Asia,--a remarkable distribution which we could not
+explain were it not that the geological record shows that during
+Tertiary times tapirs ranged throughout the northern hemisphere,
+making their way to South America late in that period. During the
+Pleistocene they became extinct over all the intervening lands
+between the widely separated regions where now they live. The
+geographic distribution of animals, as well as their relationships
+and origins, can be understood only through a study of their
+geological history.
+
+THE PROBOSCIDIANS. This unique order of hoofed mammals, of which
+the elephant is the sole survivor, began, so far as known, in the
+Eocene, in Egypt, with a piglike ancestor the size of a small
+horse, with cheek teeth like the Mastodon's, but wanting both
+trunk and tusks. A proboscidian came next with four short tusks,
+and in the Miocene there followed a Mastodon (Fig. 346) armed with
+two pairs of long, straight tusks on which rested a flexible
+proboscis.
+
+The DINOTHERE was a curious offshoot of the line, which developed
+in the Miocene in Europe. In this immense proboscidian, whose
+skull was three feet long, the upper pair of tusks had
+disappeared, and those of the lower jaw were bent down with a
+backward curve in walrus fashion.
+
+In the true ELEPHANTS, which do not appear until near the close of
+the Tertiary, the lower jaw loses its tusks and the grinding teeth
+become exceedingly complex in structure. The grinding teeth of the
+mastodon had long roots and low crowns crossed by four or five
+peaked enameled ridges. In the teeth of the true elephants the
+crown has become deep, and the ridges of enamel have changed to
+numerous upright, platelike folds, their interspaces filled with
+cement. The two genera--Mastodon and Elephant--are connected by
+species whose teeth are intermediate in pattern. The proboscidians
+culminated in the Pliocene, when some of the giant elephants
+reached a height of fourteen feet.
+
+THE ARTIODACTYLS comprise the hoofed Mammalia which have an even
+number of toes, such as cattle, sheep, and swine. Like the
+perissodactyls, they are descended from the primitive five-toed
+plantigrade mammals of the lowest Eocene. In their evolution,
+digit number one was first dropped, and the middle pair became
+larger and more massive, while the side digits, numbers two and
+five, became shorter, weaker, and less serviceable. The FOUR-TOED
+ARTIODACTYLS culminated in the Tertiary; at present they are
+represented only by the hippopotamus and the hog. Along the main
+line of the evolution of the artiodactyls the side toes, digits
+two and five, disappeared, leaving as proof that they once existed
+the corresponding bones of palm and sole as splints. The TWO-TOED
+ARTIODACTYLS, such as the camels, deer, cattle, and sheep, are now
+the leading types of the herbivores.
+
+SWINE AND PECCARIES are two branches of a common stock, the first
+developing in the Old World and the second in the New. In the
+Miocene a noticeable offshoot of the line was a gigantic piglike
+brute, a root eater, with a skull a yard in length, whose remains
+are now found in Colorado and South Dakota.
+
+CAMELS AND LLAMAS. The line of camels and llamas developed in
+North America, where the successive changes from an early Eocene
+ancestor, no larger than a rabbit, are traced step by step to the
+present forms, as clearly as is the evolution of the horse. In the
+late Miocene some of the ancestral forms migrated to the Old World
+by way of a land connection where Bering Strait now is, and there
+gave rise to the camels and dromedaries. Others migrated into
+South America, which had now been connected with our own
+continent, and these developed into the llamas and guanacos, while
+those of the race which remained in North America became extinct
+during the Pleistocene.
+
+Some peculiar branches of the camel stem appeared in North
+America. In the Pliocene arose a llama with the long neck and
+limbs of a giraffe, whose food was cropped from the leaves and
+branches of trees. Far more generalized in structure was the
+Oreodon, an animal related to the camels, but with distinct
+affinities also with other lines, such as those of the hog and
+deer. These curious creatures were much like the peccary in
+appearance, except for their long tails. In the middle Eocene they
+roamed in vast herds from Oregon to Kansas and Nebraska.
+
+THE RUMINANTS. This division of the artiodactyls includes
+antelopes, deer, oxen, bison, sheep, and goats,--all of which
+belong to a common stock which took its rise in Europe in the
+upper Eocene from ancestral forms akin to those of the camels. In
+the Miocene the evolution of the two-toed artiodactyl foot was
+well-nigh completed. Bonelike growths appeared on the head, and
+the two groups of the ruminants became specialized,--the deer with
+bony antlers, shed and renewed each year, and the ruminants with
+hollow horns, whose two bony knobs upon the skull are covered with
+permanent, pointed, horny sheaths.
+
+The ruminants evolved in the Old World, and it was not until the
+later Miocene that the ancestors of the antelope and of some deer
+found their way to North America. Mountain sheep and goats, the
+bison and most of the deer, did not arrive until after the close
+of the Tertiary, and sheep and oxen were introduced by man.
+
+The hoofed mammals of the Tertiary included many offshoots from
+the main lines which we have traced. Among them were a number of
+genera of clumsy, ponderous brutes, some almost elephantine in
+their bulk.
+
+THE CARNIVORES. The ancestral lines of the families of the flesh
+eaters--such as the cats (lions, tigers, etc.), the bears, the
+hyenas, and the dogs (including wolves and foxes)--converge in the
+creodonts of the early Eocene,--an order so generalized that it
+had affinities not only with the carnivores but also with the
+insect eaters, the marsupials, and the hoofed mammals as well.
+From these primitive flesh eaters, with small and simple brains,
+numerous small teeth, and plantigrade tread, the different
+families of the carnivores of the present have slowly evolved.
+
+DOGS AND BEARS. The dog family diverged from the creodonts late in
+the Eocene, and divided into two branches, one of which evolved
+the wolves and the other the foxes. An offshoot gave rise to the
+family of the bears, and so closely do these two families, now
+wide apart, approach as we trace them back in Tertiary times that
+the Amphicyon, a genus doglike in its teeth and bearlike in other
+structures, is referred by some to the dog and by others to the
+bear family. The well-known plantigrade tread of bears is a
+primitive characteristic which has survived from their creodont
+ancestry.
+
+CATS. The family of the cats, the most highly specialized of all
+the carnivores, divided in the Tertiary into two main branches.
+One, the saber-tooth tigers (Fig. 351), which takes its name from
+their long, saberlike, sharp-edged upper canine teeth, evolved a
+succession of genera and species, among them some of the most
+destructive beasts of prey which ever scourged the earth. They
+were masters of the entire northern hemisphere during the middle
+Tertiary, but in Europe during the Pliocene they declined, from
+unknown causes, and gave place to the other branch of cats,--which
+includes the lions, tigers, and leopards. In the Americas the
+saber-tooth tigers long survived the epoch.
+
+MARINE MAMMALS. The carnivorous mammals of the sea--whales,
+seals, walruses, etc.--seem to have been derived from some of the
+creodonts of the early Tertiary by adaptation to aquatic life.
+Whales evolved from some land ancestry at a very early date in the
+Tertiary; in the marine deposits of the Eocene are found the bones
+of the Zeuglodon, a whalelike creature seventy feet in length.
+
+PRIMATES. This order, which includes lemurs, monkeys, apes, and
+man, seems to have sprung from a creodont or insectivorous
+ancestry in the lower Eocene. Lemur-like types, with small, smooth
+brains, were abundant in the United States in the early Tertiary,
+but no primates have been found here in the middle Tertiary and
+later strata. In Europe true monkeys were introduced in the
+Miocene, and were abundant until the close of the Tertiary, when
+they were driven from the continent by the increasing cold.
+
+ADVANCE OF THE MAMMALIA DURING THE TERTIARY. During the several
+millions of years comprised in Tertiary time the mammals evolved
+from the lowly, simple types which tenanted the earth at the
+beginning of the period, into the many kinds of highly specialized
+mammals of the Pleistocene and the present, each with the various
+structures of the body adapted to its own peculiar mode of life.
+The swift feet of the horse, the horns of cattle and the antlers
+of the deer, the lion's claws and teeth, the long incisors of the
+beaver, the proboscis of the elephant, were all developed in
+Tertiary times. In especial the brain of the Tertiary mammals
+constantly grew larger relatively to the size of body, and the
+higher portion of the brain--the cerebral lobes--increased in size
+in comparison with the cerebellum. Some of the hoofed mammals now
+have a brain eight or ten times the size of that of their early
+Tertiary predecessors of equal bulk. Nor can we doubt that along
+with the increasing size of brain went a corresponding increase in
+the keenness of the senses, in activity and vigor, and in
+intelligence.
+
+
+
+
+
+CHAPTER XXII
+
+THE QUATERNARY
+
+
+The last period of geological history, the Quaternary, may be said
+to have begun when all, or nearly all, living species of mollusks
+and most of the existing mammals had appeared.
+
+It is divided into two great epochs. The first, the Pleistocene or
+Glacial epoch, is marked off from the Tertiary by the occupation
+of the northern parts of North America and Europe by vast ice
+sheets; the second, the Recent epoch, began with the disappearance
+of the ice sheets from these continents, and merges into the
+present time.
+
+THE PLEISTOCENE EPOCH
+
+We now come to an episode of unusual interest, so different was it
+from most of the preceding epochs and from the present, and so
+largely has it influenced the conditions of man's life.
+
+The records of the Glacial epoch are so plain and full that we are
+compelled to believe what otherwise would seem almost incredible,
+--that following the mild climate of the Tertiary came a succession
+of ages when ice fields, like that of Greenland, shrouded the
+northern parts of North America and Europe and extended far into
+temperate latitudes.
+
+THE DRIFT. Our studies of glaciers have prepared us to decipher
+and interpret the history of the Glacial epoch, as it is recorded
+in the surface deposits known as the drift. Over most of Canada
+and the northern states this familiar formation is exposed to view
+in nearly all cuttings which pass below the surface soil. The
+drift includes two distinct classes of deposits,--the unstratified
+drift laid down by glacier ice, and the stratified drift spread by
+glacier waters.
+
+The materials of the drift are in any given place in part unlike
+the rock on which it rests. They cannot be derived from the
+underlying rock by weathering, but have been brought from
+elsewhere. Thus where a region is underlain by sedimentary rocks,
+as is the drift-covered area from the Hudson River to the
+Missouri, the drift contains not only fragments of limestone,
+sandstone, and shale of local derivation, but also pebbles of many
+igneous and metamorphic rocks, such as granites, gneisses,
+schists, dike rocks, quartzites, and the quartz of mineral veins,
+whose nearest source is the Archean area of Canada and the states
+of our northern border. The drift received its name when it was
+supposed that the formation had been drifted by floods and
+icebergs from outside sources,--a theory long since abandoned.
+
+The distribution also of the drift points clearly to its peculiar
+origin. Within the limits of the glaciated area it covers the
+country without regard to the relief, mantling with its debris not
+only lowlands and valleys but also highlands and mountain slopes.
+
+The boundary of the drift is equally independent of the relief of
+the land, crossing hills and plains impartially, unlike water-laid
+deposits, whose margins, unless subsequently deformed, are
+horizontal. The boundary of the drift is strikingly lobate also,
+bending outward in broad, convex curves, where there are no
+natural barriers in the topography of the country to set it such a
+limit. Under these conditions such a lobate margin cannot belong
+to deposits of rivers, lakes, or ocean, but is precisely that
+which would mark the edge of a continental glacier which deployed
+in broad tongues of ice.
+
+THE ROCK SURFACE UNDERLYING THE DRIFT. Over much of its area the
+drift rests on firm, fresh rock, showing that both the preglacial
+mantle of residual waste and the partially decomposed and broken
+rock beneath it have been swept away. The underlying rock,
+especially if massive, hard, and of a fine grain, has often been
+ground down to a smooth surface and rubbed to a polish as perfect
+as that seen on the rock beside an Alpine glacier where the ice
+has recently melted back. Frequently it has been worn to the
+smooth, rounded hummocks known as roches moutonnees, and even
+rocky hills have been thus smoothed to flowing outlines like
+roches moutonnees on a gigantic scale. The rock pavement beneath
+the drift is also marked by long, straight, parallel scorings,
+varying in size from deep grooves to fine striae as delicate as
+the hair lines cut by an engraver's needle. Where the rock is soft
+or closely jointed it is often shattered to a depth of several
+feet beneath the drift, while stony clay has been thrust in among
+the fragments into which the rock is broken.
+
+In the presence of these glaciated surfaces we cannot doubt that
+the area of the drift has been overridden by vast sheets of ice
+which, in their steady flow, rasped and scored the rock bed
+beneath by means of the stones with which their basal layers were
+inset, and in places plucked and shattered it.
+
+TILL. The unstratified portion of the drift consists chiefly of
+sheets of dense, stony clay called till, which clearly are the
+ground moraines of ancient continental glaciers. Till is an
+unsorted mixture of materials of all sizes, from fine clay and
+sand, gravel, pebbles, and cobblestones, to large bowlders. The
+stones of the till are of many kinds, some having been plucked
+from the bed rock of the locality where they are found, and others
+having been brought from outside and often distant places. Land
+ice is the only agent known which can spread unstratified material
+in such extensive sheets.
+
+The FINE MATERIAL of the till comes from two different sources. In
+part it is derived from old residual clays, which in the making
+had been leached of the lime and other soluble ingredients of the
+rock from which they weathered. In part it consists of sound rock
+ground fine; a drop of acid on fresh, clayey till often proves by
+brisk effervescence that the till contains much undecayed
+limestone flour. The ice sheet, therefore, both scraped up the
+mantle of long-weathered waste which covered the coun try before
+its coming, and also ground heavily upon the sound rock
+underneath, and crushed and wore to rock flour the fragments which
+it carried.
+
+The color of unweathered till depends on that of the materials of
+which it is composed. Where red sandstones have contributed
+largely to its making, as over the Triassic sandstones of the
+eastern states and the Algonkian sandstones about Lake Superior,
+the drift is reddish. When derived in part from coaly shales, as
+over many outcrops of the Pennsylvanian, it may when moist be
+almost black. Fresh till is normally a dull gray or bluish, so
+largely is it made up of the grindings of unoxidized rocks of
+these common colors.
+
+Except where composed chiefly of sand or coarser stuff,
+unweathered till is often exceedingly dense. Can you suggest by
+what means it has been thus compacted? Did the ice fields of the
+Glacial epoch bear heavy surface moraines like the medial and
+lateral moraines of valley glaciers? Where was the greater part of
+the load of these ice fields carried, judging from what you know
+of the glaciers of Greenland?
+
+BOWLDERS OF THE DRIFT. The pebbles and bowlders of the drift are
+in part stream gravels, bowlders of weathering, and other coarse
+rock waste picked up from the surface of the country by the
+advancing ice, and in part are fragments plucked from ledges of
+sound rock after the mantle of waste had been removed. Many of the
+stones of the till are dressed as only glacier ice can do; their
+sharp edges have been blunted and their sides faceted and scored.
+
+We may easily find all stages of this process represented among
+the pebbles of the till. Some are little worn, even on their
+edges; some are planed and scored on one side only; while some in
+their long journey have been ground down to many facets and have
+lost much of their original bulk. Evidently the ice played fast
+and loose with a stone carried in its basal layers, now holding it
+fast and rubbing it against the rock beneath, now loosening its
+grasp and allowing the stone to turn.
+
+Bowlders of the drift are sometimes found on higher ground than
+their parent ledges. Thus bowlders have been left on the sides of
+Mount Katahdin, Maine, which were plucked from limestone ledges
+twelve miles distant and three thousand feet lower than their
+resting place. In other cases stones have been carried over
+mountain ranges, as in Vermont, where pebbles of Burlington red
+sandstone were dragged over the Green Mountains, three thousand
+feet in height, and left in the Connecticut valley sixty miles
+away. No other geological agent than glacier ice could do this
+work.
+
+The bowlders of the drift are often large. Bowlders ten and twenty
+feet in diameter are not uncommon, and some are known whose
+diameter exceeds fifty feet. As a rule the average size of
+bowlders decreases with increasing distance from their sources.
+Why?
+
+TILL PLAINS. The surface of the drift, where left in its initial
+state, also displays clear proof of its glacial origin. Over large
+areas it is spread in level plains of till, perhaps bowlder-
+dotted, similar to the plains of stony clay left in Spitzbergen by
+the recent retreat of some of the glaciers of that island. In
+places the unstratified drift is heaped in hills of various kinds,
+which we will now describe.
+
+DRUMLINS. Drumlins are smooth, rounded hills composed of till,
+elliptical in base, and having their longer axes parallel to the
+movement of the ice as shown by glacial scorings. They crowd
+certain districts in central New York and in southern Wisconsin,
+where they may be counted by the thousands. Among the numerous
+drumlins about Boston is historic Bunker Hill.
+
+Drumlins are made of ground moraine. They were accumulated and
+given shape beneath the overriding ice, much as are sand bars in a
+river, or in some instances were carved, like roches moutonnees,
+by an ice sheet out of the till left by an earlier ice invasion.
+
+TERMINAL MORAINES. The glaciated area is crossed by belts of
+thickened drift, often a mile or two, and sometimes even ten miles
+and more, in breadth, which lie transverse to the movement of the
+ice and clearly are the terminal moraines of ancient ice sheets,
+marking either the limit of their farthest advance or pauses in
+their general retreat.
+
+The surface of these moraines is a jumble of elevations and
+depressions, which vary from low, gentle swells and shallow sags
+to sharp hills, a hundred feet or so in height, and deep, steep-
+sided hollows. Such tumultuous hills and hummocks, set with
+depressions of all shapes, which usually are without outlet and
+are often occupied by marshes, ponds, and lakes, surely cannot be
+the work of running water. The hills are heaps of drift, lodged
+beneath the ice edge or piled along its front. The basins were
+left among the tangle of morainic knolls and ridges as the margin
+of the ice moved back and forth. Some bowl-shaped basins were made
+by the melting of a mass of ice left behind by the retreating
+glacier and buried in its debris.
+
+THE STRATIFIED DRIFT. Like modern glaciers the ice sheets of the
+Pleistocene were ever being converted into water about their
+margins. Their limits on the land were the lines where their
+onward flow was just balanced by melting and evaporation. On the
+surface of the ice along the marginal zone, rivulets no doubt
+flowed in summer, and found their way through crevasses to the
+interior of the glacier or to the ground. Subglacial streams, like
+those of the Malaspina glacier, issued from tunnels in the ice,
+and water ran along the melting ice front as it is seen to do
+about the glacier tongues of Greenland. All these glacier waters
+flowed away down the chief drainage channels in swollen rivers
+loaded with glacial waste.
+
+It is not unexpected therefore that there are found, over all the
+country where the melting ice retreated, deposits made of the same
+materials as the till, but sorted and stratified by running water.
+Some of these were deposited behind the ice front in ice-walled
+channels, some at the edge of the glaciers by issuing streams, and
+others were spread to long distances in front of the ice edge by
+glacial waters as they flowed away.
+
+ESKERS are narrow, winding ridges of stratified sand and gravel
+whose general course lies parallel with the movement of the
+glacier. These ridges, though evidently laid by running water, do
+not follow lines of continuous descent, but may be found to cross
+river valleys and ascend their sides. Hence the streams by which
+eskers were laid did not flow unconfined upon the surface of the
+ground. We may infer that eskers were deposited in the tunnels and
+ice-walled gorges of glacial streams before they issued from the
+ice front.
+
+KAMES are sand and gravel knolls, associated for the most part
+with terminal moraines, and heaped by glacial waters along the
+margin of the ice.
+
+KAME TERRACES are hummocky embankments of stratified drift
+sometimes found in rugged regions along the sides of valleys. In
+these valleys long tongues of glacier ice lay slowly melting.
+Glacial waters took their way between the edges of the glaciers
+and the hillside, and here deposited sand and gravel in rude
+terraces.
+
+Outwash plains are plains of sand and gravel which frequently
+border terminal moraines on their outward face, and were spread
+evidently by outwash from the melting ice. Outwash plains are
+sometimes pitted by bowl-shaped basins where ice blocks were left
+buried in the sand by the retreating glacier.
+
+Valley trains are deposits of stratified drift with which river
+valleys have been aggraded. Valleys leading outward from the ice
+front were flooded by glacial waters and were filled often to
+great depths with trains of stream-swept drift. Since the
+disappearance of the ice these glacial flood plains have been
+dissected by the shrunken rivers of recent times and left on
+either side the valley in high terraces. Valley trains head in
+morainic plains, and their material grows finer down valley and
+coarser toward their sources. Their gradient is commonly greater
+than that of the present rivers.
+
+THE EXTENT OF THE DRIFT. The extent of the drift of North America
+and its southern limits are best seen in Figure 359. Its area is
+reckoned at about four million square miles. The ice fields which
+once covered so much of our continent were all together ten times
+as large as the inland ice of Greenland, and about equal to the
+enormous ice cap which now covers the antartic regions.
+
+The ice field of Europe was much smaller, measuring about seven
+hundred and seventy thousand square miles.
+
+CENTERS OF DISPERSION. The direction of the movement of the ice is
+recorded plainly in the scorings of the rock surface, in the
+shapes of glaciated hills, in the axes of drumlins and eskers, and
+in trains of bowlders, when the ledges from which they were
+plucked can be discovered. In these ways it has been proved that
+in North America there were three centers where ice gathered to
+the greatest depth, and from which it flowed in all directions
+outward. There were thus three vast ice fields,--one the
+Cordilleran, which lay upon the Cordilleras of British America;
+one the Keewatin, which flowed out from the province of Keewatin,
+west of Hudson Bay; and one the LABRADOR ice field, whose center
+of dispersion was on the highlands of the peninsula of Labrador.
+As shown in Figure 359, the western ice field extended but a short
+way beyond the eastern foothills of the Rocky Mountains, where
+perhaps it met the far-traveled ice from the great central field.
+The Keewatin and the Labrador ice fields flowed farthest toward
+the south, and in the Mississippi valley the one reached the mouth
+of the Missouri and the other nearly to the mouth of the Ohio. In
+Minnesota and Wisconsin and northward they merged in one vast
+field.
+
+The thickness of the ice was so great that it buried the highest
+mountains of eastern North America, as is proved by the
+transported bowlders which have been found upon their summits. If
+the land then stood at its present height above sea level, and if
+the average slope of the ice were no more than ten feet to the
+mile,--a slope so gentle that the eye could not detect it and less
+than half the slope of the interior of the inland ice of
+Greenland,--the ice plateaus about Hudson Bay must have reached a
+thickness of at least ten thousand feet.
+
+In Europe the Scandinavian plateau was the chief center of
+dispersion. At the time of greatest glaciation a continuous field
+of ice extended from the Ural Mountains to the Atlantic, where,
+off the coasts of Norway and the British Isles, it met the sea in
+an unbroken ice wall. On the south it reached to southern England,
+Belgium, and central Germany, and deployed on the eastern plains
+in wide lobes over Poland and central Russia (Fig. 360).
+
+At the same time the Alps supported giant glaciers many times the
+size of the surviving glaciers of to-day, and a piedmont glacier
+covered the plains of northern Switzerland.
+
+THE THICKNESS OF THE DRIFT. The drift is far from uniform in
+thickness. It is comparatively thin and scanty over the Laurentian
+highlands and the rugged regions of New England, while from
+southern New York and Ontario westward over the Mississippi
+valley, and on the great western plains of Canada, it exceeds an
+average of one hundred feet over wide areas, and in places has
+five and six times that thickness. It was to this marginal belt
+that the ice sheets brought their loads, while northwards, nearer
+the centers of dispersion, erosion was excessive and deposition
+slight.
+
+SUCCESSIVE ICE INVASIONS AND THEIR DRIFT SHEETS. Recent studies of
+the drift prove that it does not consist of one indivisible
+formation, but includes a number of distinct drift sheets, each
+with its own peculiar features. The Pleistocene epoch consisted,
+therefore, of several glacial stages,--during each of which the
+ice advanced far southward,--together with the intervening
+interglacial stages when, under a milder climate, the ice melted
+back toward its sources or wholly disappeared.
+
+The evidences of such interglacial stages, and the means by which
+the different drift sheets are told apart, are illustrated in
+Figure 361. Here the country from N to S is wholly covered by
+drift, but the drift from N to m is so unlike that from m to S
+that we may believe it the product of a distinct ice invasion and
+deposited during another and far later glacial stage. The former
+drift is very young, for its drainage is as yet immature, and
+there are many lakes and marshes upon its surface; the latter is
+far older, for its surface has been thoroughly dissected by its
+streams. The former is but slightly weathered, while the latter is
+so old that it is deeply reddened by oxidation and is leached of
+its soluble ingredients such as lime. The younger drift is
+bordered by a distinct terminal moraine, while the margin of the
+older drift is not thus marked. Moreover, the two drift sheets are
+somewhat unlike in composition, and the different proportion of
+pebbles of the various kinds of rocks which they contain shows
+that their respective glaciers followed different tracks and
+gathered their loads from different regions. Again, in places
+beneath the younger drift there is found the buried land surface
+of an older drift with old soils, forest grounds, and vegetable
+deposits, containing the remains of animals and plants, which tell
+of the climate of the interglacial stage in which they lived.
+
+By such differences as these the following drift sheets have been
+made out in America, and similar subdivisions have been recognized
+in Europe.
+
+    5 The Wisconsin formation
+    4 The Iowan formation
+    3 The Illinoian formation
+    2 The Kansan formation
+    1 The pre-Kansan or Jerseyan formation
+
+In New Jersey and Pennsylvania the edge of a deeply weathered and
+eroded drift sheet, the Jerseyan, extends beyond the limits of a
+much younger overlying drift. It may be the equivalent of a deep-
+buried basal drift sheet found in the Mississippi valley beneath
+the Kansan and parted from it by peat, old soil, and gravel beds.
+
+The two succeeding stages mark the greatest snowfall of the
+Glacial epoch. In Kansan times the Keewatin ice field slowly grew
+southward until it reached fifteen hundred miles from its center
+of dispersion and extended from the Arctic Ocean to northeastern
+Kansas. In the Illinoian stage the Labrador ice field stretched
+from Hudson Straits nearly to the Ohio River in Illinois. In the
+Iowan and the Wisconsin, the closing stages of the Glacial epoch,
+the readvancing ice fields fell far short of their former limits
+in the Mississippi valley, but in the eastern states the Labrador
+ice field during Wisconsin times overrode for the most part all
+earlier deposits, and, covering New England, probably met the
+ocean in a continuous wall of ice which set its bergs afloat from
+Massachusetts to northern Labrador.
+
+We select for detailed description the Kansan and the Wisconsin
+formations as representatives, the one of the older and the other
+of the younger drift sheets.
+
+THE KANSAN FORMATION. The Kansan drift consists for the most part
+of a sheet of clayey till carrying smaller bowlders than the later
+drift. Few traces of drumlins, kames, or terminal moraines are
+found upon the Kansan drift, and where thick enough to mask the
+preexisting surface, it seems to have been spread originally in
+level plains of till.
+
+The initial Kansan plain has been worn by running water until
+there are now left only isolated patches and the narrow strips and
+crests of the divides, which still rise to the ancient level. The
+valleys of the larger streams have been opened wide. Their well-
+developed tributaries have carved nearly the entire plain to
+valley slopes (Figs. 50 B, and 59). The lakes and marshes which
+once marked the infancy of the region have long since been
+effaced. The drift is also deeply weathered. The till, originally
+blue in color, has been yellowed by oxidation to a depth of ten
+and twenty feet and even more, and its surface is sometimes rusted
+to terra-cotta red. To a somewhat less depth it has been leached
+of its lime and other soluble ingredients. In the weathered zone
+its pebbles, especially where the till is loose in texture, are
+sometimes so rotted that granites may be crumbled with the
+fingers. The Kansan drift is therefore old.
+
+THE WISCONSIN FORMATION. The Wisconsin drift sheet is but little
+weathered and eroded, and therefore is extremely young. Oxidation
+has effected it but slightly, and lime and other soluble plant
+foods remain undissolved even at the grass roots. Its river
+systems are still in their infancy (Fig. 50, A). Swamps and peat
+bogs are abundant on its undrained surface, and to this drift
+sheet belong the lake lands of our northern states and of the
+Laurentian peneplain of Canada.
+
+The lake basins of the Wisconsin drift are of several different
+classes. Many are shallow sags in the ground moraine. Still more
+numerous are the lakes set in hollows among the hills of the
+terminal moraines; such as the thousands of lakelets of eastern
+Massachusetts. Indeed, the terminal moraines of the Wisconsin
+drift may often be roughly traced on maps by means of belts of
+lakes and ponds. Some lakes are due to the blockade of ancient
+valleys by morainic delms, and this class includes many of the
+lakes of the Adirondacks, the mountain regions of New England,
+and the Laurentian area. Still other lakes rest in rock basins
+scooped out by glaciers. In many cases lakes are due to more than
+one cause, as where preglacial valleys have both been basined by
+the ice and blockaded by its moraines. The Finger lakes of New
+York, for example, occupy such glacial troughs.
+
+Massive TERMINAL MORAINES, which mark the farthest limits to which
+the Wisconsin ice advanced, have been traced from Cape Cod and the
+islands south of New England, across the Appalachians and the
+Mississippi valley, through the Dakotas, and far to the north over
+the plains of British America. Where the ice halted for a time in
+its general retreat, it left RECESSIONAL MORAINES, as this variety
+of the terminal moraine is called. The moraines of the Wisconsin
+drift lie upon the country like great festoons, each series of
+concentric loops marking the utmost advance of broad lobes of the
+ice margin and the various pauses in their recession.
+
+Behind the terminal moraines lie wide till plains, in places
+studded thickly with drumlins, or ridged with an occasional esker.
+Great outwash plains of sand and gravel lie in front of the
+moraine belts, and long valley trains of coarse gravels tell of
+the swift and powerful rivers of the time.
+
+THE LOESS OF THE MISSISSIPPI VALLEY. A yellow earth, quite like
+the loess of China, is laid broadly as a surface deposit over the
+Mississippi valley from eastern Nebraska to Ohio outside the
+boundaries of the Iowan and the Wisconsin drift. Much of the loess
+was deposited in Iowan times. It is younger than the earlier drift
+sheets, for it overlies their weathered and eroded surfaces. It
+thickens to the Iowan drift border, but is not found upon that
+drift. It is older than the Wisconsin, for in many places it
+passes underneath the Wisconsin terminal moraines. In part the
+loess seems to have been washed from glacial waste and spread in
+sluggish glacial waters, and in part to have been distributed by
+the wind from plains of aggrading glacial streams.
+
+THE EFFECTS OF THE ICE INVASIONS ON RIVERS. The repeated ice
+invasions of the Pleistocene profoundly disarranged the drainage
+systems of our northern states. In some regions the ancient
+valleys were completely filled with drift. On the withdrawal of
+the ice the streams were compelled to find their way, as best they
+could, over a fresh land surface, where we now find them flowing
+on the drift in young, narrow channels. But hundreds of feet below
+the ground the well driller and the prospector for coal and oil
+discover deep, wide, buried valleys cut in rock,--the channels of
+preglacial and interglacial streams. In places the ancient valleys
+were filled with drift to a depth of a hundred feet, and sometimes
+even to a depth of four hundred and five hundred feet. In such
+valleys, rivers now flow high above their ancient beds of rock on
+floors of valley drift. Many of the valleys of our present rivers
+are but patchworks of preglacial, interglacial, and postglacial
+courses (Fig. 366). Here the river winds along an ancient valley
+with gently sloping sides and a wide alluvial floor perhaps a mile
+or so in width, and there it enters a young, rock-walled gorge,
+whose rocky bed may be crossed by ledges over which the river
+plunges in waterfalls and rapids.
+
+In such cases it is possible that the river was pushed to one side
+of its former valley by a lobe of ice, and compelled to cut a new
+channel in the adjacent uplands. A section of the valley may have
+been blockaded with morainic waste, and the lake formed behind the
+barrier may have found outlet over the country to one side of the
+ancient drift-filled valley. In some instances it would seem that
+during the waning of the ice sheets, glacial streams, while
+confined within walls of stagnant ice, cut down through the ice
+and incised their channels on the underlying country, in some
+cases being let down on old river courses, and in other cases
+excavating gorges in adjacent uplands.
+
+PLEISTOCENE LAKES. Temporary lakes were formed wherever the ice
+front dammed the natural drainage of the region. Some, held in the
+minor valleys crossed by ice lobes, were small, and no doubt many
+were too short-lived to leave lasting records. Others, long held
+against the northward sloping country by the retreating ice edge,
+left in their beaches their clayey beds, and their outlet channels
+permanent evidences of their area and depth. Some of these glacial
+lakes are thus known to have been larger than any present lake.
+
+Lake Agassiz, named in honor of the author of the theory of
+continental glaciation, is supposed to have been held by the
+united front of the Keewatin and the Labrador ice fields as they
+finally retreated down the valley of the Red River of the North
+and the drainage basin of Lake Winnipeg. From first to last Lake
+Agassiz covered a hundred and ten thousand square miles in
+Manitoba and the adjacent parts of Minnesota and North Dakota,--an
+area larger than all the Great Lakes combined. It discharged its
+waters across the divide which held it on the south, and thus
+excavated the valley of the Minnesota River. The lake bed--a plain
+of till--was spread smooth and level as a floor with lacustrine
+silts. Since Lake Agassiz vanished with the melting back of the
+ice beyond the outlet by the Nelson River into Hudson Bay, there
+has gathered on its floor a deep humus, rich in the nitrogenous
+elements so needful for the growth of plants, and it is to this
+soil that the region owes its well-known fertility.
+
+THE GREAT LAKES. The basins of the Great Lakes are broad
+preglacial river valleys, warped by movements of the crust still
+in progress, enlarged by the erosive action of lobes of the
+continental ice sheets, and blockaded by their drift. The
+complicated glacial and postglacial history of the lakes is
+recorded in old strand lines which have been traced at various
+heights about them, showing their areas and the levels at which
+their waters stood at different times.
+
+With the retreat of the lobate Wisconsin ice sheet toward the
+north and east, the southern and western ends of the basins of the
+Great Lakes were uncovered first; and here, between the receding
+ice front and the slopes of land which faced it, lakes gathered
+which increased constantly in size.
+
+The lake which thus came to occupy the western end of the Lake
+Superior basin discharged over the divide at Duluth down the St.
+Croix River, as an old outlet channel proves; that which held the
+southern end of the basin of Lake Michigan sent its overflow
+across the divide at Chicago via the Illinois River to the
+Mississippi; the lake which covered the lowlands about the western
+end of Lake Erie discharged its waters at Fort Wayne into the
+Wabash River.
+
+The ice still blocked the Mohawk and St. Lawrence valleys on the
+east, while on the west it had retreated far to the north. The
+lakes become confluent in wide expanses of water, whose depths and
+margins, as shown by their old lake beaches, varied at different
+times with the position of the confining ice and with warpings of
+the land. These vast water bodies, which at one or more periods
+were greater than all the Great Lakes combined, discharged at
+various times across the divide at Chicago, near Syracuse, New
+York, down the Mohawk valley, and by a channel from Georgian Bay
+into the Ottawa River. Last of all the present outlet by the St.
+Lawrence was established.
+
+The beaches of the glacial lakes just mentioned are now far from
+horizontal. That of the lake which occupied the Ontario basin has
+an elevation of three hundred and sixty-two feet above tide at the
+west and of six hundred and seventy-five feet at the northeast,
+proving here a differential movement of the land since glacial
+times amounting to more than three hundred feet. The beaches which
+mark the successive heights of these glacial lakes are not
+parallel; hence the warping began before the Glacial epoch closed.
+We have already seen that the canting of the region is still in
+progress.
+
+THE CHAMPLAIN SUBSIDENCE. As the Glacial epoch approached its end,
+and the Labrador ice field melted back for the last time to near
+its source, the land on which the ice had lain in eastern North
+America was so depressed that the sea now spread far and wide up
+the St. Lawrence valley. It joined with Lake Ontario, and
+extending down the Champlain and Hudson valleys, made an island of
+New England and the maritime provinces of Canada.
+
+The proofs of this subsidence are found in old sea beaches and
+sea-laid clays resting on Wisconsin till. At Montreal such
+terraces are found six hundred and twenty feet above sea level,
+and along Lake Champlain--where the skeleton of a whale was once
+found among them--at from five hundred to four hundred feet. The
+heavy delta which the Mohawk River built at its mouth in this arm
+of the sea now stands something more than three hundred feet above
+sea level. The clays of the Champlain subsidence pass under water
+near the mouth of the Hudson, and in northern New Jersey they
+occur two hundred feet below tide. In these elevations we have
+measures of the warping of the region since glacial times.
+
+THE WESTERN UNITED STATES IN GLACIAL TIMES. The western United
+States was not covered during the Pleistocene by any general ice
+sheet, but all the high ranges were capped with permanent snow and
+nourished valley glaciers, often many times the size of the
+existing glaciers of the Alps. In almost every valley of the
+Sierras and the Rockies the records of these vanished ice streams
+may be found in cirques, glacial troughs, roches moutonnecs, and
+morainic deposits.
+
+It was during the Glacial epoch that Lakes Bonneville and Lahontan
+were established in the Great Basin, whose climate must then have
+been much more moist than now.
+
+THE DRIFTLESS AREA. In the upper Mississippi valley there is an
+area of about ten thousand square miles in southwestern Wisconsin
+and the adjacent parts of Iowa and Minnesota, which escaped the
+ice invasions. The rocks are covered with residual clays, the
+product of long preglacial weathering. The region is an ancient
+peneplain, uplifted and dissected in late Tertiary times, with
+mature valleys whose gentle gradients are unbroken by waterfalls
+and rapids. Thus the driftless area is in strong contrast with the
+immature drift topography about it, where lakes and waterfalls are
+common. It is a bit of preglacial landscape, showing the condition
+of the entire region before the Glacial epoch.
+
+The driftless area lay to one side of the main track of both the
+Keewatin and the Labrador ice fields, and at the north it was
+protected by the upland south of Lake Superior, which weakened and
+retarded the movement of the ice.
+
+South of the driftless area the Mississippi valley was invaded at
+different times by ice sheets from the west,--the Kansan and the
+Iowan,--and again by the Illinoian ice sheet from the east. Again
+and again the Mississippi River was pushed to one side or the
+other of its path. The ancient channel which it held along the
+Illinoian ice front has been traced through southeastern Iowa for
+many miles.
+
+BENEFITS OF GLACIATION. Like the driftless area, the preglacial
+surface over which the ice advanced seems to have been well
+dissected after the late Tertiary uplifts, and to have been carved
+in many places to steep valley slopes and rugged hills. The
+retreating ice sheets, which left smooth plains and gently rolling
+country over the wide belt where glacial deposition exceeded
+glacial erosion, have made travel and transportation easier than
+they otherwise would have been.
+
+The preglacial subsoils were residual clays and sands, composed
+of the insoluble elements of the country rock of the locality,
+with some minglings of its soluble parts still undissolved. The
+glacial subsoils are made of rocks of many kinds, still undecayed
+and largely ground to powder. They thus contain an inexhaustible
+store of the mineral foods of plants, and in a form
+made easily ready for plant use.
+
+On the preglacial hillsides the humus layer must have been
+comparatively thin, while the broad glacial plains have gathered
+deep black soils, rich in carbon and nitrogen taken from the
+atmosphere. To these soils and subsoils a large part of the wealth
+and prosperity of the glaciated regions of our country must be
+attributed.
+
+The ice invasions have also added very largely to the water power
+of the country. The rivers which in preglacial times were flowing
+over graded courses for the most part, were pushed from their old
+valleys and set to flow on higher levels, where they have
+developed waterfalls and rapids. This power will probably be fully
+utilized long before the coal beds of the country are exhausted,
+and will become one of the chief sources of the national wealth.
+
+THE RECENT EPOCH. The deposits laid since glacial times graduate
+into those now forming along the ocean shores, on lake beds, and
+in river valleys. Slow and comparatively slight changes, such as
+the warpings of the region of the Great Lakes, have brought about
+the geographical conditions of the present. The physical history
+of the Recent epoch needs here no special mention.
+
+THE LIFE OF THE QUATERNARY
+
+During the entire Quaternary, invertebrates and plants suffered
+little change in species,--so slowly are these ancient and
+comparatively simple organisms modified. The Mammalia, on the
+other hand, have changed much since the beginning of Quaternary
+time: the various species of the present have been evolved, and
+some lines have become extinct. These highly organized vertebrates
+are evidently less stable than are lower types of animals, and
+respond more rapidly to changes in the environment.
+
+PLEISTOCENE MAMMALS. In the Pleistocene the Mammalia reached their
+culmination both in size and in variety of forms, and were
+superior in both these respects to the mammals of to-day. In
+Pleistocene times in North America there were several species of
+bison,--one whose widespreading horns were ten feet from tip to
+tip,--a gigantic moose elk, a giant rodent (Castoroides) five feet
+long, several species of musk oxen, several species of horses,--
+more akin, however, to zebras than to the modern horse,--a huge
+lion, several saber-tooth tigers, immense edentates of several
+genera, and largest of all the mastodon and mammoth.
+
+The largest of the edentates was the Megatherium, a. clumsy ground
+sloth bigger than a rhinoceros. The bones of the Megatherium are
+extraordinarily massive,--the thigh bone being thrice as thick as
+that of an elephant,--and the animal seems to have been well able
+to get its living by overthrowing trees and stripping off their
+leaves. The Glyptodon was a mailed edentate, eight feet long,
+resembling the little armadillo. These edentates survived from
+Tertiary times, and in the warmer stages of the Pleistocene ranged
+north as far as Ohio and Oregon.
+
+The great proboscidians of the Glacial epoch were about the size
+of modern elephants, and somewhat smaller than their ancestral
+species in the Pliocene. The MASTODON ranged over all North
+America south of Hudson Bay, but had become extinct in the Old
+World at the end of the Tertiary. The elephants were represented
+by the MAMMOTH, which roamed in immense herds from our middle
+states to Alaska, and from Arctic Asia to the Mediterranean and
+Atlantic.
+
+It is an oft-told story how about a century ago, near the Lena
+River in Siberia, there was found the body of a mammoth which had
+been safely preserved in ice for thousands of years, how the flesh
+was eaten by dogs and bears, and how the eyes and hoofs and
+portions of the hide were taken with the skeleton to St.
+Petersburg. Since then several other carcasses of the mammoth,
+similarly preserved in ice, have been found in the same region,--
+one as recently as 1901. We know from these remains that the
+animal was clothed in a coat of long, coarse hair, with thick
+brown fur beneath.
+
+THE DISTRIBUTION OF ANIMALS AND PLANTS. The distribution of
+species in the Glacial epoch was far different from that of the
+present. In the glacial stages arctic species ranged south into
+what are now temperate latitudes. The walrus throve along the
+shores of Virginia and the musk ox grazed in Iowa and Kentucky. In
+Europe the reindeer and arctic fox reached the Pyrenees. During
+the Champlain depression arctic shells lived along the shore of
+the arm of the sea which covered the St. Lawrence valley. In
+interglacial times of milder climate the arctic fauna-flora
+retreated, and their places were taken by plants and animals from
+the south. Peccaries, now found in Texas, ranged into Michigan and
+New York, while great sloths from South America reached the middle
+states. Interglacial beds at Toronto, Canada, contain remains of
+forests of maple, elm, and papaw, with mollusks now living in the
+Mississippi basin.
+
+What changes in the forests of your region would be brought about,
+and in what way, if the climate should very gradually grow colder?
+What changes if it should grow warmer?
+
+On the Alps and the highest summits of the White Mountains of New
+England are found colonies of arctic species of plants and
+insects. How did they come to be thus separated from their home
+beyond the arctic circle by a thousand miles and more of temperate
+climate impossible to cross?
+
+MAN. Along with the remains of the characteristic animals of the
+time which are now extinct there have been found in deposits of
+the Glacial epoch in the Old World relics of Pleistocene MAN, his
+bones, and articles of his manufacture. In Europe, where they have
+best been studied, human relics occur chiefly in peat bogs, in
+loess, in caverns where man made his home, and in high river
+terraces sometimes eighty and a hundred feet above the present
+flood plains of the streams.
+
+In order to understand the development of early man, we should
+know that prehistoric peoples are ranked according to the
+materials of which their tools were made and the skill shown in
+their manufacture. There are thus four well-marked stages of human
+culture preceding the written annals of history:
+
+    4 The Iron stage.
+    3 The Bronze stage.
+    2 The Neolithic (recent stone) stage.
+    1 The Paleolithic (ancient stone) stage.
+
+In the Neolithic stage the use of the metals had not yet been
+learned, but tools of stone were carefully shaped and polished. To
+this stage the North American Indian belonged at the time of the
+discovery of the continent. In the Paleolithic stage, stone
+implements were chipped to rude shapes and left unpolished. This,
+the lowest state of human culture, has been outgrown by nearly
+every savage tribe now on earth. A still earlier stage may once
+have existed, when man had not learned so much as to shape his
+weapons to his needs, but used chance pebbles and rock splinters
+in their natural forms; of such a stage, however, we have no
+evidence.
+
+PALEOLITHIC MAN IN EUROPE. It was to the Paleolithic stage that
+the earliest men belonged whose relics are found in Europe. They
+had learned to knock off two-edged flakes from flint pebbles, and
+to work them into simple weapons. The great discovery had been
+made that fire could be kindled and made use of, as the charcoal
+and the stones discolored by heat of their ancient hearths attest.
+Caves and shelters beneath overhanging cliffs were their homes or
+camping places. Paleolithic man was a savage of the lowest type,
+who lived by hunting the wild beasts of the time.
+
+Skeletons found in certain caves in Belgium and France represent
+perhaps the earliest race yet found in Europe. These short, broad-
+shouldered men, muscular, with bent knees and stooping gait, low-
+browed and small of brain, were of little intelligence and yet
+truly human.
+
+The remains of Pleistocene man are naturally found either in
+caverns, where they escaped destruction by the ice sheets, or in
+deposits outside the glaciated area. In both cases it is extremely
+difficult, or quite impossible, to assign the remains to definite
+glacial or interglacial times. Their relative age is best told by
+the fauna with which they are associated. Thus the oldest relics
+of man are found with the animals of the late Tertiary or early
+Quaternary, such as a species of hippopotamus and an elephant more
+ancient than the mammoth. Later in age are the remains found along
+with the mammoth, cave bear and cave hyena, and other animals of
+glacial time which are now extinct; while more recent still are
+those associated with the reindeer, which in the last ice invasion
+roamed widely with the mammoth over central Europe.
+
+THE CAVES OF SOUTHERN FRANCE. These contain the fullest records of
+the race, much like the Eskimos in bodily frame, which lived in
+western Europe at the time of the mammoth and the reindeer. The
+floors of these caves are covered with a layer of bone fragments,
+the remains of many meals, and here are found also various
+articles of handicraft. In this way we know that the savages who
+made these caves their homes fished with harpoons of bone, and
+hunted with spears and darts tipped with flint and horn. The
+larger bones are split for the extraction of the marrow. Among
+such fragments no split human bones are found; this people,
+therefore, were not cannibals. Bone needles imply the art of
+sewing, and therefore the use of clothing, made no doubt of skins;
+while various ornaments, such as necklaces of shells, show how
+ancient is the love of personal adornment. Pottery was not yet
+invented. There is no sign of agriculture. No animals had yet been
+domesticated; not even man's earliest friend, the dog. Certain
+implements, perhaps used as the insignia of office, suggest a rude
+tribal organization and the beginnings of the state. The remains
+of funeral feasts in front of caverns used as tombs point to a
+religion and the belief in a life beyond the grave. In the caverns
+of southern France are found also the beginnings of the arts of
+painting and of sculpture. With surprising skill these Paleolithic
+men sketched on bits of ivory the mammoth with his long hair and
+huge curved tusks, frescoed their cavern walls with pictures of
+the bison and other animals, and carved reindeer on their dagger
+heads.
+
+EARLY MAN ON OTHER CONTINENTS. Paleolithic flints curiously like
+those of western Europe are found also in many regions of the Old
+World,--in India, Egypt, and Asia Minor,--beneath the earliest
+vestiges of the civilization of those ancient seats, and sometimes
+associated with the fauna of the Glacial epoch.
+
+In Java there were found in 1891, in strata early Quaternary or
+late Pliocene in age, parts of a skeleton of lower grade, if not
+of greater antiquity, than any human remains now known.
+Pithecanthropus erectus, as the creature has been named, walked
+erect, as its thigh bone shows, but the skull and teeth indicate a
+close affinity with the ape.
+
+In North America there have been reported many finds of human
+relics in valley trains, loess, old river gravels buried beneath
+lava flows, and other deposits of supposed glacial age; but in the
+opinion of some geologists sufficient proof of the existence of
+man in America in glacial times has not as yet been found.
+
+These finds in North America have been discredited for various
+reasons. Some were not made by scientific men accustomed to the
+closest scrutiny of every detail. Some were reported after a
+number of years, when the circumstances might not be accurately
+remembered; while in a number of instances it seems possible that
+the relics might have been worked into glacial deposits by natural
+causes from the surface.
+
+Man, we may believe, witnessed the great ice fields of Europe, if
+not of America, and perhaps appeared on earth under the genial
+climate of preglacial times. Nothing has yet been found of the
+line of man's supposed descent from the primates of the early
+Tertiary, with the possible exception of the Java remains just
+mentioned. The structures of man's body show that he is not
+descended from any of the existing genera of apes. And although he
+may not have been exempt from the law of evolution,--that method
+of creation which has made all life on earth akin,--yet his
+appearance was an event which in importance ranks with the advent
+of life upon the planet, and marks a new manifestation of creative
+energy upon a higher plane. There now appeared intelligence,
+reason, a moral nature, and a capacity for self-directed progress
+such as had never been before on earth.
+
+THE RECENT EPOCH. The Glacial epoch ends with the melting of the
+ice sheets of North America and Europe, and the replacement of the
+Pleistocene mammalian fauna by present species. How gradually the
+one epoch shades into the other is seen in the fact that the
+glaciers which still linger in Norway and Alaska are the lineal
+descendants or the renewed appearances of the ice fields of
+glacial times.
+
+Our science cannot foretell whether all traces of the Great Ice
+Age are to disappear, and the earth is to enjoy again the genial
+climate of the Tertiary, or whether the present is an interglacial
+epoch and the northern lands are comparatively soon again to be
+wrapped in ice.
+
+NEOLITHIC MAN. The wild Paleolithic men vanished from Europe with
+the wild beasts which they hunted, and their place was taken by
+tribes, perhaps from Asia, of a higher culture. The remains of
+Neolithic man are found, much as are those of the North American
+Indians, upon or near the surface, in burial mounds, in shell
+heaps (the refuse heaps of their settlements), in peat bogs,
+caves, recent flood-plain deposits, and in the beds of lakes near
+shore where they sometimes built their dwellings upon piles.
+
+The successive stages in European culture are well displayed in
+the peat bogs of Denmark. The lowest layers contain the polished
+STONE implements of Neolithic man, along with remains of the
+SCOTCH FIR. Above are OAK trunks with implements of BRONZE, while
+the higher layers hold iron weapons and the remains of a BEECH
+forest.
+
+Neolithic man in Europe had learned to make pottery, to spin and
+weave linen, to hew timbers and build boats, and to grow wheat and
+barley. The dog, horse, ox, sheep, goat, and hog had been
+domesticated, and, as these species are not known to have existed
+before in Europe, it is a fair inference that they were brought by
+man from another continent of the Old World. Neolithic man knew
+nothing of the art of extracting the metals from their ores, nor
+had he a written language.
+
+The Neolithic stage of culture passes by insensible gradations
+into that of the age of bronze, and thus into the Recent epoch.
+
+In the Recent epoch the progress of man in language, in social
+organization, in the arts of life, in morals and religion, has
+left ample records which are for other sciences than ours to read;
+here, therefore, geology gives place to archaeology and history.
+
+Our brief study of the outlines of geology has given us, it is
+hoped, some great and lasting good. To conceive a past so
+different from the present has stimulated the imagination, and to
+follow the inferences by which the conclusions of our science have
+been reached has exercised one of the noblest faculties of the
+mind,--the reason. We have learned to look on nature in new ways:
+every landscape, every pebble now has a meaning and tells
+something of its origin and history, while plants and animals have
+a closer interest since we have traced the long lines of their
+descent. The narrow horizons of human life have been broken
+through, and we have caught glimpses of that immeasurable reach of
+time in which nebulae and suns and planets run their courses.
+Moreover, we have learned something of that orderly and world-
+embracing progress by which the once uninhabitable globe has come
+to be man's well-appointed home, and life appearing in the
+lowliest forms has steadily developed higher and still higher
+types. Seeing this process enter human history and lift our race
+continually to loftier levels, we find reason to believe that the
+onward, upward movement of the geological past is the
+manifestation of the same wise Power which makes for righteousness
+and good and that this unceasing purpose will still lead on to
+nobler ends.
+
+
+End of the Project Gutenberg Etext of The Elements of Geology, by W. H. Norton
+
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