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+*** START OF THE PROJECT GUTENBERG EBOOK 78317 ***
+
+
+
+
+Transcriber’s Notes:
+
+ Underscores “_” before and after a word or phrase indicate _italics_
+ in the original text.
+ Equal signs “=” before and after a word or phrase indicate =bold=
+ in the original text.
+ Small capitals have been converted to SOLID capitals.
+ Illustrations and footnotes have been moved so they do not break up
+ paragraphs.
+ Deprecated spellings have been preserved.
+ Typographical and punctuation errors have been silently corrected.
+
+
+
+
+THE SOIL SOLUTION
+
+
+
+
+ Published by
+ The Chemical Publishing Co.
+ Easton, Penna.
+ Publishers of Scientific Books
+
+ Engineering Chemistry Portland Cement
+ Agricultural Chemistry Qualitative Analysis
+ Household Chemistry Chemists’ Pocket Manual
+ Metallurgy, Etc.
+
+
+
+
+ The Soil Solution
+
+ The Nutrient Medium for Plant Growth
+
+ By
+ FRANK K. CAMERON
+
+ In Charge, Physical and Chemical Investigations,
+ Bureau of Soils,
+ U. S. Department of Agriculture
+
+ EASTON, PA.:
+ THE CHEMICAL PUBLISHING CO.
+ 1911
+
+ LONDON, ENGLAND:
+ WILLIAMS & NORGATE
+ 14 HENRIETTA STREET, COVENT GARDEN, W. C.
+
+ COPYRIGHT, 1911, BY EDWARD HART
+
+
+
+
+Preface.
+
+
+It has long been the custom to regard soil chemistry from one of two
+diametrically opposed points of view. Either, it has been considered
+extremely simple, or complex and hopelessly difficult. In either case
+the impression has generally prevailed that practical work in soil
+chemistry consists in treating the soil with some solvent or other and
+analyzing the resulting solution for “available” plant food elements;
+in other words, that the chemist’s role in soil studies is merely that
+of an analyst.
+
+Soil chemistry is complex, but not by any means hopelessly so.
+Unfortunately, the complexity of most of the problems presented has
+deterred the student of pure chemistry from attacking them, and
+because they do not offer any material pecuniary rewards, they have
+not appealed strongly to the investigator in applied chemistry.
+Investigations in soil chemistry, for their own sake, or for the sole
+purpose of increasing the sum total of human knowledge concerning the
+phenomena taking place in the soil, have been comparatively rare. The
+subject has generally been regarded from the analytical point of view
+and as incidental to agronomic studies.
+
+One purpose of this little book is to show the investigator in
+chemistry who is not limited by the condition that his work must bring
+some personal financial return, that the soil and its problems offer
+a field for his efforts quite worthy of ranking along-side the most
+interesting branches of pure chemistry, as well as being of the very
+highest importance to the development of the welfare of the human race.
+Another purpose is to point out the line of attack upon the problems of
+soil chemistry which at this time offers the largest opportunity for
+results. In how far the details of the story in the following pages are
+correct, time with its further investigations will tell. In a sense,
+the correctness of the details is of secondary importance. It is of the
+first importance, however, that there should be a general recognition
+that soil phenomena are essentially dynamic in character, and that the
+investigation of the properties of the soil solution and its relation
+to crop production is a procedure certain to yield results of positive
+value.
+
+Again, it is a purpose of this book to make available for students
+of agriculture, a systematic outline of the work so far accomplished
+in this particular field. It is to the students of to-day from whom
+are to come the investigations of the near future that the book is
+particularly addressed. Some of the details presented in the following
+pages are matters on which opposed opinions are now held strongly
+by different authorities, and to the unbiased minds of the coming
+investigators must be left the decision as to how closely the truth
+has been approximated in what is written to-day. The field of effort
+covered by this book is one in which there is an increasing activity,
+and new facts and deductions will inevitably bring modifications to
+present opinions. To encourage this further acquisition of knowledge is
+the main purpose of the book.
+
+The material brought together in this book has been presented to the
+faculties and students of several of our Agricultural Colleges, in the
+form of a short course of lectures. In large part, moreover, it has
+been published in Volume XIV of the Journal of Physical Chemistry. To
+make it accessible to and more easily read by one familiar with the
+progress of technical soil investigations, it has been recast in its
+present form.
+
+It has been assumed that the reader will have a fair working knowledge
+of the concepts of modern chemistry. Nevertheless, an effort has been
+made to avoid technical terms so far as this can be done without undue
+sacrifice of lucidity of expression. Free references have been made to
+the bulletins of the Bureau of Soils, U. S. Department of Agriculture,
+because they are generally accessible to the American student, and
+because in them will be found detailed discussions and bibliographical
+material pertinent to the subjects outlined here. To his coworkers,
+the author is indebted for many criticisms and suggestions; and more
+especially in the making of the book is he indebted to Mr. S. C. Stuntz.
+
+ Washington, D. C.
+ 1911.
+
+
+
+
+ Table of Contents.
+ PAGE
+ Preface iii
+ I. The Soil 1
+ II. Soil Management or Control 4
+ III. Soil Analysis and the Historical Methods of Soil
+ Investigation 8
+ IV. The Plant-Food Theory of Fertilizers 16
+ V. The Dynamic Nature of Soil Phenomena 18
+ VI. The Film Water 24
+ VII. The Mineral Constituents of the Soil Solution 31
+ VIII. Absorption by Soils 59
+ IX. The Relation of Plant Growth to Concentration 70
+ X. The Balance Between Supply and Removal of Mineral
+ Plant Nutrients 75
+ XI. The Organic Constituents of the Soil Solution 79
+ XII. Fertilizers 105
+ XIII. Alkali 110
+ Index 127
+
+
+
+
+AN INTRODUCTION TO THE STUDY OF THE SOIL SOLUTION.
+
+
+
+
+Chapter I.
+
+THE SOIL.
+
+
+The soil, or that part of the land surface of the earth adapted to
+the growth and support of crops, is a heterogeneous mixture composed
+of solids, gases and a liquid, and containing living organisms. There
+are present: mineral debris from rock degradation and decomposition;
+organic matter from the degradation and decomposition of former plant
+and animal tissues; the soil atmosphere, always richer in carbon
+dioxide and water vapor and possibly other gases than the atmosphere
+above the soil; living organisms, such as various kinds of bacteria and
+fungi, with the products of their activities, notably the “nitrogen
+carriers” and the enzymes; and finally the soil moisture, a solution
+of products yielded by the above components and in equilibrium or
+approaching equilibrium with the solids and gases with which it is in
+contact.
+
+In its relation to crop plants,[1] that part of the soil of immediate
+importance is the soil moisture. From this solution the plants, through
+their roots, draw all the material involved in their growth, except
+the carbon dioxide absorbed through their leaves. The soil solution is
+the natural nutrient medium from which the plants absorb the mineral
+constituents which have been shown to be absolutely essential to their
+continued existence and development. And from this solution plants
+sometimes absorb dissolved organic substances, but such absorptions
+are probably adventitious and incidental to the growth of the plant in
+a particular environment. While it appears certain that no organic
+substance in the nutrient medium is necessary to the maintenance of
+plant growth, nevertheless organic substances are probably always
+present under natural conditions. They may or may not be absorbed by
+the plant and may affect it beneficially or otherwise.
+
+[1] By crop plants are meant the ordinary green plants employed in
+agriculture. As is well-known, the fungi as well as certain parasitic
+and saprophytic non-green seed plants obtain their nutriment in a very
+different way from ordinary green crop plants.
+
+The study of the soil solution is of the first importance in the
+investigation of the relation of the soil to plant growth, and in the
+following pages there is given an outline of our present knowledge of
+the chemical principles involved, with such discussion of the physical
+and biological factors as is essential to an orderly presentation of
+the subject.
+
+To understand clearly the relations of the soil solution to the soil
+as a whole and to the plant which it nourishes, it is desirable to
+consider some attributes of soils in general. Every soil, no matter
+of what type it may be, is a complex system. In it various processes
+are continually in operation, excepting possibly in the extreme case
+when it remains frozen for a time at some definite temperature. The
+resultant or summation of these processes, whether expressed in
+plant production or otherwise, will vary from time to time, both
+quantitatively and in direction; for instance, as to the amount and
+kinds of plant growth it produces. That is to say, any particular
+soil area is seemingly an organic entity, functioning according to
+its own inherent properties, but subject to the modifying influences
+of environment, as by exceptional climatic extremes, flood, fire, and
+especially by artificially imposed agencies of control.
+
+From the practical point of view the problem of the soil in its
+relation to crop production is like the problem of the factory or of
+any other industrial endeavor, in that it is a problem of management
+or control. The soil possesses this distinction, however, that it
+is both the raw material and the factory.[2] The processes involved
+are physical, chemical and biological, are always numerous and
+interdependent, and are never (speaking generally) exactly the same,
+so that each soil possesses marked individuality. No matter how soils
+may be classified, as for instance into provinces, series and types,[3]
+the fact remains that the soil of the individual field has properties
+which give it a crop-producing power, an adaptation to a specific
+crop or crop rotation, or a responsiveness to cultural treatment,
+which can not be anticipated in any other field. Consequently, there
+is no possibility of reducing soil management or agriculture to the
+state of an exact science. That is to say, scientific investigation of
+the problems involved cannot be expected to yield absolute results,
+although furnishing the best possible basis on which to form judgments.
+Soil management, like other agricultural practices, is an art, more or
+less well founded on scientific principles, perhaps, but susceptible of
+much higher development as the scientific principles involved become
+better understood.
+
+[2] According to S. W. Johnson—Some points of agricultural science, Am.
+Jour. Sci. (2), =28=, 71-85 (1859)—“The soil (speaking in the widest
+sense) is then not only the ultimate exhaustless source of mineral
+(fixed) food, to vegetation, but it is the storehouse and conservatory
+of this food, protecting its own resources from waste and from too
+rapid use, and converting the highly soluble matters of animal exuviæ
+as well as of artificial refuse (manures) into permanent supplies.”
+
+[3] For definitions, see Soil Survey Field Book, 1906, Bureau of
+Soils, U. S. Dept. of Agriculture, pp. 15-24. On the ground that
+experience has shown that genetic classifications are the ones which
+have generally persisted and proved the most useful, objection might be
+made to the classification just cited. But a careful inspection of the
+results of the Soil Survey by the U. S. Department of Agriculture will
+show that while not categorically stating the fact, to all intents and
+purposes it has employed a genetic classification. This is exemplified
+by the fact that its delineation of soil provinces corresponds quite
+closely with the recognized physiographic provinces of the United
+States. See map accompanying Soils of the United States, by Milton
+Whitney, Bull. No. =55= Bureau of Soils, U. S. Dept. Agriculture, 1909.
+
+
+
+
+Chapter II.
+
+SOIL MANAGEMENT OR CONTROL.
+
+
+Aside from such devices as greenhouses, wind-breaks, etc., which have
+a local application only, there are three general methods of soil
+control: tillage methods, such as plowing and harrowing; rotation of
+crops; and the use of soil amendments or “fertilizers.”
+
+The existing knowledge regarding tillage methods is generally
+considered to be fairly satisfactory. The purposes are well understood,
+namely, to break up and “fine” the soil,[4] to keep down weeds, and by
+forming mulches to decrease the loss of water by evaporation. Not much
+increase is being made in our theoretical knowledge of this subject,
+although mechanical improvements in the implements of tillage are being
+and will undoubtedly continue to be made.
+
+[4] Actually, to granulate the soil. “Fine” would seem to be a
+misnomer, but its agricultural significance is well understood, and it
+has the sanction of long usage in the literature.
+
+The existing knowledge concerning crop rotations is fairly extensive,
+but it is almost entirely empirical. Some at least of the purposes
+served by a rotation of crops are fairly well known, such as the
+elimination of weeds or lower types of parasitic growth associated
+with particular crops; the introduction of humus by a grass crop or a
+green manure crop, especially by the _Leguminosae_ with their symbiotic
+_Azobacteria_; the improvement in the structure or arrangement of the
+soil particles by alternating deep-rooted and shallow-rooted crops;
+the avoidance of continually growing a crop in the presence of its
+own excreta, products of decay, etc.; and lastly, economic and market
+considerations.
+
+The existing knowledge of fertilizers, in spite of a vast amount of
+work and an enormous literature, is still very meagre and it also is
+almost entirely empirical; and this because studies on the subject have
+been dominated for three-quarters of a century by one theory almost to
+the exclusion of any other. The exponents of this theory have generally
+assumed that the action of fertilizers is on the plant rather than on
+the soil, and is independent of other factors. That is, while it is
+admitted that other factors influence plant growth, it has been held
+that the effect of the fertilizer is not to modify the influence of
+the other factors but to directly influence the plant by increasing
+its food supply. As a consequence, it has also been generally assumed
+that the influence of fertilizers is additive, that is, the increase
+in yield of crop is proportional to the increase in fertilizer added,
+and the increase in yield produced by adding two fertilizers is the
+sum of the increases which would have been produced by each alone. In
+this form the theory is essentially a quantitative one, and fertilizer
+practice should be easily susceptible of control by chemical analyses.
+But the large mass of data obtained from plot experiments shows that
+fertilizer effects are not additive. Indeed, the addition of some one
+or more fertilizer constituent is sometimes followed by a decreased
+yield. For example, about 20 per cent. of the trials of fertilizers
+on soils growing corn and reported by the American State Experiment
+Stations show a decreased yield. And furthermore, in spite of the
+quantitative character of the theory, and the numerous analyses
+of soils and of plants which have been made, there is yet lacking
+any authoritative method for determining in quantitative terms the
+fertilizer needs of a soil. That analytical methods have a very
+restricted value in indicating even qualitatively the fertilizer needs
+of the soil is evidenced by the fact that within the past few years a
+number of the State Experiment Stations have publicly announced their
+unwillingness to undertake them.[5]
+
+[5] In this connection see: The texture of the soil, by L. H. Bailey,
+Cornell University Agr. Expt. Sta., Bull. No. =119= (1896); Suggestions
+regarding the examination of lands, by E. W. Hilgard, University of
+California, College of Agriculture, Circ. No. =25=, (1906); Chemical
+analysis of soils, by William P. Brooks, Massachusetts Agr. Expt. Sta.
+Circ. No. =11=, (1907); Testing soils for fertilizer needs, by F. W.
+Taylor, New Hampshire Agr. Expt. Sta., Circ. No. =2=, (1908); The uses
+and limitations of soil analysis, by J. T. Willard, The Industrialist.
+Kansas State Agricultural College, =34=, 291, (1908); Soil analysis,
+by Wm. Frear, Pennsylvania Agr. Expt. Sta., Chem. Circ. No. =1=; How
+to determine the fertilizer requirements of Ohio soils, by Chas. E.
+Thorne, Ohio Agr. Expt. Sta., Circ. No. =79=, (1908); Concerning work
+which the station can and cannot undertake for residents of the state,
+by Joseph L. Hills, Vermont Agr. Expt. Sta., Circ. No. =3=, (1909).
+
+The common procedure has been to define some arbitrary percentage limit
+in the soil, below which the soil is supposed to require fertilizers.
+But the amount of fertilizer to be applied is suggested on the
+indefinite basis of “experience.” Thus, Hilgard, in an interesting
+discussion of this subject,[6] quotes Dyer as showing that “on
+Rothamsted soils of known productiveness or manurial condition, it
+appears that when the citric acid extraction yields as much as 0.005
+per cent. of potash and 0.010 per cent. of phosphoric acid, the supply
+is adequate for normal crop production, so that the use of the above
+substances as fertilizers would be, if not ineffective, at least not
+a profitable investment.” Hilgard himself sets limits as determined
+by strong hydrochloric acid digestion; thus a soil containing upwards
+of 0.45 per cent. (K₂O) does not need this substance as a fertilizer,
+while one containing below 0.25 per cent. does need it at once, and
+intermediate percentages indicate that potash fertilizers would
+probably be profitable; the corresponding upper and lower limits for
+phosphoric acid are set at 0.10 per cent. and 0.05 per cent. But
+Hilgard points out that various things, such as the content of lime,
+or the texture of the soil, may materially alter these limits. In a
+very interesting set of experiments in which white mustard was grown
+in various soils, and these same soils diluted with various amounts of
+dune sand which had previously been extracted with strong hydrochloric
+acid, he found that the plants did best when the soils had been diluted
+with four times their weight of the extracted sand. This was the case
+even with a pulverulent sandy loam; and with a black adobe, the best
+results were obtained when the diluted soil contained but 0.15 per
+cent. potash (K₂O) and 0.04 per cent. phosphoric acid (P₂O₅). It also
+appears that Hilgard regards soil analyses of value only in the case of
+virgin soils or soils which have been out of cultivation, and in common
+with other authorities, he fails to point out how to determine the
+_amount_ of fertilizer needed by lands.
+
+[6] Soils by E. W. Hilgard, 1906, p. 339, _et seq._
+
+It is clear, therefore, that the principles underlying the practice or
+art of soil management and crop rotation are in a state of development
+far from satisfactory, and scientific methods of soil control yet
+wanting.[7] Recent activities in soil investigations, however,
+justify the hope that much improvement is to be anticipated, and the
+application of the modern methods of physical, chemical, and biological
+research to the soil problem promises a sure and probably rapid advance
+in this branch of applied science.
+
+[7] It should, of course, be borne in mind that soil factors are not
+the only ones in crop production. Control by seed selection, breeding
+of standard types of plants, etc., may be, and probably is, more highly
+developed than control by soil factors. The same might possibly be
+claimed for moisture supply in irrigated areas; but on the other hand,
+such factors as the bacterial and lower life processes in the soil are
+generally under little or no control, and as a rule the amount and
+distribution of sunlight under none at all. A notable effort has been
+made in the last case with shade-grown tobacco (see Bulletins Nos. 20
+and 39, Bureau of Soils, U. S. Dept. Agriculture) and a few cases are
+known where shade-crops are employed, but not in general agriculture.
+
+
+
+
+Chapter III.
+
+SOIL ANALYSIS AND THE HISTORICAL METHODS OF SOIL INVESTIGATION.
+
+
+Owing to the labors of Davy, Boussingault, de Saussure, Liebig, Sachs,
+Knop, Salm-Horstmar, and other scarcely less distinguished savants,
+it has been clearly shown that _growing plants need certain mineral
+elements in order to maintain their metabolic functions_, and that
+_these mineral elements can be obtained, under normal conditions, from
+the soil_. All subsequent investigation has confirmed these statements
+and they can now be accepted as facts with as much assurance as any
+known law of nature.
+
+The determination and formulation of these two fundamental facts came
+at a time when analytical chemistry was being rapidly developed and was
+finding wide and useful applications in numerous fields of activity. It
+was natural, therefore, that analytical chemistry should be enlisted
+in this new field of work, obviously of the first importance to the
+welfare of mankind. It was early found, however, that the chemical
+analysis of a soil fails to explain its relative productivity. In
+other words the content of a soil with respect to potash, phosphoric
+acid, or other mineral plant-food constituent, bears no necessary
+relation to its crop-producing power. Many cases were found where one
+soil “analyzed well” but did not produce as large a crop as another
+soil which “analyzed poor.”[8] To meet this difficulty a subsidiary
+hypothesis was brought forward, which rapidly gained general acceptance
+although lacking experimental support.
+
+[8] See also, Die Aufnahme der Nährstoffe aus dem Boden durch die
+Pflanzen, von J. König und E. Haselhoff, Landw. Jahrb., 23, 1009, 1030,
+(1894).
+
+This hypothesis supposes that the mineral constituents of the soil
+are present in two different chemical conditions or distinct kinds
+of combinations, one of which readily gives up its constituents to
+growing plants, while the other does not; and the constituents have,
+therefore, been called respectively “available” and “non-available.”
+It would appear from his writings that Liebig regarded this distinction
+as applying to the “absorbed” or “adsorbed” mineral matter; that
+is, on the one hand the material held in or upon the soil grains by
+surface forces, and on the other the chemically combined constituents
+in the minerals themselves. We know that Liebig was much impressed by
+the absorption experiments of Way, and himself did much work in this
+field.[9] But the great body of soil investigators has evidently held
+to the opinion that there are two general classes of minerals in the
+soil. Some have held that the “available” potassium is held in zeolites
+or “zeolitic” minerals, an interesting example often cited being
+glauconite or “green sand marl,” which sometimes contains phosphorus
+as well as potassium;[10] in minerals which are easily broken down by
+alkaline solutions, as by sodium carbonate solutions or ammonia; or
+in minerals which are easily broken down by organic acids supposedly
+excreted from the roots of growing plants, or formed by the decay of
+plant tissue.[11]
+
+[9] Way was misled, as we now know, in considering the results of his
+absorption experiments with soils as merely metathetical reactions; see
+Absorption by soils, by Harrison E. Patten and William H. Waggaman,
+Bull. No. =52=, Bureau of Soils, U. S. Dept. Agriculture, 1908.
+
+[10] The formation of zeolites in the soil has often been assumed,
+but has not yet been proven; see Rocks, rock-weathering and soils, by
+George P. Merrill, 1906, p. 363.
+
+[11] The classic experiments of Sachs, in producing etchings on marble
+slabs, and the etchings observed occasionally on rock surfaces are the
+proofs universally cited. The experiments of Czapek, who substituted
+slabs of aluminum phosphate and other substances for the marble, and
+those of Kossowitch, show that the action can be accounted for more
+satisfactorily and reasonably as due to dissolved carbon dioxide. In
+fact such etchings can be produced on marble slabs by laying platinum
+wires upon them and covering with moist soil, or cotton, or mats of
+filter-paper; see Bull. No. =22=, p. 14, and Bull. No. =30=, p. 41,
+Bureau of Soils, U. S. Dept. Agriculture.
+
+With the advent of this idea of a distinction between the available and
+non-available mineral plant-food elements in the soil, came attempts
+to distinguish them by analytical methods. Of these attempts we now
+have a bewildering array, most of them frankly empirical. For instance,
+Hilgard, in his classical investigation of the cotton soils for the
+Tenth Census, treated his soil samples with an excess of hydrochloric
+acid, evaporated to dryness, extracted with water, and regarded the
+extracted mineral constituents as available. In Germany, a method
+similar to Hilgard’s is now in common use, while in France nitric acid
+is preferred generally because it is supposed to have peculiar solvent
+powers on soil phosphates. In the United States the “official method”
+of the Association of Official Agricultural Chemists is to keep 10
+grams of the soil in contact with 100 cc. of a solution of hydrochloric
+acid (specific gravity 1.115) at the boiling point of water for exactly
+10 hours. In England the popular method is that proposed by Dyer,
+namely, to treat the soil with a 1 per cent. citric acid solution,
+this strength of solution being supposed at one time to represent the
+average acidity of root sap. Maxwell, in Hawaii, and afterwards in
+Australia, claimed good results for the extraction of the soil with a
+1 per cent. solution of aspartic acid, this acid being employed on the
+erroneous ground that the organic acids of the soil are amino acids,
+and that these are the effective agents in dissolving the soil minerals
+and rendering their constituents “available.” The Kentucky Agricultural
+Experiment Station favors an N/5 nitric acid solution,[12] but does not
+recommend its use for soils of other localities, while in a contiguous
+state, the Tennessee Station favors the “official” method.[13] Many
+other methods have been proposed, but the foregoing are typical and
+sufficient to illustrate the present status of soil analysis.
+
+[12] Soils, by A. M. Peter and S. D. Averitt, Bull. No. 126, p. 66,
+(1906).
+
+[13] The soils of Tennessee, by Charles A. Mooers, Bull. No. 78, p. 49,
+(1906).
+
+It is clear that these several methods must give differing results. And
+it is not clear that any one of them is to be preferred to the others
+for any reasons than analytical convenience. There is no reason to
+expect that the proportion of solvent to soil required in these methods
+bears any relation whatever to the mechanism of absorption by plant
+roots. And the attempts to simulate the properties of plant sap in
+some of these solvents are obviously illogical, for the plant sap does
+not come in contact with the soil grains, except through an accidental
+destruction of the plant.
+
+Naturally, comparisons were attempted between the amounts of the
+mineral constituents extracted from a soil by these various solvents
+and the amounts taken up by crops growing on the soil. It was found,
+however, that the amount of any given mineral constituent extracted
+from the soil by a solvent is not, generally, the same as that taken up
+by the plant. Moreover, the ratio of one constituent to another in the
+extract bears no definite relation to the ratio of these constituents
+in the plant. Nevertheless many efforts were made to establish
+“factors.” For instance, the percentage of potash extracted from the
+soil of a field by hydrochloric acid is some multiple of the percentage
+removed by a wheat crop; it was sought to determine this multiple,
+assuming it to be a definite ratio and a natural constant, and it was
+designated as the potash factor. But there is a different factor for
+phosphorus, another for calcium, and still others for each and every
+constituent. The factors found for a soil from one area generally
+do not hold for a soil from another area. Again, different factors
+obviously must be used for different crops. And, finally, the whole
+scheme becomes hopeless when it is realized that the same crop will
+yield widely varying ash analyses, depending upon the cultural methods
+employed, the judicious selection of seed, the amount and distribution
+of rainfall and sunlight, and possibly other agencies, all of which
+affect the growth and absorptive functions of the plant to as great an
+extent as does the particular soil upon which it may be growing.
+
+Moreover, from the purely analytical point of view the situation is
+no better. For instance, the addition of potassium in the amounts
+usually employed in ordinary fertilizer practice generally does produce
+a noticeable effect on the yield of crop. The average application
+of potash (K₂O) is certainly less than 50 lbs. to the acre. It is
+customary to consider the surface foot of soil as the region affected
+by the fertilizer, and an acre foot in good moisture condition weighs
+about 4,000,000 lbs. To be conservative, let it be assumed that 60
+lbs. of potash have been added to 3,000,000 lbs. of soil. The official
+method of the Association of Official Agricultural Chemists calls for
+the determination of the potash in 2 grams of soil, which on the basis
+of the present assumption calls for the estimation of an added amount
+of 0.00004 gram of potash or 0.002 per cent. Taking as an example
+the report of the Association of Official Agricultural Chemists for
+1895[14] there are given the following results obtained independently
+by a number of analysts, on soils which had presumably been sampled by
+the referee with all possible care:
+
+[14] Proceedings of the Twelfth Annual Convention of the Association of
+Official Agricultural Chemists, Bull. No. 47, Division of Chemistry, U.
+S. Dept. Agriculture, p. 36, (1896).
+
+ POTASH CALCULATED AS PER CENT. OF THE FINE DRIED EARTH.
+
+ =============================================================
+ | 1 | 2 | 3 | 4
+ Analyst +-----+------+-----+------+-----+-----+-----+--------
+ | Per | | Per | | Per | | Per |
+ |cent.| Var.|cent.| Var.|cent.| Var.|cent.| Var.
+ --------+-----+------+-----+------+-----+-----+-----+--------
+ A |0.359| 0.044|0.154|-0.002| — | — | — | —
+ B |0.345| 0.030|0.112|-0.044|0.380|0.051|0.104|-0.050
+ C |0.354| 0.039|0.235| 0.079|0.396|0.067|0.225| 0.071
+ D |0.260|-0.055| — | — | — | — | — | —
+ E |0.373| 0.058|0.179| 0.023|0.365|0.036|0.175| 0.021
+ F |0.210|-0.105|0.130|-0.026|0.220|0.109|0.109|-0.045
+ G |0.304|-0.011|0.125|-0.031|0.286|0.043|0.158| 0.004
+ Mean |0.315| — |0.156| — |0.329| — |0.154| —
+ --------+-----+------+-----+------+-----+-----+-----+--------
+
+Not only do the individual determinations show differences far in
+excess of 0.002 per cent., but the differences between each individual
+reading and the mean is greater than 0.002 per cent., so that it is
+evident from these results that the analytical procedure fails to
+recognize appreciable amounts of the so-called available plant foods.
+Consequently the “acid digestion” of a soil fails of the purpose for
+which it was designed, and it is one of the mysteries of chemical
+history that so much time and energy have been devoted to such a
+hopeless quest.
+
+This state of affairs is the more surprising when the limitations of
+the analytical procedure are considered. The data tabulated above
+indicate that the analyses were made with an exactness that justifies
+a statement to three decimal places, that is, to three significant
+figures; and in fact, as was shown, such is necessary if the figures
+are to have any significance regarding fertilizer applications. It is
+obvious that the analysis of a finely pulverized definite mineral or
+rock is less subject to error than a sample of soil sifted through
+a 2 mm. mesh. Yet the U. S. Geological Survey commonly reports its
+analytical data to only hundredths of a per cent., that is, to
+two decimal places. What variation may be expected in duplicate
+determinations by the same analysts it is difficult to say, for such
+duplicates are not commonly published.[15] In spite of the widespread
+view that the chemical analysis of a soil is a statement of great
+accuracy, it is improbable that as usually determined the potash
+content is correct to three or even two significant figures; it is
+also doubtful if the phosphoric acid content is correct to even one
+significant figure, if the total amount is below 0.1 per cent. of the
+soil. That these determinations have a higher accuracy than here stated
+is not shown by an inspection of the literature including the fairly
+numerous results reported in the annual Proceedings of the Association
+of Official Agricultural Chemists.
+
+[15] See: On the interpretation of mineral analyses, by S. L. Penfield,
+Amer. Jour. Sci., (4), 10, 33, (1900); The analysis of silicate and
+carbonate rocks, by W. F. Hillebrand, Bull. No. 305. U. S. Geol. Surv.,
+1907; Manual of the chemical analysis of rocks, by H. S. Washington,
+1904, p. 24; Über Genauigkeit von Gesteinanalysen, von M. Dittrich,
+Neues Jahrbuch für Mineralogie und Palaeontologie, 2, 69, (1903).
+
+It was early felt by some investigators that soil analyses were
+unsatisfactory for studying the relation of the soil to the food
+requirements of a crop, and a second method was devised, namely, the
+growing of a crop, and determining the amount of mineral constituents
+removed from the soil by analyzing the ash of the crop. From the
+point of view of practical soil management this procedure involves
+the serious difficulty of being first obliged to get the crop before
+determining what must be done to best get it. It apparently has the
+scientific advantage of directness in determining the mineral needs
+of the plant from the plant itself. If these needs were constant, the
+advantage would be real, but as already mentioned, one and the same
+plant may have a very different ash content as the result of different
+cultural methods, different climatic and seasonal factors, as well
+as different soils. Generally, a poor crop has a higher percentage
+of ash content than a good crop, and sometimes the poor crop may
+remove from the soil more in absolute amounts of some one or other of
+the ash constituents than does the good crop. The ratio of the ash
+constituents is by no means constant for any one crop, and of course
+varies with different crops.[16] Finally, it is now known that the
+amount of the several mineral nutrients which a soil must furnish to a
+crop in the earlier stages of growth is greater than the crop contents
+at maturity,[17] consequently an analysis of the ripe crop would not
+indicate the plant’s drain upon the soil at all growing periods. So
+that, while ash analyses have taught some important things concerning
+plant growth, they have of necessity failed as guides or criteria of
+the crop-producing power of a soil, its fertilizer requirements, or its
+content of “available” plant-food.
+
+[16] For a brief but comprehensive discussion of ash analyses see, The
+ash constituents of plants, etc., by B. Tollens, Expt. Sta. Rec., 13,
+207-220, 305-317, (1901-02).
+
+[17] Über die Nährstoffaufnahme der Pflanzen in verschiedenen Zeiten
+ihres Wachstums, von Wilfarth, Römer und Wimmer. Landw. Vers. Sta., 63,
+1-70, (1905); Plant food removed from growing plants by rain or dew, by
+J. A. Le Clerc and J. F. Breazeale, Year Book, U. S. Dept. Agriculture,
+1908, p. 389-402.
+
+A third method of soil investigation, also essentially analytical in
+character, is the plot or pot test. The difference between a plot or
+pot experiment is mainly one of size, although it is claimed, and with
+a certain amount of justice, that the plot experiment more nearly
+approximates actual practice, and should be given a somewhat different
+consideration than the more readily controlled pot experiment. Here
+again it has to be considered that seasonal factors and factors other
+than the soil play a relatively large part in the production of the
+crop, so that conclusions regarding the productivity of a soil can
+not be drawn from one season’s crop. Also, nowadays it is recognized
+generally that continuous growing of one crop is an incorrect practice,
+and a rotation should be followed and repeated several times before
+conclusions regarding the productivity of the soil are justified.
+If, however, the rotation has been well managed, the cultivation,
+fertilizing and soil management generally been well done for sixteen,
+twenty or more years, the soil has materially changed, and there can
+be no assurance that the treatment then best for it, is that which was
+best at the beginning of the experiment. Therefore the method throws no
+certain light on the productive power of the soil, or the availability
+of its mineral plant-food constituents. Although much has been learned
+from plot experiments, and especially from the better controlled pot
+experiments, they are inadequate to meet the fundamental problem
+of the relation of the chemical characteristics of the soil to its
+crop-producing powers.
+
+
+
+
+Chapter IV.
+
+THE PLANT-FOOD THEORY OF FERTILIZERS.
+
+
+The guiding principle in soil investigations for about three-quarters
+of a century and until the past few years has been the assumption that
+the principal function of the soil is to furnish mineral nutrients to
+the plant, and that, to supply a lack in the soil, fertilizers are
+added because of the mineral plant nutrients they contain. This theory
+has apparently much to support it; actually, however, the evidence
+usually cited accords better with a more comprehensive generalization
+which will be formulated in a later chapter. It is attractively simple.
+It will be shown later, however, that this very simplicity is an
+argument against its validity.
+
+Those substances which experience has shown to be useful soil
+amendments usually contain one or more of the constituents necessary
+to plant metabolism, commonly phosphorus, potassium, nitrogen or
+calcium. Fertilizers do not always produce increased yields of crops,
+but it has been usual to consider bad results as due to other more or
+less extraneous causes. Moreover, as will appear later, crop yield is
+as strongly affected by some substances containing no mineral plant
+nutrient as by ordinary fertilizers. Again, the plant-food theory
+has been apparently confirmed by the popular misconception that crop
+yields are decreasing. Government statistics, however, indicate very
+positively that crop yields are increasing in Europe as well as in
+America, more in areas where the acreage is stationary than in areas
+where the acreage is increasing, and in areas where fertilizers are
+not used as well as in areas where they are used. Analyses of European
+soils which have been cropped for centuries show no characteristic
+differences from the newer soils of the United States.[18] It is true
+that, from bad management or other causes, individual fields where crop
+production has fallen off are not uncommon. But that such a condition
+is general or that it can be associated generally with a decreased
+content in the soil of any particular mineral substance or substances,
+is a conclusion not sustained by the available data.
+
+[18] A study of crop yields and soil composition in relation to soil
+productivity, by Milton Whitney, Bull. No. 57, Bureau of Soils, U. S.
+Dept. Agriculture, 1909.
+
+The plant-food theory of fertilizers must now be regarded as entirely
+insufficient. Granting that it has been useful in the past and has
+occasioned much valuable work, it seems to have reached the point
+which another simple and temporarily useful theory, the phlogiston
+theory of combustion, reached shortly before the plant-food theory of
+fertilizers was evolved. Just as the phlogiston theory passed away when
+the elementary nature of oxygen was established and Lavoisier taught
+the scientific world to use the balance, so the plant-food theory of
+fertilizers must pass with increasing knowledge of the relation of
+soil to plant and the application of modern methods of research to the
+problem.
+
+
+
+
+Chapter V.
+
+THE DYNAMIC NATURE OF SOIL PHENOMENA.
+
+
+In soil investigations, until recently, the assumption has been made,
+more or less explicitly, that any given soil mass, as for instance a
+field, remains fixed or in place indefinitely. It has been admitted,
+of course, that some physical, chemical and biological processes
+might be taking place in the soil, but these have been regarded as
+relatively unimportant in their effects upon the soil mass _in toto_.
+It has been assumed that the only important change taking place in the
+soil is a loss of mineral plant nutrients, partly by leaching, partly
+by removal in the garnered crops. In other words, the soil has been
+regarded as a static system. This is a fundamental error. In studying
+the soil as a medium for crop production, we must consider the plant
+itself, or at least that part of the plant which enters the soil,
+namely, the root; the solid particles of the soil; the soil water,
+or the aqueous solution from which the plant draws all the materials
+for its sustenance, excepting the carbon dioxide absorbed by its
+aerial portions; the soil atmosphere; the biological processes taking
+place. The one common characteristic of all these things is that they
+are continually in a state of change; therefore the soil problem is
+essentially dynamic.
+
+The root of a growing plant is always moving.[19] The amount of motion
+may be small or large, depending upon the surrounding conditions or
+attendant circumstances, but cessation of motion means the death of
+the root. This becomes evident from a consideration of the mechanism of
+root growth. The living root absorbs and excretes water and dissolved
+substances through a restricted area just back of the root tip or the
+tips of the root hairs. While absorption is taking place, however,
+there is a deposition of denser material over the absorbing area,
+or “root corking.” But coincident with the corking process, the tip
+is pushed forward between the soil grains into the nutrient medium,
+new cells are formed and a new absorbing surface continually brought
+into functional activity. A failure of the plant root to move forward
+in this way would mean a reabsorption of root effluvia with harmful
+consequences to the plant, or a corking over of the root without
+further formation of absorbing surface and with consequent cessation
+of its functioning. This would mean the inevitable death of the root,
+and, if general, of the whole plant. It is clear, therefore, that root
+penetration and absorption of plant nutrients are essentially dynamic.
+
+[19] In order to penetrate the soil, a living root must be capable
+of exerting large pressures, and indeed, the magnitude of these
+pressures has been determined for some cases. See, for citations of
+the literature, Pfeffer, Plant Physiology, translated by Ewart, 1903,
+Vol. 2, p. 124 _et seq._ But it can not be doubted that, in general,
+root movement is much facilitated and perhaps directed by movements
+among the soil particles. As the absorbing tip of the root removes film
+water from the adjacent soil grains, there is a necessary rearrangement
+of these grains with a shrinking away from the tip, which then moves
+forward by taking advantage of the movements among the soil grains.
+
+The solid components of the soil are always in motion. Every soil, no
+matter how flat the area or how well protected by vegetal covering,
+suffers some translocation of soil material through rains, as is
+evidenced by suspended material in the run-off waters. On hillsides
+this is shown by the soil accumulating on the “up” sides of fences,
+especially stone fences. In the aggregate this movement is probably
+quite large everywhere. It is manifestly so in the watersheds of many
+of the world’s important rivers as shown by their muddy waters and
+the formation of deltas, sometimes of great area and agricultural
+importance.
+
+With the saturation or approach to saturation of the surface soil the
+particles are more easily moved among themselves by an extraneous
+force. It is very rarely that the surface of a field is a dead level.
+Consequently when the soil is wetted, the gravitational force on the
+individual soil grains produces a more or less pronounced “creeping”
+effect down hill. On decided slopes this soil creep is believed to be
+of great importance in connection with soil erosion.[20]
+
+As important as is the translocation of material by water, quite as
+important probably is that produced by the winds. These are blowing all
+the time, uphill as well as down, and their range of action is thus
+far wider than is that of rain and flood. The effectiveness of the
+wind as a translocating agency is seldom realized or even suspected by
+the layman, although it is commonly known that the air always contains
+some dust, and dust storms are familiar phenomena. That soil material
+can be carried long distances is certain, however, as for instance
+the sirocco dust, often carried from the Sahara over Europe.[21] Dust
+carried high into the air by volcanic eruptions sometimes travels
+enormous distances, as in the case of the eruption of Krakatoa, when
+such material is reported to have traveled thousands of miles, and
+volcanic debris from the eruptions at Soufrière fell upon ships several
+hundred miles distant. Arctic explorers have reported the finding of
+wind-borne soil materials over the polar ice, and mountaineers have
+observed similar deposits on snow-capped peaks. Soil material on roofs
+and similar inaccessible places has been observed many times, and
+testifies to the continual activity of the wind. The burial of objects
+even of considerable size by wind-borne soil gives like testimony.
+
+[20] Soil erosion is undoubtedly one of the greatest economic problems
+of the time, and yet there is scarcely any subject about which there
+are current so many popular misconceptions. In the rivers and to those
+who use the rivers the water-borne soil material is an unmitigated
+nuisance, save possibly to a few cultivators of low-lying lands who
+for one reason or another, may flood their fields for the sake of the
+silt deposited. To the upland farmer, however, erosion is not only a
+necessity of natural conditions which can not be avoided entirely, but
+under proper control it may be even a blessing. The scalded and gullied
+hillsides, a trial and unnecessary disgrace to the owner, are probably
+not the main sources of the material which finds its way to the river.
+On the contrary, what are regarded usually as well-tilled fields supply
+the greater part of the suspended material in the rivers. The problem
+of erosion on the farm is not merely to check gullying and scalding,
+and deepening of stream heads, but to so adjust both cropping system
+and cultural methods as to secure a reasonable translocation of surface
+soil material with a minimum contamination of the neighborhood streams.
+See, Man and the earth, by Nathaniel Southgate Shaler, 1905.
+
+[21] For a comprehensive discussion of wind as a translocating agent,
+see: The movement of soil material by the wind, by E. E. Free, Bureau
+of Soils, Bull. No. 68, U. S. Dept. Agriculture.
+
+Measurements of the amount of action of wind in translocating soil
+material are rare and probably have a qualitative value only. But
+Udden[22] in what appears to be a conservative calculation, finds “the
+capacity of the atmosphere [over the Mississippi Valley] to transport
+dust is 1000 times as great as that of the [Mississippi] River.” The
+wind seldom is carrying anything like so great a load as it is capable
+of carrying. That is, the wind in its attack upon the land surface
+does not ordinarily obtain so large an amount of material capable of
+being wind-borne as it is possible for the wind to carry when suitable
+material is artificially provided. It should be remembered that,
+speaking generally, the velocity of the wind is lower just at the
+surface of the ground than at heights above, and it is necessary to get
+the soil material above the surface before the wind can exercise its
+full efficiency as a carrying agent.
+
+[22] Erosion, transportation and sedimentation performed by the
+atmosphere, by J. A. Udden, Jour. Geol., 2, 318-331 (1894).
+
+Moreover, wind-borne material is constantly being deposited as well
+as being removed from the land surface. It is evident, however, that
+this movement of soil material by winds is very great, and there
+is no reason to believe that it is of any less importance in other
+areas than in the Mississippi Valley. It is also evident that the
+individual grains in any surface soil of any particular field or area
+are continually and more or less rapidly changing, and the farmer is
+not dealing to-day with just the same soil complex he faced a few years
+back, or will face a few years hence.
+
+But besides the movements of the solid components of the soil by
+translocating agencies, other movements are constantly taking place.
+Whenever a moderately dry soil becomes wetted, it “swells up” until a
+certain critical amount of moisture is present above which there is
+a shrinking. But as a wet soil dries out again below the critical
+amount, there is again a shrinking. As it is always either raining or
+not raining, soils are always either getting wetted or are drying.
+Consequently the individual grains are continually moving about among
+themselves. A heavy object, such as stone, when left on the ground
+gradually sinks into it.[23] Earthworms, burrowing animals and insects
+are continually at work in most arable soils. The action of frost in
+“heaving” a soil is familiar to everyone. Not so well known, however,
+is the fact that the apparently superficial cracks which occur to a
+greater or less extent in every soil, under drought conditions, are
+in reality quite deep, extending well into the subsoil. By the edges
+breaking off, and by wind- and water-borne material being carried in,
+considerable surface soil is thus brought into the subsoil. Through
+these various agencies, therefore, the solid components of the soil are
+continually subject to much mixing; subsoil is becoming surface soil,
+and to some extent _vice versa_. An important result of these various
+processes is the bringing into the surface soil of degradation and
+decomposition products from underlying rocks. The processes involved
+are essentially dynamic.[24]
+
+[23] On the small vertical movements of a stone laid on the surface
+of the ground, by Horace Darwin, Proceedings of the Royal Society of
+London, 68, 253-261, (1901). On the other hand, geological literature
+would probably furnish numerous references to the heaving out of
+boulders, probably as the result of successive freezings and thawings
+of the soil. The shape of the stone as well as the specific nature
+of the movements of the soil particles evidently has an important
+influence in determining whether the stone sinks into the soil or _vice
+versa_.
+
+[24] It is clear that as the soil is continually changing through
+physical agencies, the chemical analysis of it can not be expected to
+furnish evidence as to the mineral constituents removed by crops or by
+leaching.
+
+The soil solution is also a dynamic problem. When the rain falls on
+the soil, a part, the “run-off,” flows over the surface and finds its
+way into the regional drainage; a part immediately evaporates into the
+air, and is designated as the “fly-off;” a third part, the “cut-off,”
+enters the soil.[25] The cut-off water penetrates the soil by way of
+the larger openings and interstices, and mainly under the influence
+of gravity. For convenience this downward-moving water is designated
+as “gravitational” water. It moves through the soil with comparative
+rapidity and a portion reappears elsewhere as seepage water, springs,
+etc. But with the return of fair-weather conditions at the surface,
+there is increased evaporation and augmentation of the fly-off, and
+there is developed a drag or “capillary pull” on the water below.
+A large portion of the cut-off thus returns to the surface, mainly
+through films over the surface of the soil grains and in the finest
+interstices.[26]
+
+[25] This terminology has been suggested by Dr. W. J. McGee.
+
+[26] Leather, however, thinks the water returns from only a limited
+depth, some 5-7 feet; see, The loss of water from soil during
+dry weather, by J. Walter Leather, Memoirs of the Department of
+Agriculture, Agricultural Research Institute, Pusa, India, Chemical
+series, I, 79-116, (1908). Dr. George N. Coffey has called the author’s
+attention to some observations in Western Kansas, where a prolonged
+drought had dried the soil to a considerable depth. A fairly heavy rain
+wetted the soil to less than two feet from the surface, and practically
+all of this moisture had returned to the surface and evaporated
+within a few days. Such special cases as these, however interesting
+in themselves, are even less so than the normal cases in humid areas,
+where a part of the water passes through the soil as seepage, the
+larger portion returning to the surface, sometimes through distances of
+many feet.
+
+The soil atmosphere is continually in motion, following with more or
+less decided lag the barometric changes in the atmosphere above the
+soil. Moreover, the chemical and physical processes continually taking
+place in the soil involve the absorption or the formation of free
+carbonic acid, and it seems probable that all rain water penetrating
+the soil gives up some oxygen to the soil atmosphere. The bacteria
+and lower life forms are necessarily undergoing changes continually.
+In fact all components of the soil are continually undergoing, or are
+involved in, changes of one kind or another.
+
+It is certain that investigation of the various motions and changes
+taking place in the soil is quite as important as investigation of the
+soil components, and that no clear idea of the chemistry of the soil
+can be obtained without it. The development of a rational practice of
+soil control is possible only when the soil is regarded from a dynamic
+viewpoint.
+
+
+
+
+Chapter VI.
+
+THE FILM WATER.
+
+
+When a relatively small quantity of water is added to an absolutely
+dry soil or other powdered solid, there is some shrinkage in the
+apparent volume of the soil or powder. The water spreads over the
+surfaces of the solid particles in a film, and a rise in temperature
+shows that a noticeable energy change accompanies the formation of the
+film.[27] With further increments of water the apparent volume of the
+soil increases until a maximum is reached. The water content at which
+this maximum volume of soil can be attained is a definite physical
+characteristic for any given soil. What is popularly known as the
+“optimum water content” corresponds to this critical content.[28] It
+is the point at which further additions of water will not increase the
+thickness of the moisture film on the soil grains, but will give free
+water in the soil interstices. Just as the apparent volume of a given
+mass of soil varies with the water content, and reaches a maximum at
+a critical moisture content, so do all the physical properties vary
+and have either a maximum or minimum value at this same critical
+moisture content. Thus the apparent specific gravity of a soil reaches
+a minimum, the force required to insert a penetrating tool becomes a
+minimum, while the rate at which a soil warms up reaches a maximum,[29]
+and the ease with which aeration takes place reaches a maximum. In
+fine, this critical water content is that at which the soil can be
+brought into the best possible physical condition for the growth of
+crops. The practical significance of the optimum water content is far
+greater than would be supposed from the attention given it hitherto
+by students of the soil. It is the content of soil water which the
+greenhouse man should strive to maintain, and which the irrigation
+farmer should seek to provide, instead of the over-wetting so common to
+the practice of both. In general farming it is that moisture content
+at which the farmer will attain the best results in plowing and
+cultivating, and attain these results most readily.
+
+[27] See, in this connection, Energy changes accompanying absorption,
+by Harrison E. Patten, Trans. Am. Electrochem. Soc., 11, 387-407,
+(1907); see also the recent valuable research, Les dégagements de
+chaleur qui se produisent an contact de la terre sèche et de l’eau,
+par A. Muntz et H. Gaudechon, Ann. sci. agron. (3), 4, II, 393-443,
+(1909), where it is shown that probably a part of the heat is due to
+chemical combination between the water and the other soil components.
+To quote, “Ces diverses observations nous conduisent à penser, sans
+nous en donner toutefois la preuve absolute, que la fixation de l’eau
+sur les éléments terreux très fins et sur les matériaux organisés, est
+tout au moins, en partie, attribuable à une combinaison chimique qui se
+manifeste non seulement par un fort dégagement de chaleur, mais aussi
+par la soustraction de l’eau à des substances aux-quelles elle semble
+chimiquement liée.”
+
+[28] The moisture content and physical condition of soils, by Frank
+K. Cameron and Francis E. Gallagher, Bull. No. 50, Bureau of Soils,
+U. S. Dept. of Agriculture, 1908. See also Über physikalische
+Bodenuntersuchung, von H. Rodewald, Schriften Naturwiss. Vereins
+Schleswig-Holstein, 14, 397-399, (1909).
+
+[29] Heat transference in soils, by Harrison E. Patten, Bull. No. 59,
+Bureau of Soils, U. S. Dept. Agriculture, 1909.
+
+With additions of water beyond the critical point, there is a presence
+of free water in the soil interstices accompanied by important changes
+in the soil structure. With continued additions, there is a more or
+less rapid decrease in the apparent volume; there is a tendency for
+the soil aggregates to break down and the “crumb structure” so greatly
+desired by agriculturists is less and less readily obtained, and
+working of the soil tends in some cases to produce that phenomenon
+known as “puddling.” However desirable the property of puddling may
+be to the potter or the brick maker, to the farmer it is a bane to be
+avoided above all things. To overcome it requires his best skill, and
+it usually takes several years of patient effort to restore a puddled
+soil to good tilth.
+
+The force with which the film water is held against the soil grains
+has not been determined as yet with any degree of precision, but
+it is certainly very great. If a soil be saturated, that is, if so
+much water be added that further additions will cause a flow of free
+water, and the soil be then submitted to some mechanical device for
+abstracting the water, the moisture content of the soil can be readily
+diminished to the critical water content; but to diminish it further
+by mechanical means is not easy. The tenacity with which film water
+is held by the soil grains has been shown in several ways. In one of
+these, for instance, a semi-permeable membrane was precipitated in the
+walls of a porous clay cell, which was then filled with sugar solution
+having an osmotic pressure of about 35 atmospheres. When this cell was
+buried in a soil having a moisture content above the optimum, water
+flowed into the cell. On the contrary, when the cell was buried in
+another sample of the same soil having a moisture content well below
+the optimum, there was a marked flow of water from the cell. It would
+appear, therefore, that the attraction between the soil grains and the
+film-forming water was certainly greater than the solution pressure of
+the sugar.[30] Again, by whirling wetted soils in a rapidly revolving
+centrifuge,[31] fitted with a filtering device in the periphery,
+and developing a force equivalent on the average to 3,000 times the
+attraction of gravitation, the soils could not be reduced below the
+critical water content. From the results of Lagergren,[32] Young,[33]
+and Lord Rayleigh,[34] it appears that the force holding a very thin
+moisture film on the soil grains would be of an order of magnitude from
+6,000 to 25,000 atmospheres. This force, however, must greatly decrease
+with thickening of the film, as is shown by the fact that at the
+critical moisture content a small further addition of water produces
+no marked heat manifestation, though making a noticeable difference in
+the physical properties of the soil. Therefore, while recognizing that
+our knowledge of this force still lacks a desirable precision, it is
+nevertheless clear that the force is very great.
+
+[30] The chemistry of the soil as related to crop production, by Milton
+Whitney and Frank K. Cameron, Bull. No. 22, Bureau of Soils, U. S.
+Dept. Agriculture, 1903, p. 54.
+
+[31] The moisture equivalent of soils, by Lyman J. Briggs and John W.
+McLane, Bull. No. 45, Bureau of Soils, U. S. Dept. Agriculture, 1907.
+
+[32] Über die beim Benetzen fein verteilter Körper auftretende
+Wärmetönung, von Lagergren, Bihang till K. sv. Vet.-Akad., Handl., 24,
+Afd. II, No. 5, (1898).
+
+[33] Hydrostatics and elementary hydrokinetics, George M. Minchin, p.
+311, 1892.
+
+[34] On the theory of surface forces, by Lord Rayleigh, Phil. Mag. (5),
+30, 285-298, 456-475, (1890).
+
+The function of the film water in maintaining the soil structure is
+undoubtedly important. A soil in good tilth, or good condition for
+crop growth, shows a peculiar structural arrangement of the individual
+soil grains or soil particles, which it is very difficult to describe
+in precise terms, but which is readily recognized in practice. This
+condition is usually described as a “crumb structure,” either because
+of its appearance or because of the peculiar crumbly feeling which
+a soil in this condition gives when rubbed between the fingers. The
+individual grains of soil are gathered into groups or floccules.
+While other causes may be more or less operative in particular cases,
+it seems very probable that the film water is primarily the agency
+holding together the grains in these floccules. The obvious explanation
+is that the film is exerting a holding power because of its surface
+tension. It follows, therefore, that anything which affects the surface
+tension of water should affect the structure of the soil; that is,
+the flocculation or granulation of the particles. But certain agents
+which produce respectively flocculation or deflocculation, nevertheless
+modify the surface tension of the solution in the same direction, and
+in not widely varying degree. Similar difficulties arise in attempting
+to correlate “crumbing” phenomena with the viscosity of the film
+water,[35] and it must be admitted frankly that present views on this
+subject are very unsatisfactory, and that more careful investigation is
+urgently needed on this fundamental and important problem. Not only is
+the absence of a satisfactory theory embarrassing in considering the
+problems of soil structure and a rational control, but the difficulties
+are no less in the equally important problems of the movement of film
+moisture, and the distribution of moisture in a soil.
+
+[35] Equally unsuccessful is the attempt to correlate flocculating
+agents with changes in the density of water. See, The condensation of
+water by electrolytes, by F. K. Cameron and W. O. Robinson, Jour. Phys.
+Chem., 14, 1-11, (1910).
+
+The movement of moisture into a soil from an illimitable supply is a
+comparatively simple phenomenon, controlled by a rate law which may be
+expressed by the equation _yⁿ_ = _kt_ when _y_ is the distance through
+which the movement has taken place; _t_ is the time, and _k_ and _n_
+are characteristic constants for the particular soil and solution.[36]
+This expression may be more readily recognized as a rate formula
+when written _dy/at_ = A_yᵐ_, where A and _m_ are constants for the
+particular system. The first form of the equation promises to be the
+more useful. This formula also describes the rate of advance of a
+dissolved substance into the soil.
+
+Owing to irregularities in the soil column this equation is more
+readily studied with capillary tubes or with such absorbents as
+filter-paper or blotting paper. The following tables will, however,
+give an idea as to its validity for soils.
+
+ ALLUVIAL SOIL, GILA RIVER.[37]
+
+ ===============+====================+=================
+ Time,_t_ min. | Height,_y_ inches | _k_ (_n_ = 1.86)
+ ---------------+--------------------+-----------------
+ 2 | 1.5 | 1.05
+ 5 | 2.4 | 1.02
+ 10 | 3.6 | 1.08
+ 15 | 4.3 | 1.01
+ 30 | 6.3 | 1.05
+ 60 | 9.2 | 1.07
+ ---------------+--------------------+-----------------
+
+ DISTILLED WATER IN PENN. LOAM (_t_ = 21° C).
+
+ ==========+==============+================
+ Time,_t_ | Height,_y_ | _k_
+ min. | cm. | (_n_ = 2.25)
+ ----------+--------------+----------------
+ 1 | 1.15 | 1.37
+ 2 | 1.54 | 1.33
+ 3 | 1.85 | 1.33
+ 4 | 2.08 | 1.30
+ 5 | 2.28 | 1.28
+ 7 | 2.59 | 1.21
+ 10 | 2.97 | 1.16
+ 15 | 3.47 | 1.10
+ 20 | 3.90 | 1.07
+ 30 | 4.67 | 1.06
+ 40 | 5.39 | 1.11
+ 50 | 5.90 | 1.09
+ 60 | 6.47 | 1.12
+ 75 | 7.20 | 1.13
+ 90 | 8.03 | 1.21
+ 105 | 8.72 | 1.25
+ ----------+--------------+----------------
+
+[36] See Bull. No. =30=, Bureau of Soils, U. S. Dept. Agriculture, p.
+50 _et seq._; also, The flow of liquids through capillary spaces, by J.
+M. Bell and F. K. Cameron, Jour. Phys. Chem., =10=, 659, (1906); See
+also, Wo. Ostwald, 2 Supplementheft Zeitschrift Kolloidchemie, 1908, 20.
+
+[37] Computed from observations by Loughridge, Report Agr. Expt. Sta.,
+University California, 1893-94, p. 93.
+
+ INDIGO CARMINE IN PENN. LOAM SOIL (_t_ = 21° C.).
+
+ Solution contained 2 grains dye per liter.
+ =========+============+==============+================+=============
+ Time,_t_| Height,_y_ | _k_ for water| Height colored | _k_ for dye
+ min. | wet cm. | (_n_ = 2.25)| cm. | (_n_ = 2.25)
+ ---------+------------+--------------+----------------+-------------
+ 1 | 1.28 | 1.75 | 0.64 | 0.37
+ 2 | 1.67 | 1.59 | 0.90 | 0.39
+ 3 | 2.05 | 1.68 | .. | ..
+ 4 | 2.26 | 1.56 | .. | ..
+ 5 | 2.49 | 1.56 | 1.02 | 0.21
+ 7 | 2.74 | 1.38 | .. | ..
+ 10 | 3.20 | 1.40 | .. | ..
+ 15 | 3.72 | 1.29 | .. | ..
+ 20 | 4.28 | 1.32 | 1.92 | 0.22
+ 30 | 5.10 | 1.31 | .. | ..
+ 40 | 5.77 | 1.29 | 2.69 | 0.23
+ 50 | 6.41 | 1.26 | 3.20 | 0.28
+ 60 | 6.90 | 1.29 | .. | ..
+ 75 | 7.46 | 1.23 | .. | ..
+ 90 | 8.74 | 1.46 | 3.59 | 0.20
+ 105 | 9.00 | 1.33 | .. | ..
+ ---------+------------+--------------+----------------+-------------
+
+It has also been shown repeatedly by experiment that the movement of
+moisture is relatively rapid when the moisture content of the soil
+is above the optimum, but that the movement is exceedingly slow when
+the soil has a lower water content than the optimum; that is, the
+point at which the water is entirely in the form of film water. For
+instance, if a moderately wet sample of soil be brought into intimate
+contact with an air-dry sample of the same soil, there will, at first,
+be a relatively rapid movement of the moisture, but as soon as the
+wetted portion has been brought to the “optimum” condition, no further
+movement can be detected, although the experiment has been tried of
+leaving such samples together for months and with a difference of
+water content amounting, in the case of clay soils, to 15 or 20 per
+cent. Since the drought limit, or the soil moisture content at which
+plants wilt, is, for most soils, considerably below the optimum water
+content, the movement of film water is obviously a problem of the first
+importance from a practical point of view as well as of the highest
+theoretical interest.
+
+The movement of water vapor, or its distillation from place to
+place in the soil, is another problem often confused with the
+above. Its importance is not yet clear, although according to some
+investigators[38] it would appear that the addition of soluble
+fertilizer salts by causing a lowering of the vapor pressure of the
+water induces a distillation to that region from other regions of the
+soil as well as from the atmosphere above. This brings up the problem
+of the diffusion of water and other vapors through the soil. It has
+been shown that the soil “plug” retards the rate at which diffusion
+takes place but induces no other effect in the ordinary phenomenon of
+free diffusion. This fact is obviously of the first importance in the
+theory of mulches, but requires no further consideration here.[39]
+
+[38] Sur la diffusion des engrais salins dans le terre, par Muntz et
+Gaudechon, Comptes rendus, =148=, 253-258, (1909).
+
+[39] See, Contribution to our knowledge of the aeration of soils, and
+Studies of the movement of soil moisture, by Edgar Buckingham, Bulls.
+Nos. =25=, 1904, and =33=, 1907, Bureau of Soils, U. S. Dept. of
+Agriculture.
+
+
+
+
+Chapter VII.
+
+THE MINERAL CONSTITUENTS OF THE SOIL SOLUTION.[40]
+
+
+The mineral constituents of the soil are products of the
+disintegration, degradation and decomposition of rocks. The
+decomposition products are mainly silica in the form of quartz,
+ferruginous material consisting of more or less hydrated ferric
+oxide and alumina, and hydrated aluminum silicate. The ferruginous
+material, being deposited or formed in the soil in a very finely
+divided condition, frequently coats the soil fragments to such an
+extent as completely to mask their true character. But if a soil be
+thoroughly shaken with water, and especially in the presence of some
+deflocculating agent such as a slight excess of ammonia, as in the
+ordinary preparation of a soil sample for mechanical analysis[41]
+the coating material is generally removed quite readily, and the
+mineral particles appear as fragments and splinters of the ordinary
+rock-forming minerals. Sometimes these fragments are more or less
+worn and rounded at the edges, showing mechanical abrasion or solvent
+action; sometimes they show evidences of partial alteration and
+decomposition; but surfaces of the unaltered mineral individuals always
+are found. These unaltered minerals occur as fragments of all sizes,
+and are to be found in the sands, silts, and presumably in the clays.
+As might be anticipated, the minerals other than quartz generally show
+a tendency to segregate in the finer mechanical separations of the
+soil. The presence of these unaltered mineral fragments in the clays
+has so far defied direct experimental proof because of the limitations
+of the microscope, but from chemical reasoning and _a priori_
+considerations there can be but little doubt that they exist in the
+clays as in the coarser separations.[42]
+
+[40] For a more detailed discussion and citations of the literature,
+see The mineral constituents of the soil solution, by Frank K. Cameron
+and James M. Bell, Bull. No. =30=, Bureau of Soils, U. S. Dept.
+Agriculture, 1905.
+
+[41] Centrifugal methods of mechanical soil analysis, by L. J. Briggs,
+F. O. Martin and J. R. Pearce, Bull. No. =24=, Bureau of Soils, U. S.
+Dept. Agriculture, 1904.
+
+[42] See, The mineral composition of soil particles, by G. H. Failyer,
+J. G. Smith and H. R. Wade, Bull. No. =54=, Bureau of Soils, U. S.
+Dept. Agriculture, 1909. Recent improvements in microscope methods make
+it possible to identify without serious trouble the mineral content of
+silts with a diameter as low as 0.005 mm., and many even of the clay
+particles have recently been determined with satisfactory accuracy.
+
+The minerals to be anticipated in the soil are those commonly occurring
+in the rocks; but as a result of the action of mixing and transporting
+agencies, a soil normally contains minerals from rocks other than those
+from which it is primarily derived.
+
+It would hardly be fair to regard a beach sand, for instance, as a
+normal soil. Yet it is surprising how many minerals other than quartz
+can usually be found even in a beach sand. Opinions may differ as to
+just what are the common rock-forming minerals, and perhaps no two
+mineralogists or petrographers would give identical lists, but there
+are a number of minerals which would appear undoubtedly in every list,
+and these would be found generally in any soil. Again, it might happen
+that in any given sample of soil, no pyroxene, for instance, could
+be found; but experience shows that it would never happen in such a
+case that no amphibole, chlorite, serpentine, or other ferro-magnesian
+silicates would be present. However distinct these minerals cited may
+be from each other morphologically or optically, they are much the
+same in their chemical characteristics, their solubilities and their
+reactions with water and such dilute solutions as exist in the soil.
+Hence from the point of view of the soil chemist they may be considered
+for all practical purposes varieties of one and the same mineral
+species. Consequently an important result of researches on the minerals
+of the soil is the generalization that soils are far more heterogeneous
+than are rocks, and that _practically every soil contains all the
+common rock-forming minerals_.[43]
+
+[43] See Bull. No. =30=, Bureau of Soils, U. S. Dept. Agriculture,
+1905, p. 9.
+
+It is not difficult to account for the heterogeneity of the mineral
+content of the soil. Many of our rocks are reconsolidated soils, and
+the alternating formation of rock and soil from the same materials
+is probably an agency, in some part at least, in the mixing of soil
+material. The action of water in carrying off and transporting surface
+material and in gullying and eroding sloping surfaces is probably a
+large factor. But this agency, like the first, is rather restricted
+and localized. Just as important as a mixing agency is the wind. This,
+unlike water, works uphill as well as down, and is more or less in
+action at all times, continually transporting soil material from place
+to place. Wind-borne dust on roofs of dwellings, on rocky mountain tops
+and similar places, where it could have been brought by no other agency
+than the wind, is sometimes found supporting vegetation. Many chemical
+and mineralogical analyses of wind-borne dust obtained from various
+locations show it to have generally the same essential characteristics
+as ordinary soils.
+
+Aside from the quartz and ferruginous materials mentioned above,
+the major part of the soil minerals are silicates, ferro-silicates,
+alumino-silicates, or ferro-alumino-silicates, of the common bases,
+sodium, potassium, calcium, magnesium, and ferrous iron. Other
+bases, such as lithium, barium, or the heavy metals may occasionally
+be present in appreciable amounts as may other types of silicates,
+or other mineral salts, but these may be regarded as more or less
+incidental and rarely affecting in any essential way the general
+character of the soil mass. These silicates or silico minerals are all
+somewhat soluble in water, and being salts of weak acids with strong
+bases, are greatly hydrolyzed. A convenient illustration is afforded
+by the well-known rock and soil mineral, orthoclase. Assuming its type
+formula, the reaction with water may be represented,
+
+ K.AlSi₃O₈ + HOH ⇆ H.AlSi₃O₈ + KOH.
+
+Under ordinary soil conditions, with a relatively large proportion of
+carbon dioxide in the soil atmosphere, the potash formed would be more
+or less completely transformed to the bicarbonate,
+
+ KOH + CO₂ + H₂O ⇆ KHCO₃ + H₂O.
+
+Confirmation of this view is afforded by the natural associations and
+known alteration products of orthoclase.
+
+The acid of the formula H.AlSi₃O₈ is not known and is probably entirely
+instable under ordinary conditions, and breaks down with the separation
+of silica, to form the minerals pyrophyllite, kaolinite or kaolin, and
+diaspore according to the following equations:
+
+ H.AlSi₃O₈ - SiO₂ = H.AlSi₂O₆ (Pyrophyllite)
+ H.AlSi₃O₈ - 2SiO₂ = H.AlSiO₄ (Kaolinite)
+ H.AlSi₃O₈ - 3SiO₂ = H.AlO₂ (Diaspore).
+
+All three of these minerals and their corresponding salts have been
+found in nature as alteration products of orthoclase. It is probable
+that, under soil conditions, the principal metamorphic product of
+feldspar is kaolin (or kaolinite when it is crystalline), hydrated
+aluminum oxide being of much less importance[44] and pyrophyllite of
+doubtful occurrence. A still more interesting case, perhaps, because
+of the well recognized tendency of magnesium salts to form basic
+compounds, is the alteration of pyroxene, amphibole and olivine with
+the formation of a chlorite or serpentine, common associations in
+nature, which may be represented
+
+[44] See Ueber die Bildung von Bauxit und verwandte Mineralien, von A.
+Liebrich, Zeit. prakt. Geol., =1897=, 212-214.
+
+ MgSiO₃ + HOH ⇆ MgSiO₃._n_Mg(OH)₂ + SiO₂.
+
+
+It is tacitly assumed in the foregoing statements that the reaction
+between a silicate mineral and water is a reversible reaction. This is
+not definitely known to be the case, for the formation of the ordinary
+silicate rock-forming minerals in the wet way at ordinary temperatures
+has as yet been realized in only a few cases. The assumption has,
+however, some experimental support. Minerals have been often made in
+the wet way at somewhat elevated temperatures, especially interesting
+cases in this connection being the formation of orthoclase by Friedel
+and Sarasin[45] at slightly elevated temperatures, and the formation
+of zeolites by Gonnard[46] and by Doroshevskii and Bardt,[47] and the
+formation of apatite by Weinschenk.[48] Feldspars and zeolites are
+common natural associations, it being generally conceded that zeolites
+are alteration products of the feldspars through the action of water;
+but Van Hise[49] has pointed out that under conditions of weathering
+such as would obtain in the soil, the tendency is for the zeolites to
+alter to feldspars. Wöhler’s classical experiment of recrystallizing
+apophyllite from hot water[50] is significant, for only the products
+of hydrolysis should be obtained if there is an irreversible reaction
+between the mineral and water. Lemberg found that leucite (KAlSi₂O₆)
+when treated with an aqueous solution containing 10 per cent. or
+more of sodium chloride, was partially transformed to analcite
+(NaAlSi₂O₆._n_H₂O), potassium chloride being formed at the same time.
+The reverse reaction was also realized, that is, the partial conversion
+of analcite to leucite by treatment with a solution of potassium
+chloride, and similar transformations were carried out with the
+feldspars.[51] Lemberg’s experiments are of especial value as they were
+carried out at ordinary as well as at high temperatures. It appears
+probable, therefore, that the hydrolysis of a silicate of the alkalis
+or alkaline earths is a reversible reaction. It should be noted,
+however, that Kahlenberg and Lincoln[52] have shown that probably,
+in very dilute solutions of alkali silicates, the hydrolysis is
+practically complete and the silica is nearly all present as colloidal
+silica and not as silicic acid. Nevertheless at higher concentrations
+silicates are formed, and there is abundant evidence in nature that the
+alumino- or ferro-silicates are reacting with bases to form salts, for
+example such as the micas.[53] If the hydrolysis were quite complete,
+it would appear to follow that the reaction between water and the
+silicate is irreversible. In that case it is difficult to see how any
+silicate mineral could persist in the soil for any length of time,
+and all soils should soon become sterile wastes composed essentially
+of quartz, kaolin and ferruginous oxides. It has been suggested that
+the original mineral particles are protected from decomposition by
+the formation of a coating “gel.” That is, that silica, alumina,
+ferruginous or other materials result from the decomposition of the
+minerals in a jelly-like form on the surface of the soil grains,
+protecting them from further action of the soil solution.[54] If
+diffusion can take place through the gel, solution and hydrolysis of
+the mineral would proceed, although the presence of the gel would
+probably retard the rate of the reaction. If it be postulated, however,
+that diffusion through the gel does not take place, the minerals of the
+soil can have no influence on the composition of the soil solution,
+which is an unthinkable alternative. The presence of such gels in the
+soil has frequently been assumed, but satisfactory proof is generally
+wanting.
+
+[45] Sur la reproduction par voie aqueuse du feldspath orthose, par
+Friedel et Sarasin, Comptes rendus, =92=, 1374, (1881).
+
+[46] Note sur une observation de Fournet, concernant la production des
+zéolites a froid, par F. Gonnard, Bull. Soc. min. France, =5=, 267-269,
+(1882); Jahrb. Min., =1884=. I, Ref. 28.
+
+[47] Metathetical reactions with artificial zeolites, by A.
+Doroshevskii and A. Bardt, Jour. Russ. Phys. Chem. Soc., =42=, 435-42
+(1910). Chem. Zentr., 1910, II, 68.
+
+[48] Beiträge zur Mineralsynthesis, von E. Weinschenk, Zeit. Kryst.,
+=17=, 489-504, (1890).
+
+[49] U. S. Geol. Surv. Monograph, =47=, A treatise on metamorphism, by
+Charles R. Van Hise, 1904, p. 333.
+
+[50] Jahresb. Fortschr. Chemie Liebig and Kopp, =1847-48=, 1262; note.
+
+[51] Ueber Silicatumwandlungen, von J. Lemberg, Zeit. deutsch. geol.
+Ges., =28=, 519-621, (1876); Inaug. diss. Dorpat, =1877=; Bied.
+Centbl., =8=, 567-577, (1879).
+
+[52] Solutions of silicates of the alkalis, by L. Khlenberg and A. T.
+Lincoln, Jour. Phys. Chem., =2=, 77-90, (1898).
+
+[53] Van Hise, loc. cit., p. 693.
+
+[54] A gel is a jelly-like substance, apparently continuous, which
+forms either by the settling from suspension in a liquid of very
+fine particles which then become aggregated; or, is formed by the
+evaporation of a liquid containing fine particles in suspension until
+the quantity of liquid remaining is just sufficient to serve as a
+cementation medium holding the suspended particles together in a
+semi-rigid mass. For an experimental demonstration of the formation of
+such a gel, see, The effect of water on rock powders, by Allerton S.
+Cushman, Bull. No. =92=, Bureau of Chemistry, U. S. Dept. Agriculture,
+1905.
+
+In general, the same kind of considerations developed for orthoclase
+hold for the other soil minerals. If minerals of this character be
+pulverized or ground reasonably fine and then be shaken with distilled
+water which has been previously boiled to eliminate the dissolved
+carbon dioxide, the resulting solution will give an alkaline reaction
+with such indicators as phenolphthalein or litmus.[55] If a soil be
+shaken up thoroughly with water, the resulting solution filtered free
+of suspended matter, as by passing through a Pasteur-Chamberland
+bougie, and then boiled to eliminate the carbon dioxide, in the vast
+majority of cases the solution will also give an alkaline reaction
+with phenolphthalein or litmus. The waters of most of our springs,
+ponds, creeks or rivers being natural soil solutions, give an alkaline
+reaction after boiling.
+
+[55] In making such experiments in the laboratory or in lecture
+demonstrations, it is well to have the mass of water large in
+comparison with the mass of powdered mineral or rock; otherwise
+secondary adsorption effects may occur and obscure the results of the
+hydrolysis.
+
+But the mineral content of these natural waters varies greatly. These
+waters are composed in part of the “run-off,” in part of a portion of
+the “cut-off” waters, described above. This portion of the cut-off,
+normally, in passing through the soil goes mainly through the larger
+interstices. It is not long in contact with the individual soil
+particles and floccules, and because diffusion of dissolved mineral
+substances is quite slow, especially in dilute solutions, it takes up
+but little mineral matter from such aqueous films as it may intercept.
+
+A different state of things exists with that portion of the cut-off
+water which returns towards the surface by reason of capillary forces,
+to form the great natural nutrient medium for plants. This water is
+moving over the soil particles in films, and with slowness. It _is_
+long in contact with successive fragments of any particular mineral
+and all the different minerals making up the soil. Consequently, it
+tends towards a saturated solution with respect to the mineral mass;
+and it follows that if every soil contains all the common rock-forming
+minerals, every soil should give the same saturated solution, barring
+the presence of disturbing factors.[56] Disturbing factors, however,
+enter into all cases under field conditions, such for instance as the
+presence of some uncommon or unusual mineral in appreciable amounts,
+differences in temperature, surface effects, or extraneous substances.
+These will be considered later, but another disturbing factor requires
+immediate consideration.
+
+In every soil, varying proportions of the soluble mineral constituents
+are present otherwise than as definite mineral species; that is, they
+are present as solid solutions, or absorbed on the soil grains or
+perhaps absorbed in some other manner. The concentration of the liquid
+solution in contact with a solid solution or complex of absorbent and
+absorbed material is dependent upon the relative masses of solution and
+solid. Thus, the concentration of a solution with respect to phosphoric
+acid, when brought into contact with so-called basic phosphates of lime
+or iron, is dependent in a marked way upon the proportion of solution
+to solid.[57] Consequently it is to be expected that an aqueous extract
+of a soil will vary in concentration with the proportion of water
+used; and that with the same proportion of water, different soils or
+different samples of the same soil will yield different concentrations.
+
+[56] Feldspars certainly, and phosphorites possibly, are mineral
+components of the soil; and these substances when ground sufficiently
+fine have been added to soils with sometimes an increased production
+of crop. Other minerals, such as leucite, have given similar results.
+But also apparently pure quartz sand sometimes accomplishes the same
+results, as for example, in the experiments of Hilgard cited above.
+It has not been shown, however, that the addition of any of these
+substances produces an appreciable change in the concentration of the
+soil solution.
+
+[57] The action of water and aqueous solutions upon soil phosphates, by
+Frank K. Cameron and James M. Bell, Bull. No. =41=, Bureau of Soils, U.
+S. Dept. of Agriculture, 1907.
+
+How far absorbed mineral constituents affect the solubility of the
+definite minerals in the soil or influence the concentration of the
+soil solution, it is not possible to predict with any approach to
+certainty. Those soils which hold the most moisture are generally the
+best absorbers. Moreover, the soluble mineral constituents of the soil,
+for instance potassium or phosphoric acid, are absorbed to a very high
+degree from dilute solutions. Consequently it is to be expected that
+variations in the concentration of the natural soil solution would be
+less than in aqueous extracts, when there is employed a constant and
+relatively large proportion of water to soil. These considerations
+are of great theoretical importance since they appear to negative
+the possibility of getting, with present experimental resources, any
+_exact_ knowledge of the concentrations of the mineral constituents in
+the soil solution when the soil is in condition to grow the common crop
+plants. Moreover, they furnish a guide to the limitations which must be
+recognized in attempting to postulate what these concentrations may be
+on the basis of analytical data obtained from aqueous soil extracts.
+
+Many attempts have been made to extract the solution naturally existing
+in the soil and to analyze it. The results obtained have not been very
+satisfactory, owing mainly to the mechanical difficulties involved. As
+pointed out above, the solution in a soil under suitable conditions for
+crop growth is held by a force of great magnitude. Nevertheless, by
+using powerful centrifuges, with saturated soil, it has been possible
+to throw out the excess of solution over the critical water content
+of the soil. In this way small quantities, generally a very few cubic
+centimeters at a time, have been obtained. The analysis of a few cubic
+centimeters of a very dilute solution is in itself difficult, involving
+necessarily more or less uncertainty as to the absolute value of the
+results. Nevertheless, the concentration of the soil solutions thus
+obtained, with respect to phosphoric acid and potash, varied but little
+for soils of various textures from sands to clays, and the variations
+observed could not be correlated with the known crop-producing power
+of the soils. The average concentrations of the soil solutions thus
+obtained lies in the neighborhood of 6-8 parts per million (p.p.m.) of
+solution for phosphoric acid (P₂O₅) and 25-30 parts per million for
+potash (K₂O).[58] In the following table are given the results obtained
+by analyzing solutions extracted from different samples of loams and
+sands by means of a centrifuge. The crop growing on these soils and the
+crop condition at the time the samples were collected are given in the
+table, and the percentages of water in the samples when placed in the
+centrifuge are also given.
+
+[58] In this connection it is interesting to note that recent
+investigations on the proportions of phosphoric acid, potassium and
+nitrates in cultural solutions best adapted to the growth of wheat,
+give the same ratio of phosphoric acid to potassium as the figures just
+cited show to exist normally in the soil solution.
+
+ ANALYSIS OF SOIL SOLUTION REMOVED FROM FRESH SOILS
+ BY THE CENTRIFUGE.
+
+ ==================+=======+==========+=========+==================
+ | | | |Parts per million
+ | | | | of solution
+ Soil | Crop | Condition|Per cent +--------+----+----
+ | | of crop |moisture.| PO₄ | Ca | K
+ ------------------+-------+----------+---------+--------+----+----
+ Leonardtown loam | Wheat | Good | 22.0 | 6 | 17 | 22
+ Leonardtown loam | Wheat | Poor | 25.2 | 10 | 9 | 19
+ Leonardtown loam | Wheat | Good | 17.6 | 8 | 22 | 38
+ Sassafras loam | Clover| Good | 19.7 | 5 | 18 | 19
+ Sassafras loam | Corn | Medium | 17.5 | 8 | 13 | 36
+ Sassafras loam | Corn | Medium | 18.3 | 8 | 83 | 25
+ Sassafras loam | Wheat | Good | 18.8 | 7 | 44 | 34
+ Sassafras loam | Wheat | Poor | 20.0 | 7 | 27 | 24
+ Sassafras loam | Corn | Good | 17.3 | 8 | 24 | 25
+ Norfolk sand | Forest| Poor | 10.0 | 5 | 18 | 31
+ Norfolk sand | Corn | Good | 11.9 | 11 | 36 | 31
+ Norfolk sand | Wheat | Good | 10.7 | 18 | 45 | 31
+ Norfolk sand | Wheat | Poor | 11.2 | 8 | 38 | 24
+ Norfolk sand | Corn | Medium | 10.6 | 9 | 65 | 35
+ ------------------+-------+----------+---------+--------+----+----
+
+The concentrations of the solutions obtained from the samples do not
+justify any correlation with the crop-producing power of the soils, nor
+with the texture of the soils. The wide variation in the concentrations
+with respect to calcium is probably due to the fact that all of the
+samples came from fields which had been limed, some quite recently,
+and that the content of carbon dioxide in the different samples
+varied. It is of special interest to note that the content of calcium
+in the solutions does not show any obvious relation to the content of
+phosphoric acid.[59]
+
+[59] For the literature of the earlier work on the composition of
+aqueous extracts of soils, see: How crops feed, by Samuel W. Johnson,
+1890, p. 309 _et seq._; see also. On the analytical determination of
+probably available “mineral” plant-food in soils, by Bernard Dyer,
+Jour. Chem. Soc. =65=, 115-167, (1894); and Soils, by E. W. Hilgard,
+1906, p. 327 _et seq._
+
+An effort has been made to ascertain the mineral concentration of
+soil solutions as they occur naturally in the field. Because of the
+practical impossibility of extracting the actual soil solution, an
+empirical method was employed. Areas were selected where good and
+poor crops were growing near each other on the same soil types, and
+preferably in the same field. Samples of soil from under these crops
+were taken at several intervals during the growing season, quickly
+removed to a nearby laboratory, shaken thoroughly with distilled water
+in the proportion of one part of soil to five parts of water, allowed
+to stand twenty minutes and the supernatant solution passed through a
+Pasteur-Chamberland filter.[60]
+
+[60] Capillary studies and filtration of clays from soil solutions, by
+Lyman J. Briggs and Macy H. Lapham, Bull. No. =19=, Bureau of Soils.
+U. S. Dept. Agriculture, 1902; Colorimetric, turbidity and titration
+methods used in soil investigations, by Oswald Schreiner and George H.
+Failyer, Bull. No. =31=, Bureau of Soils, U. S. Dept. Agriculture, 1906.
+
+As has been pointed out above, the aqueous extract of a soil thus
+arbitrarily prepared has no definite or causal relation to the
+soil solution in the field. It is certain that the solutions would
+not generally be the same. It should also be emphasized that such
+a procedure can not, as some investigators have assumed, afford a
+criterion between soluble and insoluble salts in the soil, else the
+proportion of water to soil used above some minimum would be immaterial
+as far as the amounts which go into solution are concerned. The
+proportion of water to soil is not immaterial, however, considering the
+chemical nature of the soil components and the results of experiment.
+Consequently, it is clear that the concentration of the soil solution
+is not simply the ratio of the amounts found in the aqueous extract, to
+the percentage of moisture in the soil, but something quite different.
+
+Artificial solutions prepared in the manner described above should,
+however, furnish evidence as to whether or not there are recognizable
+differences in the soluble mineral constituents of good and poor
+soils respectively; and if such differences exist, whether they are
+consistent. That is to say, if the more productive soils also uniformly
+yield aqueous extracts of a higher concentration, then it would be a
+fair inference that their natural soil solutions are maintained at a
+higher concentration than in the less productive soils.
+
+Results obtained for several localities and several crops, taken from
+the original records, are given in the following tables.[61]
+
+[61] The chemistry of the soil as related to crop production, by Milton
+Whitney and F. K. Cameron, Bull. No. =22=, Bureau of Soils, U. S. Dept.
+Agriculture, 1903.
+
+ WATER SOLUBLE CONSTITUENTS OF SOIL.
+
+ Locality, Salem, N. J. Soil type, Norfolk sand. Crop, wheat.
+ Yield, good.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | Per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ March 10 | 0-12 | 13.2 | 12 | 5 | 12
+ | 12-24 | 11.5 | 7 | 5 | 16
+ June 8 | 1-24 | 4.3 | 4 | 14 | 13
+ June 13 | 1-24 | 4.6 | 5 | 13 | 17
+ June 19 | 1-24 | 9.6 | 2 | 14 | 24
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, Salem, N. J. Soil type, Norfolk sand. Crop, wheat.
+ Yield, poor.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | Per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ April 3 | 0-12 | 12.0 | 11 | 5 | 32
+ | 12-24 | 12.0 | 10 | 3 | 22
+ June 16 | 1-24 | 9.3 | 4 | 29 | 20
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, Salem, N. J. Soil type, Sassafras loam. Crop, wheat.
+ Yield, medium.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ March 10 | 0-12 | 23.2 | 19 | 10 | 8
+ | 12-24 | 21.6 | 11 | 10 | 14
+ March 14 | 0-12 | 22.3 | 18 | 8 | 18
+ | 12-24 | 20.2 | 15 | 12 | 21
+ | 24-36 | 20.3 | 18 | 17 | 16
+ March 20 | 0-12 | 19.3 | 7 | 10 | 21
+ | 12-24 | 18.6 | 4 | 11 | 21
+ | 24-36 | 12.6 | 5 | 12 | 21
+ June 16 | 1-24 | 22.5 | 4 | 14 | 23
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, Salem, N. J. Soil type, Sassafras loam. Crop, grass.
+ Yield, fair.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | Per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ March 10 | 0-12 | 25.0 | 13 | 28 | 18
+ | 12-24 | 23.8 | 7 | 26 | 13
+ | 24-36 | 19.9 | 16 | 8 | 15
+ March 14 | 0-12 | 25.8 | 21 | 12 | 21
+ | 12-24 | 23.1 | 8 | 12 | 15
+ | 24-36 | 21.8 | 9 | 15 | 21
+ March 31 | 0-12 | 23.0 | 11 | 23 | 43
+ | 12-24 | 21.6 | 8 | 20 | 34
+ April 2 | 0-12 | 24.8 | 8 | 16 | 41
+ | 12-24 | 24.0 | 6 | 21 | 38
+ | 24-36 | 21.4 | 3 | 11 | 25
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, Salem, N. J. Soil type, Sassafras loam. Crop, wheat.
+ Yield, good.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄ | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ March 17 | 0-12 | 22.0 | 8 | 6 | 10
+ | 12-24 | 18.1 | 8 | 15 | 14
+ March 17 | 0-12 | 18.3 | 10 | 15 | Lost
+ | 12-24 | 18.1 | 9 | 24 | 25
+ March 24 | 0-12 | 24.7 | 14 | 12 | 30
+ | 12-24 | 22.3 | 8 | 11 | 38
+ March 26 | 0-12 | 23.4 | 4 | 16 | 16
+ | 12-24 | 23.9 | 12 | 16 | 20
+ | 24-36 | 22.4 | 8 | 3 | 21
+ April 2 | 0-12 | 25.6 | 8 | 16 | 30
+ | 12-24 | 24.4 | 8 | 17 | 47
+ | 24-36 | 21.6 | 8 | 11 | 38
+ June 5 | 0-12 | 5.2 | 14 | 51 | 23
+ | 12-24 | 8.0 | 15 | 55 | 32
+ June 8 | 1-24 | 10.6 | 2 | 20 | 13
+ June 11 | 1-24 | 15.5 | 6 | 26 | 14
+ June 13 | 1-24 | 8.2 | 6 | 19 | 22
+ June 16 | 1-24 | 15.0 | 5 | 21 | 19
+ June 17 | 1-24 | 10.6 | 7 | 63 | 17
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, Salem, N. J. Soil type, Sassafras loam. Crop, clover.
+ Yield, fair.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ March 20 | 0-12 | 20.8 | 5 | 15 | 32
+ | 12-24 | 20.2 | 5 | 15 | 27
+ | 24-36 | 18.6 | 5 | 12 | 36
+ March 26 | 0-12 | 26.8 | 9 | 31 | 20
+ | 12-24 | 22.9 | 8 | 20 | 18
+ | 24-36 | 22.5 | 4 | 14 | 20
+ June 6 | 0-12 | 8.1 | 8 | 16 | 17
+ | 12-24 | 12.7 | 9 | 18 | 20
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, St. Marys, Md. Soil type, Leonardtown loam. Crop, wheat.
+ Yield, good.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ April 27 | 0-12 | 21.8 | 5 | 10 | 12
+ | 12-24 | 21.3 | 4 | 7 | 10
+ April 29 | 0-12 | 22.2 | 8 | 15 | 52
+ | 12-24 | 21.8 | 4 | 11 | 38
+ May 1 | 0-12 | 22.4 | 7 | 14 | 23
+ | 12-24 | 21.8 | 7 | 8 | 30
+ May 1 | 0-12 | 17.0 | 5 | 16 | 25
+ | 12-24 | 21.0 | 5 | 7 | 19
+ May 9 | 0-12 | 15.0 | 13 | 34 | 28
+ | 12-24 | 15.9 | 9 | 17 | 26
+ May 15 | 0-12 | 14.2 | 3 | 14 | 24
+ | 12-24 | 19.9 | 4 | 13 | 25
+ August 14| 0-24 | 15.0 | 6 | 11 | 13
+ August 15| 0-24 | 15.7 | 5 | 3 | 17
+ August 15| 0-24 | 16.4 | 8 | 15 | 15
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, St. Marys, Md. Soil type, Leonardtown loam. Crop, wheat.
+ Yield, poor.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ May 14 | 0-12 | 14.7 | 5 | 8 | 35
+ | 12-24 | 19.9 | 4 | 4 | 30
+ May 23 | 0-12 | 7.8 | 4 | 7 | 22
+ | 12-24 | 14.9 | 4 | 11 | 23
+ August 14| 0-24 | 16.0 | 4 | 4 | 16
+ August 15| 0-24 | 19.5 | 6 | 4 | 13
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, St. Marys, Md. Soil type, Leonardtown loam. Crop, corn.
+ Yield, good.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ May 8 | 0-12 | 18.2 | 9 | 12 | 29
+ | 12-24 | 18.9 | 10 | 7 | 26
+ May 18 | 0-12 | 18.2 | 3 | 24 | 38
+ | 12-24 | 18.8 | 6 | 19 | 28
+ August 8 | 0-24 | 17.5 | 7 | 30 | 18
+ ---------+-------+----------+-------------+---------+---------------
+
+ Locality, St. Marys, Md. Soil type, Leonardtown loam. Crop, corn.
+ Yield, poor.
+ =========+=======+==========+=======================================
+ | | | Parts per million of oven-dried soil
+ | Depth | Moisture +-------------+---------+---------------
+ Date | inches| content | Phosphoric | Calcium | Potassium
+ | | per cent.| acid (PO₄) | (Ca) | (K)
+ ---------+-------+----------+-------------+---------+---------------
+ May 23 | 0-12 | 16.6 | 5 | 12 | 22
+ | 12-24 | 17.4 | 6 | 8 | 22
+ August 8 | 0-24 | 19.9 | 9 | 25 | 20
+ August 15| 0-24 | 21.6 | 7 | 15 | 13
+ ---------+-------+----------+-------------+---------+---------------
+
+It will be observed that the results given in the above tables are
+expressed in parts per million of oven-dried soils, in order to have
+some definite basis of comparison, and because it was anticipated
+at the time the investigation was made that larger quantities of
+dissolved minerals would be found under the better crops, and _vice
+versa_. An inspection of the results, however, shows that no such
+correlation can be made, nor in fact can any consistent correlation be
+made between the dissolved material and crop, soil type, water content,
+depth of soil or part of the growing season.[62] It appears, therefore,
+that in so far as the field method of analyzing an arbitrarily prepared
+aqueous extract is competent, there is no evidence that there are
+important characteristic differences in the concentration of the
+mineral constituents in different soil solutions in the field.
+
+[62] King, however, claims that the concentration of the soil solution
+with respect to mineral plant nutrients, is higher in the soils of
+the northern states than in the soils of the South Atlantic states.
+See: Some results of investigations in soil management, by F. H. King,
+Yearbook, U. S. Dept. Agriculture, 1903, p. 159-174. Bailey E. Brown
+has obtained some preliminary results which suggest that there may
+be seasonal variations with respect to some of the dissolved mineral
+constituents. See, Annual Report of the Pennsylvania State Experiment
+Station, 1908-9, pp. 31 _et seq._
+
+The order of concentration of the soil solution can be approximated
+from the given data, if the assumption be made that in the preparation
+of the aqueous extract, soluble mineral constituents are of minor
+importance, other than the constituents already dissolved in the soil
+solution. The calculation is very laborious, is not exact, and on
+account of the assumptions made the actual figures obtained are of no
+especial value in any particular case. Remembering the method of making
+up the solutions from which these results were obtained, it would be
+sufficiently near the truth to assume an average moisture content of 20
+per cent., when the figures given here for the soil approximate those
+which would be obtained for the soil solution. More exact calculations
+have been made for a large number of such cases, and it has been
+found from this method of estimation that the average composition
+with respect to phosphoric acid would be about 6-8 parts per million,
+and for potash about 25 parts per million, figures which agree with
+the results obtained for the examination of solutions extracted from
+saturated soils by means of the centrifuge.
+
+The results given in the foregoing tables were obtained under
+great difficulties, and in some part the variations they show are
+undoubtedly due to inevitable inaccuracies of analytical work done
+under such circumstances. Some of the variations may also be due to
+the disturbing influences in the soil referred to above. Experience
+has shown, however, that the preparation of an aqueous extract of the
+soil of any particular field is by no means a simple matter. Extracts
+made from samples taken within a few feet of one another frequently
+show variations of the same order as with samples from entirely
+different fields, or even soil types. Differences in the preliminary
+drying out of the sample before the addition of the water, seems to
+result in the same order of differences as obtained between different
+soils. In consequence of these facts, and of the further fact that an
+arbitrary aqueous extract of a soil cannot be assumed to represent in
+any definite way the natural soil solution, the results of the field
+examination are inconclusive as to the concentration of the soil
+solution _in situ_. It is more necessary, therefore, that other lines
+of evidence should be sought as to the mineral characteristics and
+concentration of the soil solution. Such a line of evidence is found in
+certain percolation experiments.[63]
+
+[63] The absorption of phosphates and potassium by soils, by Oswald
+Schreiner and George H. Failyer, Bull. No. =32=, Bureau of Soils, U. S.
+Dept. Agriculture, 1906.
+
+If a solution of a soluble phosphate be percolated through a soil, a
+part of the phosphate will be removed from the solution and absorbed
+by the soil; that is, there will be a redistribution of the phosphate
+between the soil and the water. As the process continues, however,
+relatively less and less phosphate is absorbed by the soil and the
+concentration of the percolate becomes more and more nearly that of
+the added solution. This absorption takes place more or less closely
+in accordance with the simple law that the absorption of phosphates by
+the soil, per unit of solution which is percolating, is proportional
+to the total amount of phosphate which the soil may yet take from that
+solution if percolated indefinitely. This law is expressed by the
+equation
+
+ _dy_
+ —————— = _K_(_A_ - _y_)
+ _dx_
+
+where _y_ is the amount absorbed, _x_ amount of solution that has
+passed, and _A_ is the total amount which can ultimately be absorbed
+by that particular soil from that particular solution. _K_ is also a
+characteristic constant. If the percolation be maintained at constant
+rate, then _t_, time, can be substituted for _x_ and the equation
+becomes
+
+ _dy_
+ ———— = _K_(_A_ - _y_),
+ _dt_
+
+the ordinary rate equation for a mono-molecular reaction of the first
+order, whether chemical or physical.
+
+With such absorptions as are involved in soils, a clay exposes a
+greater amount of absorbing surface than does a loam or sand, and it
+will show the greatest absorption towards any particular solution,
+other things being equal. The curve showing the concentration of
+percolate would lie lower for a clay than for a loam, or for a sand.
+This is illustrated in the accompanying sketch diagram, where _y_
+represents concentration of percolate and _t_ represents time.
+
+[Illustration: Fig. 1.]
+
+If after percolation has proceeded for some time (in some experiments
+for several weeks and until the soil contained 1 or 2 per cent. of
+phosphoric acid) pure water be passed through the soil, then, as soon
+as the previously used phosphate solution has been displaced, the
+concentration of the percolate drops and continues practically constant
+for an indefinite period. Moreover, no matter what the soil may be
+as to texture or composition, the same concentration of percolate is
+obtained, namely, 6-8 parts per million, the concentration which the
+soils yielded prior to treatment with the phosphate solution. Similar
+experiments when the soils were treated with salts of potassium have
+given like results, although the curves obtained from passing pure
+water through the soils do not lie quite so close together; but the
+concentration of the percolate with respect to potassium generally
+lies somewhere between 25 and 30 parts per million.
+
+The removal of a soluble constituent from the soil by percolating water
+appears to be described by a rate equation similar to that given above
+for absorption. If the rate of percolation be maintained constant this
+formula is
+
+ _dx_
+ ————— = _K_(_B_ - _x_)
+ _dt_
+
+where _x_ is the amount removed by the percolation, with time _t_,
+_K_ is a constant characteristic for the particular system under
+consideration, and _B_ is the total amount of the constituent which may
+ultimately be leached out. In other words, the rate in any particular
+soil will depend upon the amount of the constituent still absorbed in
+that soil but has no necessary connection with the rate which would
+hold for the same amount of the constituent in any other soil.
+
+Theoretically, two consequences follow from this law which require
+consideration here. The rate at which a constituent is removed
+gradually becomes less as percolation proceeds. If the soil contains
+an amount of the constituent approaching the total amount which it
+can absorb, as for instance is probably the case sometimes when large
+applications of lime have been made to the soil, the concentration
+of the percolating solution might be expected to change noticeably.
+Generally, however, a soil contains nowhere near as much phosphoric
+acid or potassium as it is capable of absorbing, so that the
+concentration of the percolating water changes but very little with
+respect to these constituents. It follows from the equation that
+if percolation continues uninterrupted, the concentration of the
+percolate, so far as it is determined by an absorbed constituent, must
+get less and less until it becomes a vanishing quantity. This state
+of affairs does not exist in the soil, however, for percolation by
+pure water does not continue uninterrupted for any length of time. The
+rise of the capillary water in the soil will, under normal conditions,
+enable the soil to reabsorb more of the ordinary mineral constituents
+than is removed by percolating waters. Further attention will be given
+the matter in another chapter.
+
+[Illustration: Fig. 2.]
+
+Another but quite different line of evidence as to the probable
+concentration of the soil solution is furnished by the investigation of
+the solubility of certain phosphates.[64] It is popularly supposed that
+when superphosphate containing mono-calcium phosphate, CaH₄(PO₄)₂.H₂O,
+is added to a soil there is a more or less permanent increase of
+readily soluble phosphoric acid in the soil, although a part “inverts”
+to the somewhat less soluble dicalcium phosphate, Ca₂H₂(PO₄)₂·2H₂O.
+Such probably is far from a correct view of what actually takes place.
+The results obtained by studying the solubility of the different lime
+phosphates in water at ordinary temperature (25° C.) can be expressed
+in a diagram similar to the accompanying sketch, which is much
+distorted for convenience in lettering. As the diagram indicates, when
+the concentration of the solution increases with respect to phosphoric
+acid, the lime is at first less and less soluble until the point
+represented by _B_ is reached, then becomes more and more soluble until
+the point _D_ is reached, from then on becoming less and less soluble,
+until the solution reaches a syrupy consistency. In contact with all
+solutions represented by points on the line _DE_ the stable solid
+substance which can exist is mono-calcium phosphate, CaH₄(PO₄)₂.H₂O.
+Along the line _CD_ the only solid which is stable and can continue to
+persist is the dicalcium phosphate. From the point _C_ the composition
+of the stable solid varies continuously with the concentration of the
+liquid solution. Therefore, these solids form a series varying in
+composition from pure dicalcium phosphate to pure calcium hydroxide.
+One of these basic phosphates, as they would ordinarily be called, has
+a less solubility than any other, as indicated by the point _B_. All
+solutions to the right of the point _B_ have an acid reaction, while
+all solutions to the left possess an alkaline reaction. It follows from
+these facts that if we start with any lime phosphate corresponding
+to some point to the right of _B_ and dilute it, or what amounts to
+the same thing in case it has been added to the soil, if we leach it,
+phosphoric acid will go into solution more rapidly than will lime until
+the composition of the residue is that of the basic phosphate stable at
+_B_. Similarly, if we start with a phosphate more basic, lime will be
+removed more rapidly than phosphoric acid, until the residue has the
+composition of the phosphate of lowest solubility. From this point,
+with continued leaching, the lime and phosphoric acid will dissolve
+in a definite ratio, which ratio is obviously that of the phosphate
+of least solubility. That is to say, if the leaching process is slow,
+as would be the case under soil conditions, the solution would have a
+perfectly definite concentration with respect to lime and phosphoric
+acid. What the ratio of lime to phosphoric acid may be, is of no
+particular interest in this connection, but the order of concentration
+of phosphoric acid is of interest. Owing to serious analytical
+difficulties, this has not yet been determined with any great
+precision, but by interpolating on the experimentally determined curve
+_AC_, this concentration is found to be somewhere in the neighborhood
+of 5-10 parts per million, figures close to those obtained for the
+concentration of the soil solution with respect to phosphoric acid by
+the previously described investigations.
+
+[64] For reference to the literature and detailed discussion see: The
+action of water and aqueous solutions upon soil phosphates, by F. K.
+Cameron and J. M. Bell, Bull. No. =41=, Bureau of Soils, U. S. Dept.
+Agriculture, 1907.
+
+Under ordinary circumstances, however, it is not probable that lime
+is the dominant base controlling the concentration of phosphoric
+acid in the soil solution, since the great majority of agricultural
+soils contain vastly more ferric oxide (more or less hydrated) than is
+equivalent to any amount of phosphoric acid that will ever be brought
+into the soil; and ferric phosphates are less soluble relatively than
+lime phosphates. Investigation of the relation of ferric oxide to
+solutions of phosphoric acid shows that the system is quite similar in
+many respects to the basic lime phosphates and water just described.
+When the ratio of iron to phosphoric acid in the solid is greater
+than that required by the formula of the normal phosphate, FePO₄, the
+aqueous solution will have an acid reaction and contain a mere trace
+of iron and an amount of phosphoric acid determinedly the composition
+of the solid and by the proportion of solid to water. The basic ferric
+phosphates seem to be solid solutions which yield a very dilute aqueous
+solution when brought into contact with water. What the concentration
+will be under soil conditions is shown by the percolation experiments
+cited above.
+
+The addition of other substances will in many cases affect more
+or less the solubility of the soil minerals. If these substances
+be electrolytes, they will generally, but not always, affect the
+solubility of the minerals as would be anticipated from the hypothesis
+of electrolytic dissociation. Thus, the addition of potassium sulphate
+lessens the solubility and hydrolysis of a potash feldspar or a
+potash mica. Contrary, however, to the indications of the hypothesis,
+sodium nitrate decreases the solubility of a ferric phosphate. While
+appreciable solubility effects take place with sufficiently high
+concentrations, laboratory experiments indicate that the addition of
+such substances, even in a liberal application of fertilizers, is not
+sufficient to produce any great effect on the concentration of the
+soil solution. Similarly, it has often been supposed that the ammonia,
+and nitrous and nitric oxides of the atmosphere carried into the
+soil by rain, or formed in the soil by bacterial action, affect the
+solubility of the soil minerals, but it is highly improbable that the
+concentration with respect to these agents ever becomes sufficiently
+high, as laboratory investigations show to be necessary to affect
+appreciably the solubility of the ordinary rock- or soil-forming
+minerals.
+
+Rain brings from the atmosphere into the soil two agents, however,
+which do markedly affect the solubility of the soil minerals, namely,
+oxygen and carbon dioxide. The atmosphere within the soil contains
+normally a somewhat smaller proportion of oxygen than does the air
+above the soil. Rain in falling through the air absorbs or dissolves
+relatively more oxygen than nitrogen. Therefore when the rain water
+has penetrated the soil to any considerable depth there should be,
+and probably is, a liberation of dissolved oxygen into the atmosphere
+of the soil interstices. This dissolved oxygen in becoming liberated
+or when dissolved in the film water appears to be especially active
+towards the ferrous or ferro-magnesian silicates. These minerals are,
+moreover, as a class probably the most soluble of the rock-forming
+silicates. Consequently oxygen brought into the soil in this manner is
+one of the most important agencies in breaking down and decomposing
+such minerals as the amphiboles, pyroxenes, chlorites, certain
+serpentines, phlogopites and biotites; at the same time there is
+formed ferric oxide (more or less hydrated) and silica (probably as
+quartz) and magnesium, potassium, calcium or sodium pass into solution,
+probably as bicarbonates. That the concentration of the soil moisture
+may thus be made temporarily abnormal is not impossible, though
+scarcely probable.
+
+The soil atmosphere has normally a decidedly higher content of carbon
+dioxide than the atmosphere above the soil. Consequently the soil water
+is always more or less “charged” with carbon dioxide, and the presence
+of the carbon dioxide decidedly augments the solvent powers of the
+water towards a great many and different kinds of rock-forming or soil
+minerals.[65]
+
+[65] For references to the literature see Bull. No. =30=, Bureau of
+Soils, U. S. Dept. of Agriculture; also, The action of carbon dioxide
+under pressure upon a few metal hydroxides at 0° C., by F. K. Cameron
+and W. O. Robinson, Jour. phys. chem., =12=, 561-573, (1908); The
+influence of colloids and fine suspensions on the solubility of gases
+in water, Part I. Solubility of carbon dioxide and nitrous oxide, by
+Alexander Findlay and Henry Jermain Maude Creighton, Trans. Chem. Soc.,
+=97=, 536-561, (1910).
+
+What the mechanism of the reaction may be is far from clear. The
+obvious explanation, at least in the case of the ordinary silicates of
+the alkalis or alkaline earths, is that by forming bicarbonates of the
+hydrolyzed bases, the active mass of the reaction product with water
+is decreased and hydrolysis thereby increased. But this explanation is
+apparently insufficient to account for the effects sometimes observed.
+It has been shown that the passage of carbon dioxide through solutions
+of the silicates, will produce more or less slowly a precipitation of
+silica, and there seems little reason to doubt that it does induce to
+some degree a decomposition and consequent greater solubility of the
+silicates of the alkalis and alkaline earths. It also increases to an
+appreciable extent the solubility of the phosphates of iron, alumina,
+and lime. Therefore, the variation in the content of carbon dioxide in
+different soils, and its continual variation from time to time in any
+one soil, must be expected to produce corresponding changes in the soil
+solution with respect to such bases as potassium and lime, and also
+with respect to phosphoric acid. This has been verified experimentally
+with aqueous extracts of soils, the solutions being charged with carbon
+dioxide while in contact with the soils.[66] It is not conceivable,
+however, that any great difference can exist in the partial pressures
+of carbon dioxide in different soils which are in a condition to
+support crops, and therefore great absolute differences in the mineral
+content of the soil solution are not to be anticipated, nor are they
+actually observed.
+
+[66] See, for instance, the results obtained by Peter, Proceedings of
+the 19th Annual Convention of the Association of American Agricultural
+Colleges and Experiment Stations, Bull. No. =164=, Office of Experiment
+Stations, U. S. Dept. Agriculture, 1906, p. 151 _et seq._
+
+It has long been held that the organic substances in the soil have an
+important solvent effect on the minerals. This assumption seems quite
+unwarranted in the light of our present knowledge, although it is
+not to be denied that occasionally there may be present in the soil
+some soluble organic substance which influences the mineral content.
+Generally it has been assumed that the effective organic substances
+influencing the solubility of the minerals are organic acids, of which
+a number have found their way into past and even current literature,
+and which have been designated as humic, ulmic, crenic, apocrenic,
+azohumic acids, etc. Their existence has been predicated upon two
+facts: First, humus is soluble in alkaline solutions but is more or
+less completely reprecipitated on the addition of an excess of a
+strong mineral acid, a phenomenon also characteristic of many organic
+acids. But many other organic substances than acids are also soluble
+in the presence of alkalis and insoluble in the presence of an excess
+of strong mineral acids. Second, organic-copper complexes have been
+obtained from humus constituents, and supposed to be copper salts of
+various humus acids. The descriptions of these complexes so far given
+do not show that they met the usual criteria for definite compounds,
+but indicate on the contrary that they were the results of absorption
+or possibly adsorption phenomena. Consequently the existence of
+“humic” acids is purely hypothetical and without experimental or other
+scientific verification, and calls for no further consideration here.
+
+It is a widespread and popular notion that substances with a slight
+solubility also dissolve slowly, and that consequently the solubility
+of the minerals in the soil water must necessarily be a very slow
+process. This is, however, a misapprehension. It has been shown with a
+number of the common rock-forming minerals, that if they be powdered
+and then stirred into a relatively small volume of water, they dissolve
+very rapidly at first, and in a very short time, generally a few
+minutes, the solution is nearly saturated with respect to the mineral.
+Complete saturation, however, may require many days. The general shape
+of curve expressing the rate of solubility is shown in the accompanying
+figure.[67] For soils, this fact has been verified repeatedly, in the
+following way: A cell fitted with parallel electrodes is placed in
+circuit with a slide-wire[68] or Wheatstone bridge in such a manner
+that the resistance of the cell contents can be quickly determined.
+Distilled water is then placed in the cell and its resistance found.
+Generally this will be upwards of 100,000 ohms. The soil or rock
+powder under examination is then added to the cell, being rapidly
+stirred into the water contained therein. The resistance drops to
+about 5,000 ohms within a short space of time, usually three or four
+minutes. A further slight drop in the resistance generally takes place,
+but it requires days, and sometimes even months to become more than
+barely appreciable. In this manner it has been shown that the soil
+and many of the common soil minerals dissolve quite rapidly if they
+are sufficiently fine to offer a large surface to the action of the
+water. It would seem to follow, therefore, that in the case of the soil
+solution the concentration with respect to these constituents derived
+from the soil minerals, will be rapidly restored whenever disturbed
+through absorption by plants, leaching, or otherwise.
+
+[67] See, for example, Umwandlung des Feldspars in Sericit
+(Kaliglimmer) von Carl Benedick, Bull. Geol. Inst. Upsala, =7=,
+278-286, (1904).
+
+[68] See Electrical instruments for determining the moisture,
+temperature and soluble salt content of soils, by L. J. Briggs, Bull.
+No. 15, and the electric bridge for the determination of soluble salts
+in soils, by R. O. E. Davis and H. Bryan, Bull. No. =61=, Bureau of
+Soils, U. S. Dept. Agriculture.
+
+[Illustration: Fig. 3.]
+
+That the minerals of the soil, or a powdered mineral or rock-powder,
+will dissolve continually as the concentration of the solution in
+contact with it is disturbed by abstraction of a dissolved mineral
+substance, has been shown by numerous experimenters. An apparently
+obvious way to test this point would be to treat the soil sample
+with successive portions of water, and to analyze the successive
+portions for the dissolved mineral substances. This method, however,
+involves serious experimental difficulties, owing to the smaller
+sized mineral particles being suspended in the mother liquor, thus
+precluding satisfactory decantation and clogging filters. Moreover,
+such a process in no case simulates field conditions. To meet these
+difficulties, the soil or mineral powder has been placed between two
+porous media, as in the space between two concentric cylinders of
+unglazed porcelain, the space being closed by a rubber stopper. To the
+interior cylinder is fitted a stopper carrying a tube of insoluble
+metal, such as platinum or tin. This tube is bent into a goose-neck
+form, and just below the stopper the tube is perforated with a small
+opening. The whole apparatus is filled with water and set in a beaker,
+also filled with water. The metal tube is made the cathode in an
+electric circuit, a platinum or other suitable anode being introduced
+into the beaker. In a few minutes the dissolved and hydrolyzed bases
+pass into the cathode chamber, and as the water also accumulates in the
+chamber by electrolytic endosmosis, a solution of the bases dissolved
+from the soil minerals drops from the end of the metal goose-neck. By
+adding water to the outer beaker from time to time, a steady stream
+of alkaline solution has been obtained for months, and in no case yet
+has a soil thus treated failed to continue to yield up the bases it
+contains in its mineral particles. The acids, such as phosphoric acid
+for example, are of course found in the water outside the porous cells,
+and in the case of the phosphoric acid it also appears to continue
+indefinitely to be withdrawn from the soil.[69] It thus appears that
+as the products of solution and hydrolysis are removed, by such an
+endosmotic device as that just described or by the roots of growing
+plants, by leaching or otherwise, the soil minerals will continue to
+dissolve.
+
+[69] For detailed description of the apparatus and experimental data,
+see Bull. No. =30=, p. 27, _et seq._, Bureau of Soils, U. S. Dept.
+Agriculture.
+
+The foregoing arguments as to the concentration of the soil solution
+with respect to those constituents derived from the soil minerals, are
+based on the generally recognized principle that a material system
+left to itself tends towards a condition of stable equilibrium or
+final rest, that is, a condition where such changes as are taking
+place are so balanced that no change occurs in the system as a whole.
+But the soil is a system continually subject to outside forces and
+influences, and as pointed out above, is of necessity a dynamic
+system. It is doubtful in the extreme if any soil in place is ever in
+a state of final stable equilibrium. It would be natural, therefore,
+to expect and to find that even if the solution in the soil were
+dependent on the solubility of the soil minerals alone and were
+continually tending towards a definite normal concentration, actually
+this concentration would seldom if ever be realized. Most important
+in this connection is the fact that the concentration of the soil
+solution is always dependent in some degree upon the concentration of
+the soluble constituents in the solid phases in other than definite
+chemical combinations. Other factors affecting the concentration of
+the mineral constituents in the soil solution are always existent, and
+theoretically at least, can not be ignored. Nevertheless _a priori_
+reasoning as well as the experimental evidence at hand indicates
+that the various processes taking place in the soil as a whole
+continually tend to form and maintain a normal concentration of mineral
+constituents in the soil solution.
+
+
+
+
+Chapter VIII.
+
+ABSORPTION BY SOILS.
+
+
+A property of soils, affecting profoundly the composition and
+concentration of the soil solution, is absorption.[70] It is generally
+recognized that soils are good absorbers for vapors, and this fact
+finds practical expression in the common practice of burying things
+with a disagreeable odor, such as animal carcasses, night-soil, etc. It
+is also well-known that dissolved as well as suspended material can be
+more or less completely removed from water by passing it through sand
+or soil, and this fact finds important application in water supplies
+for cities and towns, sewage disposal, etc. It was known as long ago
+as Aristotle’s time that ordinary salt is partly removed from water by
+passing through sand or soil. In recent times the practical as well
+as theoretical importance of this phenomenon has led to considerable
+study and experimental research, so that our knowledge of absorption
+effects is now fairly extensive, though it can hardly be claimed that
+it is satisfactory. The absorption of a dissolved substance from
+solution by a soil may be one or more of at least three kinds of
+phenomena. It may be a mechanical inclusion or trapping, distinguished
+by the term _imbibition_, the most familiar and striking case being
+the absorption of water itself by soil or sponge or similar medium. It
+may be a partial taking up of the dissolved substance to form a new
+compound or a _solid solution_,[71] as probably is the absorption of
+phosphoric acid by lime or ferric oxide. Or it may be a condensation
+or concentration of the dissolved substance on or about the surface
+of the absorbing medium, a phenomenon known as _adsorption_. To prove
+the existence of adsorption definitely and conclusively in any given
+case is always difficult, if ever possible, but the existence of this
+phenomenon is the most logical explanation of many observations, and is
+generally admitted by chemists and physicists at the present time.[72]
+It is by adsorption, probably, that potash and ammonia are held by the
+soil when added in fertilizers.
+
+[70] For a detailed discussion and citations of the literature, see:
+Absorption of vapors and gases by soils, by H. E. Patten and F. E.
+Gallagher, Bull. No. =51=; and Absorption by soils, by H. E. Patten
+and W. H. Waggaman, Bull. No. =52=, Bureau of Soils, U. S. Dept.
+Agriculture, 1908.
+
+[71] That is, a homogeneous solid, which may be either crystalline or
+amorphous. Probably the readiest criterion for distinguishing between
+a definite compound and a solid solution, is that the former is stable
+in contact with a liquid solution of its constituents over a measurable
+range of concentrations, while the composition of the solid solution
+changes with every change in the concentration of the liquid solution
+in contact with it.
+
+[72] A clear and apparently indisputable case of adsorption has been
+noted by Patten (Some surface factors affecting distribution, Trans.
+Am. Electrochem. Soc., =10=, 67-74, (1906). On adding powdered quartz
+to an aqueous solution of gentian violet, there is a distribution of
+the dye between the water and the quartz. A microscopic examination of
+the latter showed that the dye was concentrated in thin layers upon the
+surface of the quartz grains, from which it could be washed with water,
+no change in the quartz grains being noticeable.
+
+That absorption is dependent in some manner upon the solubility of the
+dissolved substance in the particular solvent employed would seem to
+be obvious. But what the relation may be, if it exists at all, is not
+known. For instance, silk absorbs picric acid from solutions in water
+and alcohol but not from solutions in benzene, although the solubility
+of picric acid in benzene lies between its solubility in water and in
+alcohol.[73]
+
+[73] Absorption of dilute acids by silk, by James Walker and James R.
+Appleyard, Jour. Chem. Soc., =69=, 1334-1349, (1896).
+
+The absorption of any given dissolved substance from different solvents
+is markedly different. Most soils absorb methylene blue from aqueous
+solutions with great avidity, but washing out the absorbed dye with
+water is an extremely tedious and unsatisfactory process, although the
+dye can be readily and more or less completely removed from the soil
+by alcohol. As might be anticipated from this, it is known that the
+presence of one dissolved substance affects the absorption of another,
+but in what way can not, generally, be anticipated, although it would
+seem that the importance of this subject for manurial practice would
+invite further research.
+
+From the same solution, different absorbents remove a dissolved
+substance in different degrees. Speaking generally, paper absorbs dyes
+more readily than do soils, while soils absorb bases more readily than
+does paper. Hence the reddening of litmus paper when in contact with a
+moist soil. Heavy soils or soils containing much hydrated ferric oxide
+absorb bases more readily than do light soils, but this is probably
+owing to relative amounts of surface exposed, for the same relation
+holds true with respect to phosphoric acid. Soils rich in humus are
+better absorbers than soils not so rich. But here again there is yet
+doubt as to whether the explanation lies in the amount or in the kind
+of surface acting.
+
+From the same solvent different dissolved substances are absorbed quite
+differently by any given absorbent. This can be readily illustrated
+again by dyes. If an aqueous solution of a mixture of methylene
+blue and sodium eosine, for instance, be shaken up with a soil, or
+percolated through a column of soil, the methylene blue is absorbed the
+more quickly and completely and a partial separation of the two dyes
+can be readily effected, the separation being more or less complete
+according to the conditions of the experiment. In the same manner two
+salts in solution can be separated partially at least.[74] Soils absorb
+potassium more readily than sodium; magnesium more readily than lime;
+and ammonia more readily than any of these bases.[75]
+
+[74] For a number of interesting examples, see, Ueber das Aufsteigen
+von Salzlösungen in Filtrirpapier, von Emil Fischer und Edward
+Schmidmer, Liebig’s Annalen der Chemie, =272=, 156-169, (1893).
+
+[75] The prompt absorption of a base by soils is shown by the following
+experiment: To some freshly boiled distilled water add several drops
+of alcoholic phenolphthalein, and then just enough base to produce
+a decided red color. If the solution be now passed through a short
+column of soil, cotton, shredded filter-paper or similar absorbent, the
+percolate will be perfectly colorless. The red color will be restored,
+however, by adding a little of the base to the percolate.
+
+The absorption from aqueous solutions of inorganic salts involves a
+most interesting complication. Just as a mixture of two or more dyes
+or salts in solution can be separated by the selective action of an
+absorbent, so can an electrolyte itself be decomposed or resolved.
+Thus, if a solution of potassium chloride be passed through a column
+of soil, or cotton, or paper, or any similar absorbent, the filtrate
+will not only be less concentrated than the original solution, but the
+potassium will be found to have been absorbed to a greater extent than
+the chlorine, that is, the percolate contains free hydrochloric acid.
+The importance of this phenomenon for the conservation of the desirable
+constituents of manurial salts, and the elimination or leaching out
+of the less desirable constituents is obviously great. Equally great
+perhaps, is the effect upon the reaction of the soil, whether it be
+rendered temporarily alkaline or acid, an effect of the very greatest
+importance for the growth of some of our common crop plants[76] and
+for the lower soil organisms, such as the bacteria, molds, together
+with ferments, enzymes, etc., many of which are very sensitive to the
+reaction of the media in which they may be, and which in turn are of
+undoubted importance in determining the fertility of the soil for
+higher plants.
+
+[76] See, The toxic action of acids and salts on seedlings, by F. K.
+Cameron and J. F. Breazeale, Jour. Phys. Chem., =8=, 1-13, (1904). It
+is quite conceivable, for instance, that if the drainage conditions
+were not exceptionally good under a heavy type of soil, it might be
+rendered temporarily unfit for clover or alfalfa by a heavy application
+of potassium salts or of sodium nitrate. The idea put forward by some
+authorities that too long continued or over fertilizing renders soils
+acid, may have better foundation than their theoretical reasoning would
+seem to warrant.
+
+The absorption of a dissolved substance from solution by an absorbent
+is in effect a distribution phenomenon and the simplest formula to
+give quantitative expression to such a distribution is C/C¹ = K when C
+is the concentration in the liquid phase and C¹ the concentration in
+the solid phase, K being a characteristic constant for the particular
+case under consideration. When a chemical reaction or a change of
+state, chemical or physical, is involved in the absorption in either
+dissolved substance or absorbent the formula becomes Cⁿ/C¹ = K when
+_n_ is a function which may be very simple or very complex. Attempts
+to develop a precise formula of this general type for the absorption
+by some given soil, although such a formula would be desirable for
+theoretical and practical reasons alike, have uniformly failed. A
+sufficient reason for this failure seems to lie in the fact that most
+dissolved substances produce an appreciable effect on the granulation
+or flocculation of the soil particles, which is progressive with
+the absorption so that a continual change of absorbing or effective
+surface is taking place as the absorption proceeds.[77] Moreover, in
+the case of an absorption, with the formation of a continuous film of
+the dissolved substance, a new kind of absorbing surface is developed.
+Hence _n_ is a function of so difficult a character as to defy thus far
+any attempt at formulation.[78]
+
+[77] That mineral fertilizers have a decided influence on the
+granulation of soils and the properties dependent thereon, and that
+this is of practical importance, is gradually coming to be recognized;
+see, for instance, Ein Beitrag zur Kenntnis der Wirkung künstlicher
+Dünger auf die Durchlässigkeit des Bodens für Wasser, von Edwin
+Blanck, Landw. Jahrb., =38=, 863-869, (1909), and the literature there
+cited. Dr. R. O. E. Davis in a yet unpublished investigation has shown
+that the addition of soluble salts produces decided effects upon the
+soil-moisture relations which affect crop production. The critical
+moisture content is displaced, the penetrability, permeability,
+specific volume, vapor tension, etc., are affected in measurable
+degree, and it appears that the physical functions of mineral
+fertilizers are much greater in amount and importance than has been
+popularly assumed.
+
+[78] The distribution of solute between water and soil, by F. K.
+Cameron and H. E. Patten, Jour. Phys. Chem., =11=, 581-593, (1907).
+
+We cannot therefore predict in any quantitative way what will be
+the distribution of a soluble substance such as salts in commercial
+fertilizers, for instance, between the solid soil particles and the
+soil solution. Empirical experiments show, however, that with the
+amount of a soluble salt present under normal conditions in a humid
+climate, or as used in fertilizer practice, the absorption of ammonia,
+lime, potassium or phosphoric acid is relatively very great, and in a
+general way in about the order named.
+
+Absorption is not an instantaneous process. However, the rate at
+which a dissolved substance is absorbed is generally quite rapid.
+That is, if a soil be stirred or mixed with an aqueous solution, the
+absorption takes place very quickly, in the absence of any outside
+disturbing influences. The law governing the rate of absorption by
+soils has not therefore possessed any great practical interest and
+has not been studied from a quantitative point of view, although it
+is known qualitatively that the rate is increased by increasing the
+concentration of the solution, or by increasing the amount of the
+absorbent or at least its effective surface. Two rate equations are
+of interest in this connection, and have been carefully studied. The
+rate at which a salt or other dissolved substance will advance into an
+absorbing soil from a solution is given by the same equation as that
+describing the rate of advance of the water itself, _yⁿ_ = _kt_ where
+_y_ is the distance and _t_ the time.[79] The constants _n_ and _k_
+for the slower moving dissolved substance are different from those for
+the water. This equation has probably little importance for ordinary
+agriculture, for absorption by the soil from a large (and relatively
+illimitable) mass of solution is unusual. That it may have considerable
+importance in seepage, irrigation, and some soil engineering problems,
+seems quite likely.
+
+The rate at which a soil will absorb a dissolved substance from a
+percolating solution is given by the equation
+
+ _dx_
+ ————— = K(A - _x_),
+ _dt_
+
+as has been pointed out above.[80] More interesting and important,
+however, is the fact that this same equation describes the rate at
+which an absorbed substance is removed from the soil by leaching. In
+the case of soils in humid areas _dx_/_dt_ rapidly becomes exceedingly
+small as _x_ approaches A, that is, when the amount of soluble material
+in the soil becomes small, and is practically constant under such
+conditions, as has been pointed out above when describing the removal
+of potassium and phosphoric acid from soils by percolating waters. This
+formula has a special interest in considering the reclamation of alkali
+lands by underdrainage, a problem to which reference will be made later.
+
+[79] See formula, page 28.
+
+[80] See formula, page 47.
+
+Both percolation experiments, as those cited above, and direct
+absorption experiments made by shaking up soils with solutions of the
+salts in question, show conclusively that the absorption phenomena
+taking place in the soil are in harmony with the direct solubility
+effects in tending to produce and maintain a solution of a normal
+concentration as regards those constituents which it happens are also
+derived from the soil minerals.[81] It is an interesting coincidence
+that nitric acid (in combination with various bases of course) is very
+little absorbed by most soils, and does vary in concentration, not
+only in different soils but in the same soil, between wide limits, and
+within short intervals of time.[82] The nitrates of the soil are not
+derived from minerals, and should more properly be considered with the
+organic constituents of the soil solution.
+
+[81] An extreme case is worth citing in this connection. Mr. W. H.
+Heileman in studying the influence of various kinds of alkali upon
+plant growth, added from 3-4 per cent. of sodium carbonate to soils
+known to be otherwise free from alkali. Wheat seedlings grown in the
+soils so treated showed no ill effects from the added salt. When
+distilled water was percolated slowly through the soils, or shaken up
+with them, the resulting solution contained the merest traces of the
+alkali.
+
+The ordinary method of determining the lime requirement of a soil
+by adding lime water until the solution shows an alkaline reaction,
+is another obvious absorption phenomenon, and is not dependent, as
+popularly supposed, upon the presence of acids in the soil. Soils which
+by no possibility could contain any free acid, frequently absorb very
+large amounts of lime in this manner.
+
+[82] Usually, in the growing season, the soil solution has a much
+higher concentration with respect to nitrates in the morning than it
+has in the evening.
+
+An important application of these views concerning absorption arises
+in connection with certain widespread notions concerning soil acidity.
+There is a popular belief that most soils are acid, that the soil
+solution contains some free acid, mineral or organic, other than
+dissolved carbon dioxide, and that a neutral or alkaline solution is
+necessary to the successful production of most of our crops. This
+belief is, however, unwarranted, for the vast majority of soils yield
+an aqueous extract which is alkaline when boiled to expel carbon
+dioxide, and some of our crops, for instance wheat, seem to thrive
+better in a slightly acid medium. This popular fallacy seems to have
+its origin in the fact that most soils when moistened and pressed
+against blue litmus paper, redden it. This reddening may sometimes
+be due to the actual presence of some acid, or to dissolved carbon
+dioxide, but is undoubtedly due in the majority of cases to selective
+absorption. Litmus is a red dye of an acid-like character, which forms
+a soluble blue salt with the ordinary bases. But it has been shown
+that most soils are better absorbents of bases than is paper, whereas
+paper is a better absorbent of dye, speaking generally, than is a soil.
+Consequently when moist soil is brought into contact with wetted blue
+litmus paper the base is absorbed more readily by the soil, and the dye
+by the paper, the latter therefore becoming reddened.
+
+The reddening of blue or “neutral” litmus paper can be accomplished
+with various absorbents. By pressing the litmus paper between moistened
+wads of absorbent cotton the reddening can be readily accomplished,
+usually in the course of ten minutes to a half hour. That the
+phenomenon is not due to any adhering acid on the cotton can be shown
+in the following way: A litmus solution is carefully prepared so that
+there is a very small excess of base present over that required to
+give the blue color. A wad of absorbent cotton is carefully washed by
+repeatedly sousing it in distilled water from which carbon dioxide has
+been expelled by boiling. When the cotton has been thoroughly washed,
+it is stirred thoroughly in a portion of distilled water, free from
+carbon dioxide, then withdrawn by some appropriate instrument and
+allowed to drain for a few minutes. The litmus is added in fairly large
+quantity to the drainings, which should then have a blue color. Again
+stir the cotton in the water, and more or less quickly, depending on
+the amount and purity of the litmus preparation as well as the quantity
+of cotton used, the solution will become red. The only criterion for
+determining surely that a soil is acid, is to make an aqueous extract,
+expel the dissolved carbon dioxide by boiling, or by passing through
+the solution an inactive gas, such as nitrogen, and then to test the
+reaction of the solution. Acid soils undoubtedly do exist, but they are
+by no means common or widespread, and are to be regarded as exceptional
+and abnormal.
+
+The phenomena of selective absorption suggest the important part which
+surfaces play in modifying and changing chemical reactions.[83] For
+instance, Becquerel[84] observed that a solution of copper nitrate or
+cobalt chloride diffusing from a cracked test-tube placed in a solution
+of sodium sulphide, led to the formation of the corresponding sulphide,
+but in the crack the metal itself was precipitated. Experiments of
+Graham[85] show that when a solution of silver nitrate is percolated
+through charcoal, not only is there a selective absorption as is shown
+by the percolate containing free acid, but there is a chemical reaction
+involved, since the silver is deposited in metallic spangles in the
+interstices of the absorbent. Graham has shown, and since his time
+others, that often metals can be separated from solutions of their
+salts by such absorbents as charcoal. Spring[86] has shown that at
+bounding surfaces of dilute solutions, chemical action is increased.
+
+[83] For references to the literature see, Bull. No. =30=, Bureau of
+Soils, U. S. Dept. Agriculture, p. 61 _et seq._
+
+[84] Note sur les réductions métalliques produites dans les espaces
+capillaires, par M. Becquerel, Comptes rendus, =82=, 354-356, (1876).
+
+[85] Effects of animal charcoal on solutions, by T. Graham, Quart.
+Jour. Sci., I, 120-125, (1830).
+
+[86] Über eine Zunahme chemischer Energie an der freien Oberfläche
+flüssiger Körper, von W. Spring, Zeit. physik. Chem., =4=, 658-662,
+(1889).
+
+It has been shown that the amount and kind of surface has a marked
+influence on the decomposition of hypochlorous acid, carbon dioxide,
+phosphine, arsine, and other compounds. Meyer and his associates, as
+well as a number of other investigators, have shown that the character
+of the surface of the containing vessel greatly affects the combination
+of hydrogen and oxygen. Many reactions have been investigated by van’t
+Hoff, who concludes that both the nature and amount of surface exposed
+have an influence. The inversion of sugar is affected by the nature
+of the walls of the containing vessel, and its reduction by Fehling’s
+solution is affected both by the walls of the vessel and the amount
+of cuprous oxide formed in the reaction. Alteration in the character
+as well as degree of a number of reactions by having them take place
+in capillary spaces has been observed by Liebreich, Becquerel,
+Lieving and other investigators. So-called “contact reactions,” as in
+the production of sulphuric acid, are now familiar processes finding
+commercial applications. And the solubility of some substances at
+least, notably gypsum, has been shown to vary considerably with the
+size and consequent shape of the particles in the solid substance in
+contact with its solution.[87]
+
+[87] See especially, Beziehungen zwischen Oberflächenspannung und
+Löslichkeit, von G. A. Hulett, Zeit. Phys. Chem., =37=, 385-406,
+(1901). Löslichkeit und Löslichkeits Beeinflussung, von V. Rothmund, p.
+109, (1907); Principles théoretiques des methodes d’analyse minerale,
+par G. Chesneau, p. 16-25, (1906).
+
+It has been shown that some soils will at times produce the blue
+coloration in alcoholic solutions of guiac, which is characteristic
+of oxidases, and yellow aloin solutions are sometimes colored red.
+Hydrogen peroxide is decomposed by some soils even after they have been
+thoroughly ignited to get rid of all organic matter. But in how far
+these effects may be due to surface influences can not be positively
+stated; yet uncompleted investigations by Dr. M. X. Sullivan indicate
+that some of these phenomena at least must be attributed to specific
+influences (although probably of catalytic character) of particular
+soil components, such possibly as manganous oxide or ferric oxide; but
+the mechanism of the reactions is as yet largely speculative.
+
+The soil is composed in large part of very fine particles of rounded
+shape, exposing relatively an enormous surface to the soil solution,
+and normally this solution is mainly under capillary conditions, so
+that we should expect that many reactions would take place quite
+differently in the soil from the way they would in a beaker or flask.
+This fact has been generally overlooked or ignored, and is probably
+the explanation of many of the apparently anomalous results hitherto
+reported in chemical investigations of soils. Abnormal solubilities,
+precipitations, oxidations or reductions are frequently found in the
+literature, and when their abnormality is noted at all, they are too
+often and with slight show of reason ascribed to indefinite bacterial
+action or more mysterious vital agencies. Many of them are undoubtedly
+the results of surface actions. Unfortunately, aside from some few
+studies of absorption phenomena, surface effects have received little
+or no attention from soil investigators, although obviously one of the
+most important and apparently fruitful fields, requiring immediate
+attention. Enough is known to justify the statement that the chemistry
+of the soil need not be, and probably is not, the chemistry of the
+beaker.
+
+
+
+
+Chapter IX.
+
+THE RELATION OF PLANT GROWTH TO CONCENTRATION.
+
+
+That the concentration of the mineral constituents in the soil solution
+under normal conditions is competent for plant support, is shown by
+numerous experiments. Birner and Lucanus[88] in an experiment that
+has long since become classic, found that they could raise wheat to
+maturity in a well-water, the concentration of which was approximately
+18 parts per million with respect to potassium, and 2 parts per million
+with respect to phosphoric acid, while the corresponding concentrations
+of the soil solution are normally about 25-30 parts per million of
+potassium and 6-8 parts per million of phosphoric acid. Nevertheless
+Birner and Lucanus report that the wheat grown in the well-water throve
+even better than that grown at the same time in a rich garden mold.
+Since then many investigators in numerous trials have obtained similar
+results. Recently wheat, corn, and some of the common grasses have been
+grown to a satisfactory maturity in tap water with a concentration
+of about 7 parts per million of potassium and 0.5 parts per million
+of phosphoric acid. And repeatedly wheat plants, grasses, cowpeas,
+vetches, potatoes and other plants have grown in a satisfactory way in
+solutions made by shaking up a soil in distilled water and separating
+from the solid particles by means of filters of unglazed porcelain.
+
+[88] Wasserculturversuche mit Hafer, von Dr. Birner und Dr. Lucanus,
+Landw. Vers.-Sta., =8=, 128-177, (1866).
+
+There can be no doubt, therefore, that the soil solution is normally
+of a concentration amply sufficient to support ordinary crop plants,
+and is maintained at a sufficient concentration, so far as mineral
+plant nutrients are concerned. Undoubtedly, however, variations in
+the concentration of the soil solution can, and often do, take place,
+and the results of laboratory experiment indicate that they probably
+produce effects on plants.
+
+It has been shown in water-culture experiments with wheat, that if a
+given ratio of mineral nutrients be maintained, relatively small effect
+is produced on the growing plants by varying the concentration over
+a wide range, in one case from 75 parts per million to 750 parts per
+million,[89] and this effect seems to be largely independent of the
+nature of the particular mixture of solutes. But varying the relative
+proportions of the mineral constituents has been shown by numerous
+experiments to produce very marked changes in the growth of plants.
+Not only does a control of the concentration and proportion of the
+mineral constituents of a solution produce a more rapid, or a slower
+growth, a greater or lesser total growth, but it produces differences
+in the character of growth; as for instance, causing the tops to grow
+relatively faster than the roots, or _vice versa_. However, many
+effects of this type can be produced, and sometimes more readily, by
+soluble organic substances, or mechanical agencies. The mechanism of
+these effects is by no means clear, in many cases. That other causes
+obtain than a sufficient supply of mineral nutrients will be shown
+in the following chapters. Experiments with wheat seedlings in water
+cultures, where the weights of the green tops were taken as the measure
+of growth, showed that the most-favorable ratio was one of phosphoric
+acid (PO₄) to three or four of potassium (K), about the ratio which has
+been found to exist normally in the soil solution of humid areas of
+the United States, namely, 6-8 parts per million of phosphoric acid to
+25-30 parts per million of potassium.
+
+[89] Effect of the concentration of the nutrient solution upon wheat
+cultures, by J. F. Breazeale, Science, n. s., =22=, 146-149, (1905).
+
+All growing plants require for their growth and development various
+organic compounds containing carbon, hydrogen, oxygen and nitrogen. The
+higher crop plants with which agricultural investigations appear to
+be more immediately concerned, seem to have inherent power to produce
+these needed substances within themselves. But it is becoming more and
+more evident that the large problem of soil fertility, or the relation
+of the soil to crop production, frequently if not generally involves
+the growth and development of lower organisms including ferments and
+bacteria. These may or may not in particular cases, favor the growth
+of the desired higher plants. Many of these lower organisms require
+certain organic compounds or thrive better if these are brought to
+them in the soil solution, and indeed evidence is not lacking that
+such may sometimes be the case even with the higher plants. Certainly
+their growth can be much affected by the presence of different organic
+substances in the nutrient solution. Enough work has been done in
+this field of investigation to show that the concentration of the
+soil solution or artificial nutrient solution with respect to the
+organic compounds must generally be low; too high a concentration
+always inhibits growth or even produces death; and there is probably
+an optimum concentration, or one at which the plant will grow best;
+but this optimum concentration varies with the specific nature of the
+plant, the presence of other dissolved substances, mineral or organic,
+and possibly with other factors. While a notable amount of work has
+thus been done in a field of inquiry obviously of practical as well as
+theoretical interest, almost no definite information has as yet been
+obtained as to the concentration of organic substances in the soil
+solution, or its effect upon plants under field conditions, excepting
+in the case of the nitrates, the products of bacterial activities. The
+concentration with respect to nitrates is known to vary greatly from
+a few parts to several thousand parts per million, and this sometimes
+within a few days or even hours. The great changes in concentration
+with respect to nitrates, the rapidity of the changes, and the
+correspondingly large effects on growing plants make this a subject
+requiring special treatment by itself. This at present seems more
+easily appreciated from a consideration of the bacteria involved, and
+will not be discussed more fully here.[90]
+
+[90] See: The fixation of atmospheric nitrogen by bacteria, by J.
+G. Lipman, Bull. No. =81=, Bureau of Chemistry, U. S. Dept. of
+Agriculture, 1904; A review of investigations in soil bacteriology,
+by Edward B. Voorhees and Jacob G. Lipman, Bull. No. =194=, Office of
+Experiment Stations, U. S. Dept. of Agriculture, 1907; The physiology
+of plants, by W. Pfeffer, translated by A. J. Ewart, vol. I, p. 388
+_et seq._, 1900; The effect of partial sterilization of soil on the
+production of plant food, by Edward John Russell and Henry Brougham
+Hutchinson, Jour. Agric. Sci., =3=, 111-144, (1909).
+
+Of the ash constituents of plants, there must be in the soil solution,
+potassium, magnesium, phosphorus, sulphur and iron for any plant
+growth, and for the higher crop plants, calcium must also be present.
+Of these, iron is usually present in barely appreciable concentration
+and more than this is not desirable, or is even harmful for common crop
+plants. Under the normal conditions for soils in humid areas, sulphur
+also is usually present in scarcely more than appreciable quantities
+and there is no positive evidence to show that higher concentrations
+are especially desirable, though this may be the case for certain
+crops, such for instance as the onion. Phosphorus is usually present
+to the extent of 5 or 6 parts per million of phosphoric acid (P₂O₅),
+while it has repeatedly been shown that such crops as wheat can thrive
+and make a good growth with a concentration a tenth of this. It appears
+to be clear therefore that as far as food supply is concerned there is
+normally an ample supply of phosphorus in the soil solution; but it
+does not follow that increasing the concentration of the solution if
+only temporarily would not result in favorable effects upon growing
+plants.
+
+A consideration of the bases, however, introduces serious difficulties,
+which will probably require much further research by the plant
+physiologist as well as the soil chemist. It is impossible as yet to
+determine the concentrations at which different plants will not grow.
+It is even impossible to determine the concentrations at which they
+will thrive best. It seems certain that different crop plants require
+different amounts of these minerals, but whether or not they require
+different concentrations of the constituents in the nutrient solution
+for their several best growths is yet not clearly shown. It now seems
+probable that to some extent at least these basic mineral nutrients can
+replace one another for the plant’s metabolism. It has been shown in
+the case of certain lower plant organisms that potassium can be more
+or less successfully replaced by rubidium and caesium, and in the case
+of some higher plants, possibly calcium, magnesium and potassium can
+partially replace one another.[91] In spite of the fact that sodium
+as well as potassium is a necessary constituent for the metabolism
+of higher animals which feed upon plants, it is generally held that
+sodium can not replace potassium in the processes of plant growth,
+although Wheeler and his colleagues have advanced evidence to show that
+a partial replacement is possible.[92] It seems evident, however, that
+no generalizations can hold concerning the effect of the concentration
+of any one base on plant growth which do not include recognition
+of possible modifications due to the presence of other bases; and
+the formulation of such generalizations must needs wait upon a more
+thorough knowledge of the parts played by the several mineral nutrients
+in the metabolism of different classes of plants.
+
+[91] For a more detailed discussion of this subject, and the functions
+of the several ash constituents in plant nutrition, see: The physiology
+of plants, by W. Pfeffer, translated by A. J. Ewart, vol. I, p. 410,
+_et seq._, 1900.
+
+[92] The effect of the addition of sodium to deficient amounts of
+potassium, upon the growth of plants in both water and sand culture,
+by B. L. Hartwell, H. J. Wheeler and F. R. Pember, Report Rhode Island
+Agricultural Experiment Station, 1906-7, p. 299-357.
+
+As to forms or chemical combinations in which the inorganic
+constituents of the soil solution are best adapted to plant growth,
+but little can yet be said other than that the different combinations
+do have an importance. Some empirical information is available, such
+as for instance, that potassium sulphate or carbonate is a better
+fertilizer for some crops than is potassium chloride. It is known that
+the mineral nutrients in the plant are partly in inorganic combinations
+but largely in organic combinations. But the causal relationships are
+yet to be worked out. And finally, although some meagre experimental
+data have been obtained as to the effect of certain inorganic
+constituents on the absorption of others, by particular plants, the
+mechanism of absorption itself, including the selective powers of the
+plant, is yet wanting an adequate explanation.
+
+
+
+
+Chapter X.
+
+THE BALANCE BETWEEN SUPPLY AND REMOVAL OF MINERAL PLANT NUTRIENTS.
+
+
+The mechanism of the solution and transport of mineral nutrients
+developed in the preceding pages makes it of interest to determine
+the relation between the possible or probable supply of mineral
+plant nutrients and crop demands over large areas. The inquiry can
+be formulated more specifically: Is the movement of mineral plant
+nutrients towards the surface soil equal to or in excess of the removal
+by drainage waters and garnered crops? Satisfactory data are yet
+wanting for anything like exact computations, but approximate figures
+are available which appear sufficient for the present purpose.
+
+The rainfall (R) can be considered as disposed in three portions, the
+fly-off (_f_), the run-off (_r_), and the cut-off (_c_). Stating this
+as an equation,
+
+ R = _f_ + _r_ + _c_.
+
+The cut-off can be resolved into the portion (_a_) seeping through the
+soil to ultimately join the run-off, and the portion (_b_) returning to
+the surface to ultimately join the fly-off. Stated as equations,
+
+ R = _f_ + _r_ + _a_ + _b_
+ = _f_ + _b_ + (_r_ + _a_).
+
+In other words, the rainfall can also be considered as made up of the
+fly-off, the capillary water of the soil and the drainage from the
+area. According to Murray,[93] Geikie,[94] Newell,[95] and others, the
+drainage water for humid areas, or such an area as the United States
+as a whole, would be between 20 and 30 per cent. of the rainfall, the
+major portion coming from seepage water rather than surface drainage.
+Assuming the higher figure, and making the further very probable
+assumption that the capillary water in the soil (_b_) is never less
+than the fly-off or the water that evaporates during rain (_f_),
+it follows from the equations given that the capillary water is at
+least 35 per cent. of the rainfall. If we assume the lower value for
+the drainage, then the capillary water is at least 40 per cent. of
+the rainfall, and if we assume the extreme case—that the fly-off is
+practically negligible—the capillary water becomes 80 per cent. of the
+rainfall. It appears, therefore, that in all probability the proportion
+of the cut-off water which returns to the surface as film water or
+capillary water is always greater, and generally much greater, than the
+portion which seeps through the soil to join the run-off.
+
+[93] On the total annual rainfall on the land of the globe, and the
+relation of rainfall to the annual discharge of rivers, by Sir John
+Murray, Scot. Geog. Mag., =3=, 65-77, (1887).
+
+[94] Textbook of Geology, by Sir Archibald Geikie, p. 484, (1903).
+
+[95] _In_ Principles and conditions of the movements of ground water,
+by F. H. King, Ann. rept. U. S. Geol. Surv., =19=, II, 59-294,
+(1897-98).
+
+From the available data, it appears that the average concentration of
+the run-off waters of the United States is about 1.8 parts per million
+of potassium (K) and about 0.6 parts per million of phosphoric acid
+(PO₄),[96] while the concentration of the capillary groundwater is some
+ten or twelve times greater. But even if these concentrations were the
+same, it is altogether probable that very much the greater part of the
+mineral plant nutrients dissolved by meteoric waters is continually, if
+slowly, moving towards the surface of the soil.
+
+The average rainfall of the United States may be taken as approximately
+30 inches.[97] If it be assumed that the discharge into the sea is
+25 per cent., then the capillary cut-off water is at least 37.5, and
+probably nearer 70 per cent. of the rainfall. King’s experimental
+work[98] indicates that the higher figure is much nearer the truth.
+Computing from the concentrations just cited, with the equations given
+above, it is found that approximately 3,500,000 tons of potassium (K)
+and 1,200,000 tons of phosphoric acid (PO₄) are carried into the sea
+annually from the United States, while from 48,000,000 to 100,000,000
+tons of potassium and 18,000,000 to 40,000,000 tons of phosphoric acid
+are being carried towards the surface of the soil. If it be assumed
+that an average of one ton per acre of dry crop containing one per
+cent. potash and 0.6 per cent. phosphoric acid[99] be removed from the
+entire area of the United States, then the annual loss from this source
+would be 24,000,000 tons of potassium and 14,000,000 tons of phosphoric
+acid. Consequently, there is an ample margin between the losses by
+cropping and seepage waters, and the supply of capillary waters. It is
+true that cases exist where the production of vegetable matter is much
+greater than a ton to the acre, productions of five tons or even more
+being on record. But such cases occur only where the water supply is
+also greater, either through natural rainfall or artificial irrigation;
+and it should also be borne in mind that the production of so large a
+mass of green crop involves a considerable drawing power on the water
+in the soil in addition to the evaporation which would take place at
+the surface under ordinary conditions. In other words, the plant would
+then be playing no small part in drawing to itself its needed supplies
+of water and dissolved mineral nutrients.
+
+[96] Estimated from data in Bull. No. 330, U. S. Geological Survey, The
+data of geochemistry, by Frank Wigglesworth Clarke, 1908, p. 53-90.
+
+[97] The latest authoritative statement is that the average annual
+rainfall of the United States is 29.4 inches; see: Water Resources,
+by W. J. McGee, vol. 1, p. 39-49, and Distribution of rainfall, by
+Henry Gannett, vol. 2, p. 10-12, Report of the National conservation
+commission, Senate doc. No. 676, 60th Congress, 2d session, 1909.
+
+[98] King: loc. cit., p. 85.
+
+[99] Estimated from Wolff’s tables, How crops grow, by Samuel W.
+Johnson, 1890, appendix.
+
+The question may be asked, if the processes outlined above are
+generally operative, why accumulations of soluble mineral substances
+are not usually found at the surface of the soil. As a matter of fact
+such accumulations do occur normally when the evaporation at the
+surface is relatively large, that is, under arid conditions. And under
+humid conditions it appears to be a general rule that the surface
+soil contains more readily soluble or absorbed mineral matter than do
+subsoils.[100] No great accumulation occurs at the surface normally
+under humid conditions because the rainfall is sufficiently distributed
+throughout the year to enable the cut-off water to carry back promptly
+into the lower soil levels any excessive amount of soluble material,
+there to start anew its slower ascent towards the surface.
+
+[100] See, for instance: Investigations in soil management, by F. H.
+King, Madison, Wis., 1904, p. 62 _et seq._ This tendency towards a
+higher content of absorbed soluble mineral matter in the surface soil
+has been amply confirmed by other experiments. It has been advanced
+as an argument against the assumption that the hydrolysis of the soil
+minerals is a reversible process. But as pointed out elsewhere in the
+text, many of the soil minerals can be made in the wet way at more or
+less elevated temperatures and the more rational explanation is simply
+that at ordinary temperatures the rate of formation is exceedingly slow.
+
+Calculations such as those here presented are at the best open to many
+objections, and it is wise to avoid giving them too much emphasis. So
+far as the available data justify any conclusion, however, it appears
+that the rise of capillary water is entirely capable of maintaining
+a sufficient supply of mineral nutrients for crop requirements; and
+furthermore, it is obvious that the problem of the supply of mineral
+plant nutrients is dynamic and cannot be successfully attacked by
+considerations which are essentially static.
+
+
+
+
+Chapter XI.
+
+THE ORGANIC CONSTITUENTS OF THE SOIL SOLUTION.
+
+
+The organic substances in the soil are tissue remains, to a large
+extent of plants, and to a less extent of animals; and it is to be
+expected that there may be found also in the soil the substances which
+were in the organisms at the time of their death, and degradation and
+decomposition products derived from these. Moreover, there are to
+be anticipated numerous products of bacterial origin, secretions of
+algae, fungi, etc., so that the organic complex in the soil may contain
+numerous substances of widely different chemical characteristics.
+Degradation products of proteins, fats, and carbohydrates, as well
+as decomposition products may be expected in almost any soil. But it
+does not follow that any particular organic substance (excluding, of
+course, carbon dioxide or nitrates) is to be found in every soil. No
+generalization regarding the organic substances in the soil can be made
+such as that formulated for the inorganic compounds. It is probable
+that further investigation will show certain organic substances or
+classes of substances to be common to most soils, but it is reasonably
+certain that many other organic substances will be found in only a few
+soils, or occasionally, and these latter will be often a prominent
+factor characterizing the particular soil in which they may occur.
+
+Although no broad generalization is justified regarding the composition
+of the soil solution with respect to organic substances dissolved,
+nevertheless the extension of the methods developed in the study of the
+inorganic substances dissolved has led to a considerable knowledge of
+the organic ones.
+
+In view of the facts shown in the preceding chapters, and at the
+same time recognizing that good and poor soils respectively must
+show differences in the soil solution if the fundamental thesis is
+valid as to the relation of soils to crop production, experiments
+have been made to investigate in a comparative way solutions obtained
+from good and poor soils of the same type, locality, and physical
+characteristics. For this purpose two samples of soil were taken from
+adjacent fields which had been under observation for two years. The
+soils were of the same type, Cecil clay, and were so similar in their
+physical characteristics as to be distinguished with difficulty in
+the laboratory. On one field a good crop of wheat was grown, followed
+by a good crop of clover and tame grasses. On the other field, the
+corresponding crops had been quite poor. The field yielding the good
+crops had been plowed somewhat deeper, and had previously received a
+moderate application of stable manure. Otherwise, so far as could be
+learned, the cultural history of the fields had been the same. For
+convenience, the sample from the first field will be designated “good,”
+and from the other “poor.”
+
+Aqueous extracts from these soils were prepared, the same proportion
+of distilled water to soil being taken in each case, and the time of
+contact being the same. The solutions were freed from suspended matter
+by being passed through Pasteur-Chamberland bougies under pressure.
+Young wheat seedlings germinated at the same time, and selected
+carefully for uniformity of size and apparent vigor, were grown in
+these solutions for three days. At the expiration of this period the
+seedlings in the extract from the good soil were about five inches in
+height, and the roots were clear, clean and turgid. The plants in the
+poor extract were scarcely three inches in height, and the roots were
+assuming a slimy, unhealthy appearance and becoming flaccid at the
+tips. The plants were then all removed, the roots washed carefully in
+tap water; the plants which had been in the poor solution were placed
+in the good solution, and those which had been in the good solution
+were placed in the poor solution. At the end of four days further,
+the poor plants had surpassed in height the ones which had previously
+been in the good solution, and the roots had acquired the general
+characteristics of healthy plants. These which had been originally in
+the good solution and then transferred to the poor, had made little
+additional growth, and the roots had become somewhat flaccid.[101]
+
+[101] The success of this and of many of the following experiments
+was due in large measure to the skill and patience of Mr. James E.
+Breazeale.
+
+This experiment was repeated several times, not only with the soils
+cited but with samples from adjacent good and poor spots in fields
+on several soil types from widely separated areas; for instance,
+Cecil clay from near Statesville, North Carolina; Sassafras loam
+from Maryland; Windsor sand from Delaware; and similar results were
+obtained. In other words, these water cultures produced plants which
+showed much the same differences, in kind and degree, as had been
+observed in the field. This was recognized as an important step
+forward, for it indicated that _whatever was making a difference in
+the crop-producing power of these soils in the field was transmitted
+to their aqueous extracts_, and methods for studying the chemical
+properties of solutions are far in advance of methods for studying
+mixtures of solids.
+
+The soil extracts described above were subjected to a careful analysis
+for their mineral constituents. They were found to be practically
+identical in this respect. Further, the poor extract contained
+decidedly more nitrates than the good—from three to four times as much.
+It follows, therefore, that the difference in the soils which produced
+a good and a poor crop respectively, was not due to a difference in
+mineral plant nutrients, or other mineral differences probably, nor to
+their respective content of nitrates. Consequently, the poor solution
+was such, not because of the lack of anything, but because of the
+presence of something inimical or “toxic” to plant growth; and further,
+this something must be an organic substance or substances more or less
+soluble in water. This conclusion was confirmed in the following way.
+
+Samples of the poor solution from the soil obtained near Statesville,
+N. C., were diluted twice, five times, and ten times, and wheat
+seedlings were grown in these solutions, using a sample of the good
+solution as a check. It was found after several days growth that the
+plants in the solution diluted tenfold were about as good, or perhaps
+slightly better, than those grown in the check solution. In every
+case diluting the poor solution had improved it for plant growth,
+and the higher the dilution the greater the improvement, in spite
+of the consequent dilution of the mineral plant nutrients. The only
+explanation of these results which has yet suggested itself is that
+the toxic organic substances present were less effective on dilution
+until the concentration reached a point where they actually became
+stimulative, as is common with toxins of every character.
+
+Another set of experiments confirmed the conclusion that the poor
+solution contained some organic substance inhibitory to plant growth.
+A number of water cultures was prepared from the aqueous extract of
+the poor soil, and lime in various forms was added to the cultures. To
+two of the cultures lime carbonate and lime sulphate respectively were
+added in excess, so that there was in each case a powdered solid at
+the bottom of the containing vessel. At the end of two days the wheat
+seedlings which were growing in the vessels containing the powdered
+solids had decidedly outstripped those growing in all the others, the
+tops having the appearance of unusually good and healthy plants. The
+roots were of a very remarkable character, being exceptionally long,
+very turgid, clear, clean and translucent.
+
+At once, new experiments were carried out in which there were added
+to the poor solution, precipitated ferric hydroxide freed from all
+adhering salts, precipitated alumina, shredded filter-paper, absorbent
+cotton, or carbon black. In every case the same result was obtained
+as before, a much improved growth of top and a vastly better root
+development. Since, by no possibility could these various added
+substances have increased the concentration with respect to mineral
+nutrients, another explanation must be sought. Aside from their
+insolubility, the one property common to these various substances
+was the large amount of surface they brought into contact with the
+solution. The one obvious explanation of their effects on the growth of
+the wheat seedlings, therefore, is that they withdrew or absorbed from
+the solution some substance or substances deleterious to plant growth.
+As diluting with respect to mineral nutrients could not possibly be
+expected to improve the cultural value of the solution, the conclusion
+seems evident that the effect produced by these various absorbents
+was due to more or less complete removal from the solution of organic
+substances inhibitory to plant growth. These experiments were then
+repeated in a modified form by shaking the poor solution with such
+absorbents as precipitated ferric oxide or carbon black and filtering
+before adding the seedling plants. The solutions thus prepared proved
+very satisfactory nutrient media, although the decided elongation of
+the roots, always observed when the absorbents were in contact with the
+solutions, was not so noticeable with these filtered solutions.
+
+The experiments just described were repeated with extracts from a
+number of soils which were supporting or had recently supported poor
+crops. The accumulated mass of evidence admits of no doubt that in many
+cases the apparent lack of fertility of a soil is due to the presence
+of some organic substance or substances soluble in soil water. This
+point established, there was studied the effect of fertilizers when
+added to aqueous extracts from poor soils.
+
+A large amount of experimenting has been done on this subject. It has
+been found that the common commercial fertilizers, as well as many
+other substances, when added to the soil extract containing growing
+plants, sometimes improve the plants, sometimes the contrary. But, in
+general, those particular substances which improve any given soil for
+a crop also improve the aqueous extract of the soil for the growth of
+the same crop plant: _i. e._, should a soil be known to respond well
+to the application of superphosphates when planted to wheat, then the
+probability is great that the aqueous extract of the soil will be
+improved as a culture medium for the wheat plant by addition of calcium
+phosphate. Particularly important in this connection are certain
+experiments with organic fertilizers.
+
+A soil which had been found to be quite unproductive with regard to
+wheat and ordinary tame grasses yielded, however, a much better growth
+of plants if pyrogallol or better pyrogallol and lime were added to
+the soil some days before planting. An aqueous extract of this soil
+tested with young wheat seedlings produced but a poor growth, as did
+the soil itself. But with the addition of pyrogallol or pyrogallol and
+lime to the soil extract, and especially if the extract so treated
+were allowed to stand for a few days with free access of air, there
+was obtained a culture medium which yielded remarkably good results
+with wheat seedlings. Not only was there an excellent and increased
+development of tops, but the roots of the seedlings grown in the
+solution treated with pyrogallol were unusually long, turgid, clear
+and translucent. Here, then, there was obtained an increased amount
+and improved character of growth by the addition of a substance which
+contained only carbon, hydrogen and oxygen, and no recognized plant
+food. Other organic substances, such for instance as tannin, gave
+similar results.
+
+With the recognition that the presence of organic dissolved substances
+in the nutrient medium produced effects on a growing plant of as great
+or even greater magnitude than those produced by inorganic dissolved
+substances, there was carried out a number of experiments to test
+more specifically such substances as might reasonably be expected to
+be present naturally in soils. The results thus obtained suggested
+experiments with other related substances. The first substance to
+suggest itself is stable manure. Taking it all in all, this substance
+is probably the most efficient as well as the most generally used soil
+amendment in the experience of mankind. The good effects produced by
+this substance have in the past been generally considered as due to the
+readily “available” potash, phosphoric acid and nitrogen it contains,
+but thoughtful experimenters and agriculturists have long doubted
+that this explanation is sufficient, since, after all, the mineral
+constituents of stable manure are usually small in amount, and out of
+all proportion to the effects resulting from its use. That some of the
+results are due to an improvement in the physical condition of the soil
+when manure is used has quite rightly been generally assumed; but to
+its content of nitrogenous components its value has in the main been
+ascribed.
+
+A well-fermented aqueous extract of stable manure was prepared, and
+filtered free of suspended solids. Four equal volumes of this solution
+were taken. Three of these portions were evaporated to dryness
+in platinum dishes, and the residues incinerated. To the dishes
+containing: the ash were added respectively nitric acid, sulphuric
+acid, and hydrochloric acid in slight excess, and the dishes again
+brought to dryness. Water cultures for wheat seedlings were then
+prepared.[102] Into one was introduced the given volume of manure
+extract; into another the ash from an equal volume of the extract which
+had subsequently been treated with nitric acid; and cultures with the
+ash which had been treated respectively with sulphuric and hydrochloric
+acid were similarly prepared. After ten days growth, the plants from
+the several cultures were compared. The plants from the cultures which
+contained the sulphates and the chlorides were not materially different
+from the plants grown in the check culture. The plants from the nitrate
+culture had larger shoots, but shorter roots than the check plants.
+But the plants grown in the culture to which the manure extract had
+been added directly had by far larger and better shoots and the roots
+were incomparably superior to those grown in any other culture, being
+larger, thicker, better branched, clear, bright and translucent, and
+very turgid, very like the roots obtained in cultures to which carbon
+black or precipitated ferric oxide had been added.
+
+[102] Further studies on the properties of unproductive soils, B. E.
+Livingston _et al._, Bull. =36=, 1907, and =48=, 1908, Bureau of Soils,
+U. S. Dept. Agriculture.
+
+The results of this experiment, which has been repeated a number
+of times, using manure extracts of various origins, leave no doubt
+that it is the organic components of the manure which produce the
+characteristic effects, for the ash culture contained all and even more
+of the mineral constituents “available” in the original extract, and
+the nitrate culture excluded any explanation based on the nitrogenous
+content of the manure. This conclusion was supported by the results of
+another experiment.
+
+To a manure extract was added alcohol, which precipitated most of the
+organic dissolved substances but very little of the inorganic ones.
+The precipitated organic matter was filtered off, dried carefully in a
+water oven to eliminate the alcohol, and then taken up in sufficient
+water to equal the original volume of manure extract. The nitrate
+containing the major part of the salts was boiled vigorously to
+eliminate the alcohol and water was then added to restore the original
+concentration. A third solution was prepared by bringing together the
+organic and inorganic substances which had previously been separated as
+above described. The three solutions were used as water cultures for
+wheat seedlings, a solution of the original manure extract being taken
+for a check culture. The original manure extract and the reconstructed
+manure extract gave plants of about equal development. The culture
+containing the organic dissolved substances only, gave plants of
+nearly, but not quite, equal development to those grown in the check
+culture. But the plants grown in the solution containing the dissolved
+minerals only, while fine plants and making what would ordinarily be
+considered a good development, were decidedly smaller as regards their
+aerial parts, and the roots were in no wise comparable to the roots
+of the plants grown in the cultures containing the dissolved organic
+substances.
+
+This last experiment has been repeated, with dissolved substances
+prepared from another manure extract, but in this case the organic
+and inorganic substances were separated by dialysis. This suggested
+yet another experiment, in which it was sought to hasten the process
+of dialysis, by introducing electrodes into the manure extract, each
+electrode being surrounded by some porous membrane, either of parchment
+paper, or unglazed porcelain. Not only were the mineral constituents
+of the manure extract readily separated in this way, passing into
+the electrode chambers, as did also to some slight extent organic
+compounds, but also about the outer walls of the electrode chambers
+there was marked segregation and deposition of organic materials. The
+organic substances deposited at the cathode were found to stimulate
+greatly the growth of wheat seedlings while those deposited at the
+anode were found to retard the growth of seedlings. It seems probable,
+therefore, that stable manure contains organic components which produce
+as great or greater effects upon growing plants as do the inorganic
+substances it contains: that on the whole these organic components
+induce increased plant growth, but some of them, by themselves alone,
+would retard plant growth.
+
+In a similar way green manures have been examined. If fresh clover,
+alfalfa, or cowpeas, be macerated and an aqueous extract thus prepared,
+it will in general be quite toxic to plants such as wheat; and if this
+extract be allowed to stand and ferment or sour the resulting solution
+will be totally unfit for the growth of seedling plants. But if the
+clover, alfalfa, or cowpea vines be allowed to wilt thoroughly before
+being macerated and extracted, or if they be macerated and incorporated
+with soil and allowed to remain thus for ten days or a fortnight
+before being extracted; then, the resulting solution will be quite
+stimulating to such plants as wheat, corn or the grasses, when added
+either to water or soil cultures. It would seem, therefore, that the
+mineral constituents of the legumes commonly employed as green manures
+are less important than the organic, in affecting the growth of crops
+subsequently planted, and the inhibitory or toxic action of fresh green
+manure seems to be recognized in the common practice of waiting some
+days after turning under a green manure crop before seeding to a new
+crop.
+
+The wilting of a green manure involves a darkening and some blackening
+of the mass, with apparently some absorption of oxygen. This fact
+has suggested a trial of other organic substances which show a
+decided ability to absorb oxygen. Among such substances, pyrogallol
+stands preëminent. It has been shown that when pyrogallol, or better
+pyrogallol and lime, is added to certain soils, naturally low in
+productive power, and allowed to stand for a few days, these soils are
+readily brought into good condition and support good crops of wheat,
+rye, or grasses. Pyrogallol in water cultures is rather toxic to wheat
+plants, even in quite dilute solutions. But if the aqueous solution
+of pyrogallol be allowed to stand exposed to the air, and better if
+the solution be made slightly alkaline as by the addition of lime,
+oxygen is absorbed, and a dark brown or blackened solution is soon
+formed, which is stimulating to wheat seedlings. Many experiments have
+indicated it to be a general rule that soluble organic substances
+which are toxic to plant growth yield oxidation products which are
+harmless or positively beneficial.
+
+The suggestion has been made that the well-known infertility of
+subsoils, when freshly turned up, is caused by the presence of
+alkaloids of the purine or codeine type, due to the activities of
+anaerobic bacteria. Water cultures and pot cultures show that while
+these substances do have a marked effect on plant growth, it is,
+frequently, quite beneficial; strychnine for example, in certain
+concentrations, produces a very decided stimulation in the growth of
+wheat seedlings. It is clear that some other explanation will have to
+be sought for the lack of fertility of subsoils.
+
+A number of the substances which may be expected for one reason
+or another to be present in soils, have been investigated as to
+their effect on plants. In this connection may be cited the work of
+Livingston[103] and of Dachnowski,[104] who have studied the effect
+on vegetation of the organic substances dissolved in bog waters. In
+the following table are given the results obtained by growing wheat
+seedlings in solutions containing some one of a number of substances
+which might be expected to occur in a soil or to be derivatives of such
+substances. It will be observed that in the case of these dissolved
+organic substances, as has been repeatedly established with the
+inorganic ones, in concentrations sufficiently dilute not to be toxic,
+they generally show the opposite effect and appear to be stimulating.
+
+[103] Physiological Properties of Bog Water, by B. E. Livingston, Bot.
+gaz., =39=, 348-355, (1905).
+
+[104] The toxic property of bog water and bog soil, by Alfred
+Dachnowski, Bot. gaz., =46=, 130-143, (1908).
+
+ TABLE I.—EFFECT OF VARIOUS ORGANIC COMPOUNDS UPON THE GROWTH OF
+ WHEAT PLANTS, WITH ESPECIAL REFERENCE TO THEIR TOXIC PROPERTIES[105]
+
+[105] Certain organic constituents of soils in relation to soil
+fertility, by Oswald Schreiner and Howard S. Reed, assisted by J. J.
+Skinner, Bull. No. =47=, Bureau of Soils, U. S. Dept. Agriculture, 1907.
+
+ LEGEND:
+ A = Duration of experiment
+ B = Lowest concentration causing death
+ C = Lowest concentration causing injury
+ D = Concentration causing greatest stimulation
+ =======================+====+======+======+======+===================
+ | | | | |
+ | | | | |
+ Compound | A | B | C | D | Remarks
+ | | | | |
+ -----------------------+----+------+------+------+-------------------
+ |days|p.p.m.|p.p.m.|p.p.m.|
+ | | | | |
+ _a_ Aspartic acid | 10 | 500 | 100| .... |Normal growth in
+ HOOC.CH₂.CH(NH₂).COOH | | | | |concentration
+ | | | | |below 100 p.p.m.
+ -----------------------+----+------+------+------+-------------------
+ _b_ Asparagine | 9 | | | |No injury below
+ NH₂.OC.CH₂.CH(NH₂).COOH| | | | |1,000 p.p.m.
+ -----------------------+----+------+------+------+-------------------
+ _c_ Glycocoll, | 9 | | | |Tops of all plants
+ CH₂(NH₂).COOH | | | | |good. Roots slightly
+ | | | | |injured at higher
+ | | | | |concentrations
+ -----------------------+----+------+------+------+-------------------
+ _d_ Alanine, | 10 | .... | 500 | 25 |Only roots were
+ CH₃.CH(NH₂).COOH | | | | |injured at
+ | | | | |500 p.p.m.
+ -----------------------+----+------+------+------+-------------------
+ _e_ Leucine | 9 | .... | .... | .... |No injurious action
+ CH₃.(CH₂)₃.CH(NH₂).COOH| | | | |
+ -----------------------+----+------+------+------+-------------------
+ _f_ Tyrosine, | 11 | .... | 10 | |
+ OH | | | | |
+ / | | | | |
+ C₆ H₄ | | | | |
+ \ | | | | |
+ CH₂.CH(NH₂).COOH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _g_ Choline, | 10 | | 500 | 1 |Roots affected more
+ CH₂CH₂OH | | | | | than tops
+ / | | | | |
+ (CH₃)₃N | | | | |
+ \ | | | | |
+ OH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ | | | | |
+ _h_ Neurine, | 9 | 250 | 25 | |
+ CH:CH₂ | | | | |
+ / | | | | |
+ (CH₃)₃N | | | | |
+ \ | | | | |
+ OH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ Neurine (neutralized) | 8 | 250 | 25 | |
+ -----------------------+----+------+------+------+-------------------
+ _i_ Betaine, | 9 | ... | ... | |No injury
+ CH₂.CO | | | | |
+ / / | | | | |
+ (CH₃)₃N / | | | | |
+ \ / | | | | |
+ O | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _j_ Alloxan, | 10 |1,000 | 100 | |
+ NH.CO | | | | |
+ / \ | | | | |
+ CO CO | | | | |
+ \ / | | | | |
+ NH.CO | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _k_ Guanine, | 12 | | | |Insoluble above 40
+ NH.C.NH.CO.C.NH | | | | |p.p.m. No harmful
+ \\ || \ | | | | |effects.
+ \\ || CH | | | | |
+ \\ || // | | | | |
+ N————C. N | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _l_ Xanthine | | | | |No injurious
+ | | | | |action.
+ CO.NH.CO.C.NH | | | | |
+ \ || \ | | | | |
+ \ || CH | | | | |
+ \ || // | | | | |
+ NH——C—N | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _m_ Guanadine, | 9 | 100 | 1 | |
+ NH₂ | | | | |
+ / | | | | |
+ HN : C | | | | |
+ \ | | | | |
+ NH₂ | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _n_ Skatol, | 9 | 200 | 50 | |Roots injured more
+ C.CH₃ | | | | |than tops
+ / \\ | | | | |
+ C₆H₄ CH | | | | |
+ \ / | | | | |
+ NH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ | | | | |
+ _o_ Pyridine, C₅H₅N | 9 | .... | 50 | .... |In solutions of 50
+ | | | | |p.p.m. and less
+ | | | | |the root growth
+ | | | | |was normal.
+ -----------------------+----+------+-------+------+------------------
+ Picoline, C₅H₄N.CH₃ | 7 |1,000 | 500 | 100 |
+ -----------------------+----+------+-------+------+------------------
+ | | | | |
+ Piperidin | 7 | 250 | 25 | |
+ CH₂ | | | | |
+ H₂C / \ CH₂ | | | | |
+ | | | | | | |
+ | | | | | | |
+ | | | | | | |
+ H₂C \ / CH₂ | | | | |
+ NH | | | | |
+ -----------------------+----+------+-------+------+------------------
+ Piperidine | 7 | 100 | 25 | 1 |
+ (neutralized) | | | | |
+ -----------------------+----+------+-------+------+------------------
+ / \ / \ | | | | |
+ | | | | | | | |
+ Quinolin, | | | | 6 | 500 | 5 | |
+ | | | | | | | |
+ \ / \ / | | | | |
+ N | | | | |
+ -----------------------+----+------+-------+------+------------------
+ _p_ Ricin | 10 | | 40 | |Insoluble above 50
+ | | | | | p.p.m.
+ -----------------------+----+------+-------+------+------------------
+ _q_ Mucin | 10 | | 100 | |Not tested in
+ | | | | | concentrations
+ | | | | |higher than
+ | | | | |100 p.p.m.
+ -----------------------+----+------+-------+------+------------------
+ | | | | |
+ _r_ Pyrocatechin, | 12 | 500 | 25 | 1 |
+ C₆H₄(OH)₂(1,2) | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _s_ Arbutin, C₁₂H₁₆O₇ | 12 | 500 | 25 | 1 |
+ -----------------------+----+------+------+------+-------------------
+ _t_ Phloroglucin, | 13 | 500 | 25 | 1 |
+ C₆H₃(OH)₃(1,3,5) | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _u_ Vanillin, | 9 | 500 | 1 | |
+ CHO | | | | |
+ / | | | | |
+ C₆H₃——O.CH₃ | | | | |
+ \ | | | | |
+ OH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ Vanillic acid, | 7 | 100 | 25 | 5 |
+ COOH | | | | |
+ / | | | | |
+ C₆H₃—O.CH₃ | | | | |
+ \ | | | | |
+ OH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ _v_ Quinic acid, | 10 | 500 | 100 | |
+ C₆H₇(OH)₄.COOH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ O | | | | |
+ / | | | | | |
+ _w_ Quinone, C₆H₄ | | 9 | 100 | 1 | |
+ \ | | | | | |
+ O | | | | |
+ -----------------------+----+------+------+------+--------------------
+ _x_ Cinnamic acid, | 8 | 100 | 25 | |
+ C₆H₅CH : CH.COOH | | | | |
+ -----------------------+----+------+------+------+-------------------
+ Sodium cinnamate | 12 | ... | 100 | |Roots were
+ | | | | |stimulated
+ | | | | |in lower
+ | | | | |concentrations
+ -----------------------+----+------+------+------+-------------------
+ _y_ Cumarin, | 8 | 100 | 1 | |
+ CH:CH.CO | | | | |
+ / / | | | | |
+ C₈H₄/ / | 8 | 100 | 1 | |
+ \ / | | | | |
+ O | | | | |
+ -----------------------+----+------+------+------+-------------------
+ | | | | |Insoluble above
+ _z_ Daphnetin | 12 | | 50 | |50 p.p.m. Roots
+ | | | | |somewhat injured
+ CH : CH.CO | | | | |
+ / / | | | | |
+ C₆H₂ ——— O | | | | |
+ \\ | | | | |
+ (OH)₂ | | | | |
+ ----------------------+----+------+------+------+-------------------
+ _aa_ Esculin, C₁₅H₁₆O₉ | 13 | 500 | 1 | |
+ ----------------------+----+------+------+------+-------------------
+ _bb_ Piperonal | | | | |
+ (heliotropine)— | | | | |
+ CHO | | | | |
+ / | | | | |
+ C₆H₅——O | | | | |
+ \ \ | | | | |
+ \ \ | | | | |
+ O——CH₂ | 7 | 100 | 1 | ... |
+ ------------------------+----+------+------+------+-------------------
+ _cc_ Borneol, C₁₀H₁₇(OH)| 10 | 100 | 1 | ... |
+ _dd_ Camphor, C₁₀H₁₆O | 8 | 300 | 5 | ... |
+ _ee_ Turpentine, C₁₀H₁₆ | 8 | 500 | 10 | ... |
+ ------------------------+----+------+------+------+-------------------
+
+_a._ Aspartic acid has been found in young sugar-cane and in seedlings
+of the bean and pumpkin.
+
+_b._ Asparagine was first found in asparagus; but has since been shown
+to be relatively abundant in many species.
+
+_c._ Glycocoll is one of the simpler and more common degradation
+products of proteins.
+
+_d._ Alanine is a common degradation product of proteins and is related
+chemically to phenylalanine, and to tyrosine, which has been found in
+many plants.
+
+_e._ Leucine, an amino-acid of a paraffine series and a decomposition
+product of proteids, has been found in certain mushrooms, vetches,
+lupine, gourds, potatoes, corn, etc.
+
+_f._ Tyrosine is an important decomposition product of proteids, is
+widely distributed and found in many plants and fungi.
+
+_g._ Choline is a derivative of certain lecithins and is found in many
+seeds and growing plants.
+
+_h._ Neurine is a substance closely related to choline, and probably
+formed from it.
+
+_i._ Betaine is closely related to both choline and neurine, and is
+found in many seeds and plants.
+
+_j._ Alloxan is closely related chemically to convicine, which latter
+is found in beets and certain beans.
+
+_k._ Guanine is a widely distributed nitrogenous body, and has
+been found in the seeds of vetch, alfalfa, clover, gourds, barley,
+sugar-beets and sugar-cane.
+
+_l._ Xanthine, a substance closely related to guanine, has been found
+in a number of plants.
+
+_m._ Guanidine, a substance chemically related to guanine, has been
+found in a number of plants of different species.
+
+_n._ Skatol is a derivative of proteids and is a common product of the
+activities of some varieties of bacteria.
+
+_o._ Pyridine has been shown to exist in soils, as such probably, by
+Shorey, who obtained it from certain soils in Hawaii.
+
+_p._ Ricin is found in the castor-oil plant.
+
+_q._ Mucin has been found in yams.
+
+_r._ Pyrocatechin has been found in the bark of various trees, the
+berries of the Virginia creeper, the sap of sugar-beets and in several
+varieties of willows.
+
+_s._ Arbutin has been found in many plants, especially in some of the
+grasses.
+
+_t._ Phloroglucin is easily derived from a number of plant constituents.
+
+_u._ Vanillin forms readily from a glucoside, which is very widely
+distributed in many plants, and by some authorities is supposed to be a
+product of the decomposition of wood tissues.
+
+_v._ Quinic acid, which is found with quinine in the cinchona bark,
+also occurs in beet leaves, certain hays, cranberry leaves, and
+occasionally in other plants.
+
+_w._ Quinone has been shown to result from the action of a certain
+fungus, _Streptothrix chromogena_, common in soils.
+
+_x._ Cinnamic acid is found in certain barks, and forms esters which
+have been found in the leaves of various plants.
+
+_y._ Cumarin has been found in a large number of plants, including the
+grasses, beets, sweet clover, etc.
+
+_z._ Daphnetin occurs in some species of _Daphne_ and is closely
+related to cumarin.
+
+_aa._ Esculin, as well as the corresponding esculetin, has been found
+occasionally in a number of plants.
+
+_bb._ Heliotropine, or piperonal, has the odor of heliotrope and is
+found in flowers.
+
+_cc._ Borneol occurs in needles of different varieties of pine, fir,
+spruce and hemlock, golden rod and thyme.
+
+_dd._ Camphor is closely related chemically to borneol and is secreted
+by a number of plants; it is found in the wood of _Cinnamomum_,
+cinnamon root, in the leaves of sassafras, spikenard, rosemary,
+rosewood, etc.
+
+_ee._ Turpentine is a constituent of many plants and coniferous trees.
+
+Finally, a number of organic substances has been isolated from soils.
+Their composition, and in several cases their constitutions have been
+determined. The effects of these on plants, when they are present
+in the cultural media have been studied. Thus, Shorey[106] was able
+to isolate picoline carboxylic acid (C₇H₇NO₂) from certain soils in
+Hawaii, and this same substance has since been found in several soils
+of the United States. In aqueous solutions it is quite toxic to wheat
+seedlings. Since then a number of other definite organic compounds have
+been isolated from soils belonging to at least eight different classes
+of organic substances, including:[107]
+
+ Hentriacontane, C₃₁H₆₄.
+ Monohydroxystearic acid, CH₃(CH₂)₆CHOH(CH₂)₉COOH.
+ Dihydroxystearic acid, CH₂(CH₂)₇CHOH.CHOH.(CH₂)₇ COOH.
+ Agroceric acid, C₂₁H₄₂O₃.
+ Paraffinic acid, C₂₄H₄₈O₂.
+ Lignoceric acid, C₂₄H₄₈O₂.
+ Phytosterol, C₂₆H₄₄O.H₂O.
+ Pentosan, C₅H₈O₄.
+ Agrosterol, C₂₆H₄₄O.H₂0.
+ Picoline carboxylic acid, C₇H₇O₂N.
+ Histidine, C₆H₉O₂N₃.
+ Arginine, C₆H₁₄O₂,N₄.
+ Cytosine, C₄H₅ON₃.H₂O.
+ Xanthine, C₅H₄O₂N₄.
+ Hypoxanthine, C₅H₄ON₄.
+ Glycerides, resin acids, etc.
+
+[106] Organic nitrogen in Hawaiian soils, by E. C. Shorey, report of
+Hawaii Experiment Station, 1906, 37-59.
+
+[107] Chemical Nature of Soil Organic Matter, by Oswald Schreiner
+and Edmund C. Shorey, Bull. 74, Bureau of Soils, U. S. Department of
+Agriculture, 1910.
+
+Some of these, picoline carboxylic acid, dihydroxystearic acid and
+the pentosan just cited, are toxic to growing plants; others are not.
+The origin and mode of production of these substances in the soil
+is, generally speaking, uncertain and obscure, and is yet one of the
+important fundamental problems confronting the soil chemist.
+
+It is important to note that the organic substances thus far isolated
+from soils are of widely varying types, and with very different
+chemical characteristics. As pointed out above, almost any type of
+organic substance is likely to be found in soils, and the effects of
+any of them on growing plants can hardly be predicted from _a priori_
+considerations.
+
+It has been found that as a general rule the continued growth of
+one crop in any soil results in a low crop production. Pot cultures
+have given even more pronounced results in the same direction. The
+explanation long accepted is that the soil has, as a result of
+continued cropping, become deficient in some one or more of the
+“available” mineral nutrients. Pot experiments, where the garnered crop
+was returned to the soil and still a diminished yield was obtained,
+throw doubt on this explanation. Still further doubt results from
+water-cultures which, by growing a crop in them, become “poor” for
+subsequent crops, although there is maintained in them an ample
+supply of mineral plant nutrients, and they are easily renovated by
+good absorbers. These facts find a more satisfactory explanation as
+being due to the production in the nutrient medium of deleterious
+organic substances originating in the growing plant itself. This idea
+seems to have been advanced first by De Candolle, in 1832,[108] to
+account for the beneficial results obtained by employing a rotation of
+crops. It appears to have been held by Liebig at one time, although
+he subsequently abandoned it in favor of the view that the benefits
+of a crop rotation are due to the several crops requiring different
+proportions of mineral nutrients, and that the disturbance of the
+balance in the soil produced by one crop is not unfavorable to the
+growth of some other crop. Although lacking direct experimental
+confirmation, this latter view of Liebig’s has long prevailed among
+agricultural investigators, partly by reason of his authority, partly
+by reason of the dominance of the plant-food theory of fertilizers,
+and partly by reason of the fact that the ideas of De Candolle as
+originally advanced included certain errors soon detected. The trend of
+recent investigations has been distinctly in favor of a modified form
+of the view of De Candolle. It has been recognized that other factors
+enter into crop rotations, such as the elimination of associated weeds,
+various kinds of animal, insect and plant parasites, preparation of
+the soil by a deep-rooted crop for a shallow-rooted following crop,
+etc. It has come to be recognized that there are natural associations
+of plants, and natural rotations of vegetation certainly determined
+by other than plant food factors. Thus, in the eastern United States,
+wheat is followed by ragweed naturally, while across the fence
+cocklebur and wild sunflower come in after the corn, the difference
+in vegetation being as sharply marked after the removal of the crops
+as when they still occupied the land. Analyses of the ragweed, for
+instance, although it is a shallower rooted crop than wheat, show
+that it takes from the soil as much of the mineral nutrients as
+does the preceding[109] wheat crop. The investigation of Lawes and
+Gilbert[110] on fairy rings showed that the continual widening of the
+rings can not be satisfactorily explained by the comparison of the
+mineral constituents in the soil within and without the rings. Work
+at Woburn[111] on the effect of grass on apple trees finds no other
+plausible explanation than that the growing grass produces in the
+soil organic substances detrimental to young apple trees. A number of
+similar cases have been recorded.
+
+[108] See in this connection, Further studies on the properties of
+unproductive soils, by B. E. Livingston, Bull. No. =36=, Bureau of
+soils, Dept. of Agric., 1907, p. 7-9.
+
+[109] Mr. J. G. Smith has made a comparison between the potash and
+phosphoric acid content of the wheat and following crop of ragweed
+grown on a farm in Fairfax Co., Va. His unpublished results, with some
+others found in the literature, are given in the following table:
+
+ ======================+======+==========+===========================
+ |Potash|Phosphoric|
+ Material | K₂O |acid, P₂O₅| Analyst
+ | % | % |
+ ----------------------+------+----------+---------------------------
+ Wheat | 0.76 | 0.52 |Smith
+ Young ragweed | 1.78 | 0.73 |Smith
+ Ragweed in seed | 1.28 | 0.35 |Smith
+ Ragweed in seed and | | |
+ accompanying plants | 1.18 | 0.39 |Smith
+ Winter wheat in flower| 1.796| 0.51 |Wolff’s tables in Johnson’s
+ | | | “How Crops Grow,” p. 376.
+ Ragweed | 1.79 | 0.41 |DeRoode,in Bull. 19, W. Va.
+ | | | Agr. Exp. Sta., 1891
+ Ragweed | 1.809| 0.54 |Burney, 2d. Ann. rept.
+ | | | S. C. Stat., 1889, p. 146
+ ----------------------+------+----------+---------------------------
+
+On the whole, ragweed seems to require and take from the soil about
+as much mineral matter as does wheat. It is stated by some of the
+dairy farmers near Washington, who cut the mixture of ragweed, other
+weeds and grass following wheat, for a hay crop, that the weight of
+the ragweed crop is generally heavier than that of the wheat crop.
+Therefore the ragweed actually removes more mineral matter from the
+field than does the wheat. These facts lend no support to the popular
+notion that wheat “exhausts” the soil of its “available” mineral plant
+nutrients. For analyses of a number of common American weeds, see
+Analyses of the ashes of certain weeds, by Francis P. Dunnington: Am.
+Chem. Jour., =2=, 24-27, (1880).
+
+[110] Note on the occurrence of “fairy rings,” by J. H. Gilbert: Jour.
+Linn. Soc, =15=, 17-24, (1875).
+
+[111] Second, third and fifth reports of the Woburn Experimental Fruit
+Farm, =1900=, =1903=, =1905=.
+
+Finally, although less work has been done in this direction with higher
+plants than with other organisms, it is now recognized as a general law
+of all living organisms that they function less readily as the products
+of their activities accumulate.[112] These products may, however, be
+inimical, neutral or even stimulating to other organisms.
+
+[112] It may not be amiss to point out here that this general law holds
+for all dynamic phenomena. In chemistry, for instance, the general law
+is well recognized that the rate of reaction diminishes with increase
+in the active mass of the reaction products. It can be shown that the
+principle applies to plant growth. Young plants will withdraw potassium
+more rapidly than chlorine from solutions of potassium chloride; that
+is, the solution soon contains free hydrochloric acid. Conversely
+the plants cause a solution of sodium nitrate to become alkaline.
+Therefore, if the above principle holds, then the initial addition of
+small amounts of hydrochloric acid to a solution of potassium chloride
+should slow up the absorption of potassium by seedling wheat plants,
+or the addition of sodium hydroxide the absorption of nitrogen from a
+solution of sodium nitrate. Mr. J. J. Skinner has tested this idea with
+the following results, growing carefully selected wheat seedlings, for
+3 days in solutions of pure potassium chloride, solutions of potassium
+chloride containing initially enough excess of hydrochloric acid to
+be of an N/₅,₀₀₀ concentration with respect to the acid, solutions of
+sodium nitrate, and solutions of sodium nitrate containing initially an
+excess of sodium hydroxide.
+
+Solutions of KCl containing 80 p.p.m. K₂O.
+
+1 K₂O absorbed 40.0 p.p.m. 2 K₂O absorbed 40.0 p.p.m. 3 K₂O absorbed
+36.3 p.p.m.
+
+Solutions of KCl (80 p.p.m. K₂O) and HCl (N/₅,₀₀₀).
+
+4 K₂O absorbed 26.7 p.p.m. 5 K₂O absorbed 29.5 p.p.m. 6 K₂O absorbed
+26.7 p.p.m.
+
+Solutions of NaNO₃ containing 80 p.p.m. NH₃.
+
+7 NH₃ absorbed 30.2 p.p.m. S NH₃ absorbed 30.2 p.p.m. 9 NH₃ absorbed
+32.5 p.p.m.
+
+Solutions of NaNO₃ (80 p.p.m. NH₃) and NaOH (N/₅,₀₀₀).
+
+10 NH₃ absorbed 27.8 p.p.m. 11 NH₃ absorbed 34.3 p.p.m. 12 NH₃ absorbed
+27.8 p.p.m.
+
+This problem has been investigated critically by direct experimentation,
+growing wheat, and other seedlings in water and agar cultures.[113]
+It has been shown that wheat renders the culture media unsuitable
+for subsequent wheat crops, though it can be reclaimed or renovated
+by treatment with such absorbents as carbon black, or by other
+methods.[114] Wheat did about as well when grown in a medium which had
+previously supported a growth of cowpeas as when planted in a fresh
+medium; poorer results were obtained after oats; no crop produced such
+poor results in the succeeding wheat crop as did wheat itself.
+
+[113] Some factors in soil fertility, by Oswald Schreiner and Howard S.
+Reed, Bull. No. =40=, Bureau of Soils, U. S. Dept. Agriculture, 1907.
+
+[114] Soil fatigue caused by organic compounds, by Oswald Schreiner and
+M. X. Sullivan: Jour. Biol. Chem., =6=, 39-50, (1909).
+
+It is yet a matter of dispute as to whether the substances thus added
+to nutrient media are truly excretory products of the plant, sloughed
+off or otherwise eliminated from the surface of the roots, or further
+elaborated by bacterial or other agencies before becoming effective.
+These are important problems for the plant physiologist and the soil
+chemist alike. It is beyond dispute, however, by reason of a large and
+increasing weight of evidence, much of it direct experiment, that, as
+a result of the growing of plants, soils and the soil water do contain
+organic substances; harmful to the plant or organism eliminating them;
+harmful, innocuous, or even stimulating to other plants or organisms.
+
+For the elimination from the soil of toxic or inhibitory organic
+substances, whether excreted by roots or otherwise produced, several
+methods are more or less effective. When, as is sometimes the case,
+the substance is volatile, it may be removed by heating, distilling
+with steam, or passing a current of air through the soil or cultural
+medium. These methods, while effective in the laboratory and possibly
+applicable to greenhouse conditions, are naturally inapplicable to
+field conditions. In this last case the obvious procedure is to
+increase as much as possible the absorptive powers of the soil; to
+secure the best possible drainage; and with these, the best possible
+aeration of the soil.
+
+It has been found that, in general, a cultural medium which has
+been rendered unfit for the continued growth of a crop, is readily
+renovated by treatment with oxidizing agents, and is sometimes rendered
+even better than ever by such treatment, which would suggest that
+the oxidation products from plant effluvia may be even beneficial
+to the plant. To this end the growing plant seems itself to be an
+active agent, apparently attempting automatically to protect itself
+against the products of its own activities. It has been pointed out by
+Molisch[115] that root secretions have an oxidizing power, apparently
+of an enzymotic character. Some doubt of the validity of Molisch’s
+work has been raised by Czapek, Pfeffer, and others; nevertheless it
+is now accepted that while intercellular autoxidation or reduction
+processes may take place in living roots, the higher plants, such
+as our common crop plants, also show a more or less well-developed
+extracellular oxidizing power in the neighborhood of the root tips and
+root hairs.[116] That this oxidizing power displayed by growing roots
+is enzymotic is indicated by the fact that artificial culture media
+frequently display it also after plants have been grown in them for a
+short while.[117]
+
+[115] Über Wurzelausscheidungen und deren Einwirkung auf organische
+Substanzen, von Hans Molisch. Sitzungsber. Akad. Wiss. Wien, Math. nat.
+K1., =96=, 84-109 (1888).
+
+[116] The rôle of oxidation in soil fertility, by Oswald Schreiner
+and Howard S. Reed: Bull. No. =56=, Bureau of Soils, U. S. Dept.
+Agriculture, 1909.
+
+[117] From considerations as yet highly speculative, a different type
+of oxidation by roots might be anticipated. It is recognized that in
+the absorption of mineral nutrients by plants a certain amount of
+selection enters. For example, a plant with its roots in a solution of
+potassium chloride, absorbs more potassium than chlorine, relatively,
+and free hydrochloric acid is left in the solution. Obviously in the
+absorption, work is done, and a possible explanation is that water is
+decomposed at the absorbing surface of the root, with the liberation of
+oxygen. Theoretically, it ought not to be difficult to investigate this
+by a study of the energy changes during absorption, but growing plants
+do not lend themselves readily to such experimentation.
+
+It has been shown that the oxidizing action of growing roots is
+generally promoted by having the cultural medium slightly alkaline
+or neutral rather than acid. It is also promoted by the addition
+of various mineral salts, notably by nitrates, phosphates, or
+lime salts. Potassium salts promote the oxidation but slightly,
+and in some experiments have even produced a slight decrease. The
+corresponding sodium and ammonium salts are more favorable than those
+of potassium.[118] It appears altogether probable, therefore, that the
+mineral salts in commercial fertilizers may have some importance in
+this connection.
+
+Whatever may be the role of mineral fertilizers towards organic
+substances toxic to growing plants, it is certain that they have
+an importance and one that is probably specific, as indicated by
+some recent investigations.[119] Culture solutions containing the
+constituents potassium, nitric acid and phosphoric acid were prepared
+in such manner that they covered the range of all possible ratios
+of these constituents in intervals of ten per cent. in each. Into
+one set of these solutions was introduced dihydroxystearic acid,
+into another set cumarin, and into a third set, vanillin, and into a
+fourth set, quinone. The growth of wheat seedlings in these several
+sets showed indubitably that these several organic substances which
+are all deterrent to the growth of wheat, were modified in their
+influence by the presence of the mineral salts; but that nitrates
+were more efficient than the other minerals in the case of the
+solutions containing dihydroxystearic acid or vanillin; phosphates
+were most efficient in the case of the solutions containing cumarin,
+and potassium most efficient in solutions containing quinone. As the
+organic substances used in these experiments, either in themselves or
+as typifying classes of compounds, may be anticipated in soils under
+natural conditions, it is again apparent that mineral fertilizers have
+a function in addition to the traditional one of increasing the supply
+of mineral nutrients.
+
+[118] Action of fertilizing salts on plant enzymes, by M. X. Sullivan,
+Jour. biol. chem., =6=, (1909), proceed. XLIV.
+
+[119] Private communication by Dr. Oswald Schreiner and Mr. J. J.
+Skinner.
+
+The fact that the oxidizing power of roots is more marked when grown
+in aqueous extracts of soils in good tilth than in extracts made from
+soils in poor tilth, shows that cultural methods are no less important
+in field practice than are fertilizers in promoting this important
+activity of plants. There is little reason to doubt that oxidizing
+agencies other than plant roots (bacterial for instance) are more or
+less active in every arable soil, and numerous investigations, among
+which Russell’s researches[120] are conspicuous, leave little doubt
+that oxidation processes are promoted by good tilth. It is apparent,
+therefore, that by the activities of the plant itself as well as other
+agencies, the general tendency in soils is the destruction of or
+rendering innocuous harmful plant effluvia or other organic substances,
+and to this end are effective each of the three methods of soil control
+generally practiced, namely, tillage, crop rotation and fertilizers.
+
+Among the organic components of the soil none have greater importance
+and interest than those containing nitrogen or as they are frequently
+called the nitrogen carriers. Conspicuous among these are the nitrates.
+While it is now generally conceded that ammonia and other nitrogen
+compounds can be taken up by higher plants and elaborated by them under
+special conditions, it nevertheless remains true that plants draw their
+needed supplies of nitrogen from the soil solution, mainly in the
+form of nitrates. The problems presented by these nitrogen carriers
+are mainly bacterial[121] and physiological, but certain features
+are of direct importance to the soil chemist and to a study of the
+soil solution. It is now known generally that there are many kinds of
+nitrifying and denitrifying bacteria in soils, and that probably every
+arable soil contains several species, or varieties at least of both
+kinds. With good tilth and consequent aerobic conditions, nitrifying
+processes prevail, and with poor tilth or in subsoils, anaerobic
+conditions and denitrifying processes prevail. Warmth, moisture, the
+reaction of the soil, and perhaps other factors markedly affect the
+activity of the organisms of the soil solution. Another important
+factor is that the absorptive powers of the higher plants are markedly
+affected by sunlight, so that, especially on bright and clear days,
+there is generally a higher concentration of nitrates in the soil
+solution in the morning than in the evening. This fact would seem to
+affect seriously the value of some recent and extensive investigations
+where it has been sought to classify soils by their content of
+water-dissolved nitrates. Nitric acid is more readily leached from
+soils than are most other acid radicals. Consequently nitrates, like
+other organic components of the soil solution, and unlike inorganic
+components, tend to vary greatly in concentration.
+
+[120] Oxidation in soils, and its connection with fertility, by
+Edward J. Russell: Jour. Agric. Sci., I, 261-279, (1905); Pt. II. The
+influence of partial sterilization, by Francis V. Darbishire and Edward
+J. Russell, =2=, 305-326, (1907).
+
+[121] The fixation of atmospheric nitrogen by bacteria, by J. G.
+Lipman, Bull. =81=, Bureau of Chemistry, U. S. Dept. of Agriculture,
+1904, p. 146-160; A review of investigations in soil bacteriology,
+by Edward B. Voorhees and Jacob G. Lipman, Bull, =194=, Office of
+Experiment Stations, U. S. Dept. of Agriculture, 1907.
+
+
+
+
+Chapter XII.
+
+FERTILIZERS.
+
+
+It is generally recognized that the great practical problem confronting
+the soil chemist is the proper use of soil amendments or fertilizers.
+The farmers of the United States now spend annually for fertilizers
+upwards of $100,000,000. It is estimated by various authorities that
+a large fraction, perhaps as much as three-fourths, of the material
+represented by this expenditure is misapplied for lack of intelligent
+direction. Yet all of this enormous mass of fertilizers can be used
+to advantage. Great as it is, it is relatively small beside the total
+which will, and must, be used in a not distant future, with the growth
+and development of intensive methods of cultivation consequent upon
+the rapid settling of the country, the practical disappearance of new
+lands and the increase in money value of the old lands. The commercial
+importance of the problem, therefore, makes it desirable that special
+emphasis should be given to fertilizers from the point of view
+developed in the preceding chapters. It should be recalled that the use
+of fertilizers constitutes one of the three great general methods of
+soil control, and further that while tillage methods, crop rotations,
+and fertilizer applications can be used to supplement one another, no
+one of these methods can be expected to take satisfactorily the place
+of another.
+
+Crop production is dependent upon a large number of factors. Upon the
+rainfall, both as to the amount and distribution; upon the sunlight, as
+to amount and distribution; upon the chemical and physical properties
+of the soil; soil bacteria and other biologic agents; enzymes in the
+soil; biological factors in the plant, and probably many other things.
+Opinions do and will continue to differ as to what these factors are,
+but at least every one agrees that they are many.
+
+Attempting to formulate these factors develops fundamental
+difficulties, since it is not positively known how far the variables
+are dependent or independent, and we have no idea as to the nature of
+the function or functions. The weight of existing evidence favors the
+view that all the factors are dependent variables, although numerous
+attempts have been made from time to time to show that some one factor,
+such as the rainfall for instance, or the mean annual temperature, or
+available plant-food, is _practically_ an independent factor. Although
+it should be rather easy to determine experimentally the nature of the
+function, if any of these various factors were independent, this has
+never been done, and this fact is itself a strong argument that all the
+factors in crop production are dependent on one another.
+
+When there is introduced into the equation a factor for any one of
+the methods of soil control, _i. e._, tillage, crop rotation, or
+fertilizers, it becomes even more apparent that the function is
+determined by dependent variables, for the new factor always more or
+less affects several if not all of those already cited. For instance,
+fertilizers certainly affect the chemical properties of the soil, its
+physical properties, the soil bacteria, perhaps the plant-food supply,
+the oxidation of plant effluvia and other factors. It is obvious,
+therefore, that a satisfactory theory of fertilizer action can not be a
+simple one but must of necessity be complex; and the same statement is
+no less true as regards tillage and crop rotation.
+
+The recognition of the fact that the action of fertilizers is a complex
+function depending upon many factors and groups of factors which vary
+among themselves and with each individual soil, carries with it the
+conviction that an exact or quantitative fertilizer practice, while
+theoretically possible, is probably unattainable since methods for the
+solution of such complex functions are generally wanting. It is not
+surprising, therefore, that the empirical experience of the past has
+failed to develop a quantitative practice. However disappointing this
+may seem at first sight, the prospect is not altogether hopeless, for
+this point of view indicates a systematic scheme for experimentally
+determining a qualitative, but nevertheless rational, fertilizer
+practice. The dominance of the plant-food theory of fertilizers in
+the past, shutting off, as it has, a rational attack of the problem,
+is causing the annual waste of millions of dollars in misapplied
+fertilizers, and it is of scarcely less economic than scientific
+importance to investigate and extend our knowledge of the effect
+of soil amendments upon the many factors in crop production. With a
+knowledge of the effect of fertilizers upon the physical, chemical
+and biological factors in crop production, and of the nature of the
+interdependence of these factors, will come the ability to manage
+intelligently the individual field for the particular crop. This
+knowledge can only come by attacking the problem from the dynamic
+viewpoint, and so far as the soil factors are concerned, they can
+apparently be studied best as they affect the properties of the soil
+solution.
+
+While it seems certain that some fertilizer effects are directly upon
+the soil and secondarily upon the plants, it cannot be doubted that in
+others, the phenomena are more directly concerned with the absorption
+by and the metabolism within the plant and until these plant processes
+are better understood, nothing approaching a satisfactory practice can
+be anticipated. Why and how plants exercise the selective powers they
+appear to possess are fundamental questions yet to be answered. The
+important effects sometimes produced by adding to the nutrient medium
+such substances as manganese salts which are not necessary to the
+growth of the plant, can no more be neglected than the study of the
+phosphorus needs. The presence in the soil universally of substances
+other than the recognized mineral nutrients,[122] may very well have a
+significance for plant production hitherto unsuspected, for the fact
+that an organism can continue to function in the absence of a substance
+is no argument, much less proof, that it would not function better with
+that substance present. Recent investigations, showing that animal
+organisms are sometimes more resistant to certain toxins and diseases
+under starvation conditions or when ingesting substances unnecessary
+to normal development, suggest the possibility at least of similar
+phenomena with plants. It is at any rate clear that the practical
+problem of the best production of plants from soils is not merely one
+of providing a relatively large supply of potassium, phosphorus and
+nitrogen.
+
+[122] See, for instance, Barium in soils, by G. H. Failyer, Bull. No.
+=71=, Bureau of Soils, U. S. Dept. of Agriculture, 1910.
+
+In this connection it is well to consider what constitutes a commercial
+fertilizer. It must be a substance the addition of which either
+directly or indirectly affects the properties of the soil or the
+growing plant; it must be obtainable in large quantities and from a
+source or sources of supply not readily exhausted; and it must be
+cheap. Of the many substances filling the first condition, all those
+which fulfill also the other conditions are used as fertilizers, with
+the exception of common salt and human excrement. In spite of the fact
+that it does not contain a conventional plant-food, sodium chloride
+appears to produce results quite similar to those produced by the usual
+fertilizer salts. Its use has been followed generally by an increased
+yield of crop, but occasionally by a decreased one, and it appears not
+improbable that further investigation would show sodium chloride to
+have a considerable value as a fertilizer. Human excrement or night
+soil, and the sewage and garbage refuse of our large cities are not
+commercial fertilizers, although having undoubtedly a high agricultural
+value. Objection has been urged to them that they are “filthy” and
+liable to contain dangerous pathogenic organisms. Both objections could
+be met. It seems a more rational explanation that the agricultural
+methods of this country have not yet become sufficiently intensive to
+necessitate the conservation of such materials or to justify their
+commercial exploitation.
+
+New products will come into use from time to time, as in the case of
+calcium cyanamid and basic calcium nitrate. But it is worthy of note
+that these substances have become available not so much because of
+their agricultural value, but incidentally to the efforts of inventors
+and manufacturers to produce cheap nitric acid for the preparation of
+high explosives.[123] There seems no reason to doubt that an ample
+supply of desirable substances will always be available for fertilizer
+purposes. The immediate practical problem for the future is not the
+seeking of new fertilizers but the rational use of those at hand.
+
+[123] In this connection it may be of interest to call attention to
+the fact that the Twelfth Census shows less than a fifth of the sodium
+nitrate brought into the United States goes into the fertilizer trade.
+Moreover, the production of ammonium salts by the extensive coke and
+gas plants of the country has been practically _nil_ not because of any
+inherent difficulties in making them or because the cost of production
+has been high, but because the market demands in this country have been
+too small.
+
+
+
+
+Chapter XIII.
+
+ALKALI.
+
+
+In the preceding chapters there have been considered the phenomena
+which obtain under humid conditions. Under exceptional conditions of
+prolonged drought there occurs an accumulation of soluble mineral
+substances at or near the surface of the soil. This phenomenon is
+pronounced in arid and semi-arid regions,[124] and the accumulations
+of soluble salts occurring in such regions is known in the United
+States as “alkali,” in India as “reh,” in Africa as “brak,” and in
+other countries by various local designations. The study of the extreme
+conditions producing alkali has added materially to the present
+knowledge of the processes taking place in soil of humid areas.
+Moreover, alkali-infested areas are themselves becoming of so much
+importance with the growing needs for further new lands, that it seems
+wise to give here an outline of the chemical principles involved in
+their soil solutions.[125]
+
+Alkali is sometimes a single salt, but usually a mixture of some
+two or more of the chlorides, sulphates, carbonates, bicarbonates,
+and occasionally the nitrates, phosphates and borates, of sodium,
+magnesium, potassium, and calcium, and occasionally strontium and
+lithium. In the United States, when the carbonate of sodium is
+present to an appreciable extent, the salt mixture is known as _black
+alkali,_ in contradistinction to _white alkali_, which latter does
+not contain sodium carbonate.[126] Generally, but not always, soils
+containing alkali also contain accumulations of the less soluble
+salts, calcium carbonate, or calcium sulphate, or a mixture of the
+two. These substances, sometimes cementing the less soluble mineral
+components of the soil, sometimes almost pure, are found in layers more
+or less continuous, and from a fraction of an inch to several feet in
+thickness, in a position approximately parallel to and at a moderate
+depth below the surface of the soil. In such cases these layers form a
+“hard-pan” and frequently the treatment of this type of hard-pan is the
+most difficult and vexing problem in the management of alkali-bearing
+soils.
+
+[124] Occasional occurrence of alkali in humid regions, by Frank K.
+Cameron, Bull. No. =17=, Bureau of Soils, U. S. Dept. Agriculture,
+1901, p. 36-38. This phenomenon should not be confused with the surface
+deposition of various kinds of saline material from springs, which is
+fairly common in both humid and arid regions, the world over.
+
+[125] Alkali soils of the United States, by Clarence W. Dorsey, Bull.
+No. =35=, Bureau of Soils, U. S. Dept. Agriculture, 1906.
+
+[126] Black alkali is so called because the caustic solution containing
+sodium carbonate, in rising to the surface of the soil, dissolves
+and carries with it organic matter which is subsequently left on
+the surface in more or less blackish deposits, often ring-like in
+appearance. It is by no means uncommon, however, to find deposits of
+“black alkali” which are not black at all, and it is quite common to
+find “white alkali” so dark in color as to suggest the presence of
+sodium carbonate, although the latter be absent.
+
+The origin of alkali is often uncertain. In some cases the geological
+evidences in the area make it certain that the alkali came from the
+desiccation of former bodies of sea water which had become isolated
+from the ocean. In other cases the alkali appears to come from the
+desiccation of lakes which are the depositories of the drainage of a
+surrounding area, and which have no outlet to the sea. In still other
+cases it has been supposed that the alkali is derived from wind-borne
+sea-spray. Various explanations of a more or less special character
+with regard to particular localities or circumstances are to be found
+in the literature.[127]
+
+The chemical principles involved in the desiccation of a body of
+sea water are now pretty well understood, owing mainly to the
+investigations of van’t Hoff, Meyerhoffer, and their coworkers.[128]
+The salts in sea water and those constituting “white alkali” are mainly
+the chlorides and sulphates of sodium, potassium and magnesium.
+Calcium is also present, appearing in deep deposits as anhydrite, and
+at the surface as gypsum.
+
+[127] An interesting case is the Billings Area, Montana, where the
+alkali seems to be derived from the oxidation, solution and subsequent
+hydrolysis of the pyrites and marcasite of the neighboring Pierre
+shales. The sulphuric acid thus formed, leaching through shales and
+sandstones, takes up various bases and the predominating salts in the
+alkali of this area are the sulphates of sodium and magnesium.
+
+[128] Zur Bildung der ozeanischen Salzablagerungen, von J. H. van’t
+Hoff, Braunschweig, 1905-09. For a detailed discussion of these results
+with reference to alkali deposits see: Calcium sulphate in aqueous
+solutions, by Frank K. Cameron and James M. Bell, Bull. No. =33=,
+Bureau of Soils, U. S. Dept. Agriculture, 1906.
+
+From the results of this work it is possible to predict the order
+in which the different salts or minerals will separate from the
+evaporating solution. At ordinary temperature (25° C) the first salt to
+be deposited from the dilute solution is _gypsum_ (CaSO₄.2H₂O) followed
+by _halite_ or _sodium chloride_ (NaCl) in quantity. Sodium chloride
+continues to separate at all higher concentrations. Next will be
+deposited _kainite_ (MgSO₄KCl.3H₂O). At the concentration then reached,
+the stable sulphate of calcium is _anhydrite_ (CaSO₄), which continues
+to separate from solution as desiccation proceeds. Consequently, if the
+gypsum previously deposited is yet in contact with the solution, it
+tends to be transformed to anhydrite and at all higher concentrations
+the deposition of anhydrite may be expected. As evaporation proceeds a
+point is reached where _kainite_ and _kieserite_ (MgSO₄.H₂O) separate.
+Further evaporation brings a concentration at which _kieserite_ and
+_carnallite_ (MgCl₂.KCl.6H₂O) are precipitated, and as the process
+proceeds, finally the point is reached where _kieserite_, _carnallite_
+and _bischofite_ (MgCl₂.6H₂O) all three separate with sodium chloride.
+The final products separating at a higher temperature, 83° C., are
+the same four solids, sodium chloride, kieserite, carnallite and
+bischofite.[129] The alternate layers of anhydrite and sodium chloride
+noticeable in some desiccated sea beds is probably the result of
+alterations in temperature, anhydrite being less soluble, and sodium
+chloride somewhat more soluble in hot than in cold water. During warm
+weather there would be a greater tendency for anhydrite to separate and
+in colder weather for sodium chloride to be precipitated. Anhydrite at
+the surface would gradually absorb water vapor from the atmosphere and
+be transformed to gypsum.[130]
+
+[129] It will be interesting to compare with the above the following
+brief description of the Stassfurt salt deposits, taken from Ries’s
+Economic Geology of the United States, (1905), p. 127. “At the bottom
+is the main bed of rock salt which is broken up into layers 2-5 inches
+thick by layers of anhydrite. Above this come 200 feet of rock salt,
+with which are mixed layers of magnesium chloride and polyhalite....
+Resting on this is 180 feet of rock salt, with alternating layers of
+sulphates chiefly kieserite, the sulphate of magnesia. These layers are
+about 1 foot thick. Lastly, and uppermost, is a 135-foot bed consisting
+of a series of reddish layers of rock salts of magnesia and potassium,
+kainite ... kieserite ... carnallite ... tachhydrite ... as well as
+masses of snow-white boracite.”
+
+[130] As examples, some of the gypsum deposits of Kansas may be cited,
+according to Haworth, Mineral resources of Kansas, 1897, p. 61, and the
+classical case at Bex, Switzerland, described by J. G. F. Charpentier,
+Uber die Salz-Lagerstätte von Bex: Ann. Phys. Chim., =3=, 75-80,
+(1825), and by G. Bischof, Elements of chemical and physical geology,
+London, 1854-58, Vol. I, p. 350-1.
+
+Besides the principal salts just described, there may separate at
+one concentration or another other various double salts including
+_langbeinite_ (2MgSO₄.K₂SO₄), _polyhalite_ (K₂SO₄.MgSO₄.2CaSO₄.2H₂O),
+_glauberite_ (CaSO₄.Na₂SO₄), _syngenite_ (CaSO₄.K₂SO₄.H₂O), _potassium
+pentasulphate_ (K₂SO₄.5CaSO₄.H₂O), _krugite_ (4CaSO₄.K₂SO₄.MgSO₄.2H₂O),
+and possibly others. These are all stable over very restricted ranges
+of concentration, however, and if formed, probably seldom persist, but
+pass over to more stable salts as the desiccation proceeds, and have
+little more than a passing theoretical interest.
+
+The addition of carbonates to the system introduces some further
+modifications.[131] In this case lime carbonate is the first salt to
+be precipitated, followed probably by the same order of deposition
+as outlined above. As the mother liquor becomes more concentrated,
+it apparently loses its alkaline character, for the addition of
+an alcoholic solution of phenolphthalein does not produce the
+characteristic red color. That the solution does actually contain
+dissolved carbonates is shown by the appearance of the red color on
+diluting a portion of the mother liquor with distilled water. An
+interesting example in nature is furnished by the Great Salt Lake,
+Utah. A test of the water of this lake in 1899 gave no alkaline
+reaction with phenolphthalein, but the reaction appeared promptly when
+distilled water was added, and further examination showed the water
+to contain about 0.012 per cent. sodium carbonate.[132] Slosson has
+reported similar cases in Wyoming.[133]
+
+[131] The action of water and aqueous solutions upon soil carbonates,
+by Frank K. Cameron and James M. Bell, Bull. No. =49=, Bureau of Soils,
+U. S. Dept. Agriculture, 1907.
+
+[132] Application of the theory of solutions to study of soils, by F.
+K. Cameron, Report No. =64=, Field Operations of the Bureau of Soils,
+1899, p. 149.
+
+[133] Alkali lakes and deposits, by W. C. Knight and E. E. Slosson,
+Bull. No. =49=, Wyoming Agr. Expt. Station, 1901, p. 108.
+
+One “black alkali” system has been studied with some approach towards
+completeness.[134] In this case magnesium and potassium salts are not
+present, the system being composed of water, carbon dioxide, chlorides,
+sulphates, sodium and calcium salts, with the condition imposed, that
+the bases are present in amounts more than equivalent to the sulphuric
+and hydrochloric acids. On desiccation at 25° C calcium carbonate first
+appears followed by gypsum and then sodium sulphate decahydrate. Next
+appears a double salt (2CaSO₄.3Na₂SO₄) followed by anhydrous sodium
+sulphate, the Glauber’s salt which formerly crystallized being no
+longer stable. Sodium chloride then precipitates and the concentration
+finally reaches a point where gypsum is no longer stable, and the
+final group of salts in contact with the evaporating solution under
+conditions of stable equilibrium consists of calcium carbonate, the
+double sulphate of soda and lime, anhydrous sodium sulphate and sodium
+chloride.
+
+[134] The solubility of certain salts present in alkali soils, by Frank
+K. Cameron, J. M. Bell and W. O. Robinson, Jour. Phys. Chem., =11=,
+396-420, (1907).
+
+The desiccation of a lake which serves as the final repository
+of a regional drainage involves essentially the principles just
+discussed.[135] The constituents involved are the same. A serious
+problem involved in the consideration of this source of “alkali” is
+the high ratio of chlorine to the other constituents, in view of its
+very low ratio in the rocks from which it comes. The explanation
+undoubtedly involves the fact that the carbonates and sulphates are
+constantly being removed as calcium salts from a body of water which is
+more or less continuously receiving the drainage of any considerable
+watershed, and is at the same time subject to a relatively high rate of
+evaporation. The chlorine forming only very soluble salts under such
+conditions would be segregated and concentrated in the residual mother
+liquor. Most difficult is it to account for the relatively high ratio
+of sodium to potassium in alkali from such an origin. Some light is
+thrown on the subject by the progressive changes in concentration of a
+lake water which receives a regional drainage under arid conditions.
+To this end are given the following results of analyses of the waters
+of Utah Lake, made at different times[136] over an interval of twenty
+years, and showing that there is a segregation of chlorine and sodium
+taking place, although in this case the lake has an outlet in the
+Jordan River.
+
+[135] It has been suggested that the fact that shales or similar
+geological deposits are frequently to be found near alkali areas,
+indicates that the shales are the principal sources of the alkali. It
+is supposed that the constituents of the alkali salts were formed by
+the action of water on the shale minerals at or about the time the
+shales were deposited, and carried down with the latter. Subsequently
+the alkali has been leached out to appear at the surface of soils,
+generally at a lower level than are the shales.
+
+[136] The water of Utah Lake, by F. K. Cameron: Jour. Am. Chem. Soc.,
+=27=, 113-116, (1905).
+
+ ANALYSES OF THE WATER OF UTAH LAKE.
+ RESULTS IN PARTS PER MILLION
+
+ =========+========+=========+=======+=========+=========
+ | Clarke | Cameron | Brown | Seidell | Brown
+ | 1883 | 1899 | 1903 | 1904[137] | 1904[138]
+ ---------+--------+---------+-------+---------+---------
+ Ca | 55.8 | 67.6 | 80 | 67.7 | 67
+ Sr | — | — | — | 1.7 | —
+ Mg | 18.6 | 13.8 | 92 | 73.5 | 86
+ ---------+--------+---------+-------+---------+---------
+ Na | 17.7 | 233.7 | 247 | 207.2 | 230
+ K | ? | ? | 30 | 25.8 | 22
+ ---------+--------+---------+-------+---------+---------
+ Li | — | — | — | 0.7 | —
+ SO₄ | 130.6 | 236.7 | 365 | 332.9 | 378
+ Cl | 12.4 | 316.5 | 336 | 288.5 | 337
+ HCO₃ | — | — | 266 | 205.5 | 194
+ CO₃ | 60.9 | 23.7 | — | 24.0 | 11
+ SiO₂ | 10.0 | — | — | 22.6 | 28
+ | ————— | ————— | ————— | ————— | —————
+ Total | 306.0 | 892.0 | 1416 | 1250.1 | 1353
+ ---------+--------+---------+-------+---------+---------
+
+[137] Sample collected May 18. Lake unusually high.
+
+[138] Sample collected Aug. 31. Lake still high for that season of the
+year.
+
+The third general origin of alkali supposes that wind-borne sea-spray
+carries into the air salts which are left in very fine particles on the
+evaporation of the water, or are deposited on the ordinary atmospheric
+dust and carried over the land; and that this dust is precipitated here
+and there as may be determined by the various meteorological conditions
+which it encounters. All the land surface is supposed to be receiving
+more or less of it from time to time, but in arid regions the rainfall
+and drainage is not sufficient to return to the sea as much as is
+received therefrom.[139]
+
+[139] For a recent interesting and valuable discussion of this subject
+with reference to a particular area, see: The origin of the salt
+deposits of Rajputana, by Sir Thomas H. Holland and W. A. K. Christie,
+Records of the Geological Survey of India, =38=, 154-186, (1909).
+
+It is very probable that wind-borne salts from the sea are being
+carried over and to some extent being deposited on all the land
+surfaces of the earth. To what extent this process is taking place, and
+whether it is sufficient to account for the alkali of any particular
+region, available data fail to answer satisfactorily. Probably it is
+always associated with one of the origins of alkali already discussed
+and is in itself generally of secondary importance.
+
+An argument frequently advanced against the validity of the hypothesis
+that wind-borne sea-spray is the origin of alkali is that the relative
+proportions of the several constituents in “alkali” are seldom if
+ever those obtaining in sea water. This argument does not take into
+consideration, however, that the several salts in the spray probably
+separate into crystals of widely different size and specific gravities,
+and there may well be taking place a selective or sorting action by
+the wind. More important, undoubtedly, is the selective action taking
+place in the soil itself; it can only be an accidental coincidence
+that the constituents of alkali in any particular occurrence should
+have the same quantitative relations as in the material from which it
+originated, no matter what may have been the nature of its origin.
+
+In the field, alkali is found in a bewildering array of forms and
+types. Quite different combinations of constituents may be found in
+the same field within a few rods or even a few feet, and each case
+appears to have a distinct origin, to be in fact a law unto itself.
+Each alkali deposit represents generally the resultant from a mixture
+of salt which has been dissolved and reprecipitated a number of times,
+and which while dissolved has been seeping through the soil under
+gravitational forces, or has been moving through the soil as film
+water under capillary stresses. In either event the salt mixture has
+been subject to the power for selective absorption peculiar to the
+particular soil mass through which it has been moving. Re-solution
+is seldom an instantaneous process, and different rates of solution
+necessarily involve some separation of salts. Finally the alkali
+deposit is usually so mixed with other soil material that there cannot
+be recognized the characteristic solid phases (such, for instance,
+as the double sulphates of calcium and another base) which serve
+as guides in laboratory studies and in certain salt mines. Even if
+the characteristic salts are deposited in surface soils, it is very
+doubtful, owing to their hygroscopicity, if any but gypsum, halite and
+Glauber’s salt can persist for any length of time. The alternations
+of temperature from night to day characteristic of arid regions, with
+precipitation of dews, might easily be expected to make noticeable
+and rapid changes in the characteristics of any given alkali or salt
+mixture.
+
+It is not surprising, therefore, that attempts to account for the
+genesis and present appearance of an alkali deposit by comparison
+with artificial depositions of salt mixtures, as worked out in the
+laboratory, have generally been disappointing. On the other hand,
+laboratory studies have been quite fruitful in elucidating the
+phenomena taking place on the leaching of alkali from a soil, or
+so-called “alkali reclamation.”
+
+Whatever the origin of the alkali, its segregation at or near the
+surface of the soil is everywhere much the same; that is, there is a
+translocation and segregation of soluble salts in the below-surface
+seepage waters, determined mainly by the topographic features, but
+partly by the texture and structural properties of the soil and
+subsoil, with a subsequent rise as capillary water consequent upon
+evaporation at the surface. Precipitation of the solutes may take place
+at the surface; more commonly it takes place a few inches below,
+owing to the fact that under conditions of rapid evaporation, there is
+ordinarily a discontinuance in the capillary columns or the film water
+at a point below the surface of the soil, the water diffusing thence
+into the above-surface atmosphere as the vapor phase.
+
+The composition of alkali is varied. In the vast majority of cases, the
+world over, the predominating compound is sodium chloride. When calcium
+carbonate is a conspicuous component of the soil, as a hard-pan or
+otherwise, sodium carbonate or black alkali is also generally present,
+or apt to appear when the land is irrigated. When calcium sulphate or
+gypsum is likewise present, there is less probability of appreciable
+amounts of black alkali, and where gypsum predominates or the calcium
+carbonate is present in relatively inappreciable amounts, black alkali
+is generally absent, and sodium sulphate is an important constituent
+of the alkali. Relative rates of diffusion, selective absorption, and
+sometimes other factors are prominent, however, and the character of
+the alkali in different spots within a few yards of one another may
+differ greatly. One of the most interesting manifestations of alkali is
+the occasional occurrence of a predominating amount of calcium chloride
+which, as a result of its unusually high hygroscopicity, renders the
+soil damper, and therefore darker in color than the surrounding soil,
+and frequently causes even experts to suspect the presence of black
+alkali. Its true nature can, of course, be determined by a simple
+chemical examination.
+
+The effect of alkali on the physical properties of the soil is often
+very marked, aside from the cementing action or hard-pan formation
+by the carbonate or sulphate of lime. Black alkali, by dissolving
+and segregating the organic matter at the surface, removes from
+the lower soil layers the “humus” compounds which are of enormous
+importance to the maintenance of a soil structure favorable to plant
+growth. Moreover, black alkali is one of the best of deflocculating
+agents, and consequently soils where it is a noticeable component,
+frequently puddle with great readiness and are reclaimed with the
+utmost difficulty. Most of the other constituents of alkali, however,
+are flocculating or “crumbing” agencies, and if not present in too
+large amounts tend to increase the readiness with which the soil can
+be brought into good tilth. In this latter case, by separating in the
+solid phase, or in forming a viscous soil solution, near the saturation
+point, they sometimes produce a condition in the soil simulating
+puddling, and where it occurs below the surface, called an alkali
+hard-pan.
+
+The management of soils infested with alkali is possible in accordance
+with a few well established principles. Substantial progress has been
+made in selecting and breeding plants and strains of plants adapted
+to such soils. Extreme cases are the use of the so-called Australian
+salt-bushes as forage crops, and the growing of date-palms which
+through generations of breeding in the oases of the Sahara can thrive
+in lands so salty as to destroy most of the halophilous plants. More
+interesting is the unwitting development of the farmers of Utah of
+strains of wheat and alfalfa which easily withstand three or four
+times as high a salt content in the soil as do corresponding crops
+in other alkali regions, such as New Mexico and Arizona.[140] Black
+alkali, or one in which sodium carbonate is a prominent constituent, is
+especially destructive to vegetation, not alone on account of a toxic
+action on plants, but because in any considerable concentration it has
+a corrosive action on the plant tissue. Not only on this account but
+also because of its unfortunate effects on the physical properties
+of the soil, black alkali has received unusual attention from soil
+investigators. Hilgard[141] has repeatedly urged the use of gypsum as
+an “antidote” to black alkali, assuming that under conditions of good
+drainage and aeration a reaction takes place in accordance with the
+following equation,
+
+ Na₂CO₃ + CaSO₄ = CaCO₃ + Na₂SO₄.
+
+[140] Some mutual relations between alkali soils and vegetation,
+by Thomas H. Kearney and Frank K. Cameron, Report No. =71=, U. S.
+Dept. Agriculture, 1902; The date-palm and its utilization in the
+Southwestern states, by Walter T. Swingle, Bull. =53=, Bureau of Plant
+Industry, U. S. Dept. Agriculture, 1904; The comparative tolerance of
+various plants for the salts common in alkali soils, by T. H. Kearney
+and L. L. Harter, Bull. =113=, Bureau of Plant Industry, U. S. Dept.
+Agriculture, 1907; Tolerance of alkali by various cultures, by R. H.
+Loughridge, Bull. =133=, California Agr. Expt. Sta., 1901.
+
+[141] Soils, by E. W. Hilgard. 1906, p. 457-458.
+
+Furthermore, it has been shown that calcium salts and especially
+calcium sulphate exercise a marked ameliorating effect on the action
+of other salts upon growing vegetation.[142] On the other hand, the
+reaction indicated by the equation just given does not run to an end
+with complete precipitation of the carbonate, and the total amount
+of alkali is increased in the soil by the addition of the gypsum.
+Unfortunately, Hilgard’s suggestion has not yet acquired the sanction
+of satisfactory field demonstration, although it would seem to merit
+more consideration than has been given it. Inasmuch as lime is
+generally a prominent constituent of soils containing black alkali, it
+is possible that the maintenance of good drainage and aeration in the
+soil is itself the best corrective of black alkali.
+
+[142] With the salts occurring in alkali, it is a generality that
+the effects produced on higher green plants are relatively less with
+mixtures than with an equivalent amount of a single salt. It has
+recently been shown, however, that the contrary is true for at least
+some kinds of bacterial flora. See, On the lack of antagonism between
+certain salts, by C. B. Lipman, Bot. Gaz., =49=, 41-50, (1910).
+
+The best use of alkali soils involves irrigation, and it is in the
+application of irrigation waters that management of alkali soils finds
+its most highly developed and most important expression. With light
+sandy soils it has sometimes been found practicable to add sufficient
+water to carry the alkali down into the soil to such a depth that the
+crop is well advanced toward maturity before the alkali again rises in
+sufficient amounts to prove seriously detrimental to the more advanced
+crops which are generally far more “alkali resistant” than the young
+seedlings or the germinating seeds. In some cases this procedure can
+be practiced for a number of years without greatly increasing the
+seriousness of the alkali conditions, and it may be justified, for a
+time at least, by economic considerations. Ultimately, however, and
+more quickly with heavy than with light soils, increasing amounts
+of alkali must be brought into the surface soil, and this method of
+irrigating should not be considered as anything more than a temporary
+expedient. The only procedure which should be seriously considered
+as a permanent system on an alkali soil, no matter what the texture,
+is the installation of underground drains, for which purpose, so far,
+cylindrical tile drains commend themselves as giving the best results.
+With a well established system of tile drains, the alkali and all
+excess of soluble salts can be removed from the soil above the drains;
+and alkali rising from the soil below can, at least very largely, be
+prevented from rising to the upper soil layers. The reclamation of an
+alkali tract by underdrainage is not, however, a necessarily quick
+operation. Generally it must be a matter of several years persistent
+and careful effort, but once attained should readily be maintained. The
+reclamation of an alkali tract by flooding and underdrainage involves
+the reverse process to the crystallization of salt from a brine. If
+the water in percolating through the soil were long enough in contact
+with the salts present to become a saturated solution in equilibrium
+with them, then the composition of the resulting solution or drainage
+water would depend upon the particular solid phases or salts which are
+present in the soil, but not on the amounts of these salts; and the
+relative proportions of the mineral constituents in the drainage water
+should remain constant until some one of the solid phases in the soil
+permanently disappears.
+
+In practice, however, the water passes through the soil at different
+rates from time to time, the flow from the tiles being copious after a
+flooding but gradually diminishing as time goes on. One or both of two
+processes can therefore take place. The water may dissolve some of the
+salts without at any time or place becoming saturated. As the different
+salts have different rates of solution as well as different absolute
+solubilities, it would be expected that not only the concentration of
+the drainage water, but the composition of the dissolved salts would
+change from time to time. On the other hand, a part of the water may be
+imagined to percolate slowly through the finer openings, thus forming
+a saturated solution with respect to the alkali salts which solution,
+however, will be diluted on entrance to the drains by a part of the
+water going through the larger soil openings and dissolving but little
+salt in its passage. In this case, it would be anticipated that the
+concentration of the drainage water would increase as the amount of
+flow diminished but the composition of the dissolved salts would remain
+practically constant until some one or more of the alkali salts was
+completely removed. There are, unfortunately, but few experimental
+data by which these can be tested. In the accompanying table are given
+the results of an investigation on the reclamation of an alkali tract
+near Salt Lake City, Utah, where observations on the composition of
+the drainage water were made at frequent intervals for more than three
+years.[143]
+
+[143] See, Calcium sulphate in aqueous solution, by Frank K. Cameron
+and James M. Bell, Bull. No. =33=, 1906, p. 10 and 70, and Reclamation
+of alkali land in Salt Lake Valley, Utah, by Clarence W. Dorsey, Bull.
+No. =43=, 1907, p. 13, Bureau of Soils, U. S. Dept. Agriculture.
+
+At first sight these results might appear to show that the composition
+of the salts was remaining reasonably constant. This conclusion
+must be received with caution, however. Variations do occur in the
+constituents which are present in smaller amount, but the variations
+are not systematic and may plausibly be explained by dilution of
+saturated solution by unsaturated solution on entering the drains.
+Confining attention therefore to the constituents occurring in larger
+proportions, namely, sodium chloride, sodium sulphate and sodium
+bicarbonate (including the normal carbonate) it should be remembered
+that the percentage of sodium in these three salts does not vary much,
+and the “constancy” may be more apparent than real. Indeed a close
+inspection of the results indicates that while the sodium is remaining
+practically unchanged, there is some decrease in the chlorine and a
+corresponding increase in the sulph-ion. From this it would follow that
+the sodium chloride was being washed out of the soil more rapidly,
+proportionately, than sodium sulphate; and it would also appear that
+the solution entering the drains was not in final equilibrium with the
+salts in the soil.
+
+ COMPOSITION OF THE SALTS IN THE DRAINAGE WATER FROM
+ THE SWAN TRACT, UTAH
+
+ =================+=========+=========+=========+=========
+ Date | Ca | Mg | Na | K
+ |per cent.|per cent.|per cent.|per cent.
+ -----------------+---------+---------+---------+---------
+ 1902—September | 0.38 | 0.50 | 33.74 | 2.04
+ October | 0.23 | 0.78 | 34.73 | 1.49
+ November | 0.19 | 0.74 | 34.42 | 1.40
+ 1903—May | 0.38 | 0.61 | 34.48 | 0.84
+ June | 0.45 | 0.85 | 34.18 | 1.09
+ July | 0.50 | 0.80 | 34.06 | 1.25
+ August | 0.35 | 0.90 | 34.40 | 1.12
+ September | 0.49 | 0.72 | 34.54 | 1.24
+ October | 0.47 | 1.02 | 33.43 | 1.52
+ 1904—January | 0.15 | 0.75 | 33.93 | 1.26
+ February | 0.34 | 0.78 | 34.59 | 0.70
+ March | 0.29 | 0.77 | 34.57 | 1.28
+ April | 0.29 | 0.70 | 34.28 | 1.37
+ May | 0.71 | 0.74 | 26.92 | 4.01
+ June | 0.37 | 0.70 | 32.60 | 3.55
+ August | 0.37 | 0.86 | 33.85 | 2.13
+ September | 0.42 | 0.79 | 34.10 | 1.35
+ October | 1.04 | 0.60 | 33.01 | 1.86
+ December | 1.25 | 0.70 | 32.62 | 1.69
+ 1905—February | 0.32 | 0.67 | 33.59 | 0.99
+ March | 0.31 | 0.66 | 33.46 | 1.30
+ April | 0.35 | 0.65 | 34.20 | 1.01
+ May | 0.45 | 0.86 | 33.43 | 1.20
+ June | 0.40 | 0.94 | 34.05 | 1.32
+ July | 0.32 | 0.69 | 33.67 | 1.30
+ August | 0.35 | 1.04 | 33.12 | 1.58
+ September | 0.42 | 0.82 | 33.39 | 1.26
+ 1906—January | 0.55 | 0.84 | 33.12 | 1.11
+ =================+=========+=========+=========+=========
+ | SO₄ | Cl | HCO₃ | CO₃
+ Date |per cent.|per cent.|per cent.|per cent.
+ -----------------+---------+---------+---------+---------
+ 1902—September | 18.62 | 37.76 | 6.49 | 0.48
+ October | 19.14 | 39.52 | 5.06 | 0.29
+ November | 18.61 | 40.46 | 3.95 | 0.23
+ 1903—May | 29.90 | 38.19 | 4.30 | 0.25
+ June | 17.52 | 41.00 | 4.23 | 0.42
+ July | 18.24 | 40.24 | 4.67 | 0.30
+ August | 17.15 | 42.37 | 3.48 | 0.16
+ September | 17.31 | 42.02 | 3.36 | 0.33
+ October | 16.08 | 43.28 | 3.33 | 0.30
+ 1904—January | 20.08 | 36.64 | 6.94 | 0.25
+ February | 18.95 | 40.15 | 4.49 | ——
+ March | 16.31 | 42.28 | 3.81 | 0.19
+ April | 20.93 | 38.04 | 3.33 | 1.06
+ May | 21.26 | 40.93 | 4.05 | 1.38
+ June | 19.94 | 37.42 | 4.05 | 1.37
+ August | 17.12 | 41.31 | 3.20 | 1.16
+ September | 19.01 | 39.85 | 4.11 | 0.37
+ October | 21.42 | 36.63 | 4.68 | 0.76
+ December | 19.89 | 37.44 | 6.18 | 0.22
+ 1905—February | 22.30 | 33.32 | 8.45 | 0.36
+ March | 21.60 | 33.86 | 8.46 | 0.35
+ April | 20.03 | 36.99 | 6.22 | 0.55
+ May | 20.59 | 36.04 | 6.96 | 0.47
+ June | 20.89 | 35.85 | 5.71 | 0.84
+ July | 21.17 | 34.94 | 7.23 | 0.68
+ August | 21.58 | 35.92 | 5.72 | 0.99
+ September | 21.18 | 34.85 | 7.41 | 0.67
+ 1906—January | 21.10 | 34.35 | 8.57 | 0.36
+ -----------------+---------+---------+---------+---------
+
+How long drainage must continue before there is a radical change in the
+composition of the seepage water cannot be predicted, and unfortunately
+data regarding this point are not available. It is certain that in
+time some one or more of the salts in the soil would be removed and
+the nature of the drainage water would be changed. Alterations in the
+composition of the drainage water furnish the readiest as well as the
+best guides as to the changes and the nature of the changes taking
+place in the soil during the process of reclamation. As a practical
+matter it should be borne in mind that the persistence of the several
+salts of the alkali mixture does not mean necessarily that they are
+evenly distributed in the soil; while yet determining the composition
+of the water entering the drain, they may have disappeared from the
+upper soil layers which then may hold a solution of quite different
+character, suited to the support of crops. In the case just cited the
+soil contained, before drainage operations were commenced, upwards of
+2.7 per cent. of readily soluble salts and would not support any growth
+other than salt-bushes and similar halophilous plants. Four years later
+the soil contained less than 0.3 per cent. soluble salts and yielded
+a very satisfactory crop of alfalfa. In such cases, however, the land
+cannot be considered as finally reclaimed until a material change in
+the composition of the drainage water shows that there has been a
+complete removal of some of the solid salts from that portion of the
+soil feeding the drains.
+
+The rate at which alkali can be leached from a soil is dependent in a
+large measure upon the absorptive properties of the soil, and to some
+extent upon the nature of the salts composing the alkali. The leaching
+is more rapid from sandy than from clay soils, and white alkali is
+leached more readily than is black. In general, however, the same laws
+hold here as in any leaching of a solute from an absorbent, and it has
+been shown that even in the case of black alkali, the rate of removal
+under a constant leaching follows the law
+
+ _dx_
+ ————— = K (A - _x_).[144]
+ _dt_
+
+[144] The removal of “black alkali” by leaching, by F. K. Cameron and
+H. E. Patten, Jour. Am. Chem. Soc., =28=, 1639, (1906).
+
+In practice, the water does not percolate through the soil under a
+constant “head,” but the flow is intermittent, so that the value of the
+above formula is mainly academic. On the other hand, if the drainage
+between floodings is thorough, this procedure should be more efficient
+than any other for causing a rapid removal of the alkali salts, if, as
+is generally the case, a limited quantity of water is available.
+
+Finally, it remains to be pointed out that the use of excessive amounts
+of water on alkali tracts is quite as unfortunate in its effects as the
+use of too little. If water be added to an undrained soil or in excess
+of the capacity of the drains to remove it, incalculable harm may be
+done by enormously increasing in the surface soil the amount of salts
+brought up from the lower layers as the capillary stream rises to the
+surface in consequence of evaporation there. Should the wetting of the
+soil proceed so far as to establish good capillary connection with the
+permanent ground water, the harm may be sufficient to offset in a few
+weeks or months expensive reclamation efforts of years. The harm to the
+tract where the water is added may be far less than the harm done to
+other areas. A large proportion of existing alkali deposits or “spots”
+results from the evaporation of seepage waters coming sometimes from
+considerable distances. The over-wetting of a soil means the production
+of seepage waters which are to appear at the surface somewhere
+else, generally at a lower level, and frequently means the more or
+less complete ruin of the soils of the lower level. The experience
+of India, Africa and our own arid states in the increase of alkali
+spots following the introduction of irrigation, added to our present
+theoretical knowledge, should make the planning of an irrigation
+project without adequate drainage provisions, a stupidity, and its
+accomplishment a public crime. Quite as important is the development
+of a public opinion that the individual cultivator who deliberately or
+carelessly uses excessive amounts of water on his tract is a serious
+enemy to the body politic, and should be treated as such.
+
+
+
+
+INDEX.
+
+
+ Absorbents, Influence on soil extracts, 38
+ Absorption by soils, 9, 59, 65
+ formula, 62
+ of dyes, 60, 61
+ rate, 63
+ selective, 61
+ Acid digestion of soils, 11, 12
+ Adsorption, 9, 60
+ Alkali, 110, 118
+ Effect on soils, 118
+ Order of deposition, 112
+ Reclamation, 117, 121
+ Source, 111, 117
+ Antagonism between salts, 120
+ Apophyllite, Crystallization from water, 35
+ Apple trees, Effect of grass on, 98
+ Appleyard, James R. _See_ Walker, James, and
+ Appleyard, James R.
+ Ash analyses, 11, 13
+ Association of Official Agricultural Chemists’ analyses, quoted, 12
+ cited, 12
+ “official method”, 10, 12
+ “Available” and “non-available” plant-food elements, 8
+ Averitt, S. D. _See_ Peter, Alfred M., and Averitt, S. D.
+
+ Bacteria in soils, 103
+ Bailey, Liberty H., cited, 5
+ Balance between supply and removal of mineral plant nutrients, 75
+ Barium in soils, 107
+ Bardt, A. _See_ Doroshevskii, A. and Bardt, A.
+ Becquerel, Antoine C., cited, 67
+ quoted, 68
+ Bell, James M., and Cameron, Frank K., cited, 28
+ Bell, James M. _See also_ Cameron, Frank K., and Bell, J. M.;
+ Cameron, Frank K., Bell, J. M.,
+ and Robinson, W. O.
+ Benedick, Carl, cited, 55
+ Birner, H., and Lucanus, B., cited, 70
+ Bischof, Gustav, cited, 113
+ Black alkali, 110, 114, 119, 124
+ Blanck, Edward, cited, 63
+ Breazeale, James F., acknowledgments, 80
+ cited, 71
+ _See also_ Cameron, Frank K., and Breazeale, J. F.;
+ LeClerc, J. A. and Breazeale, J. F.
+ Briggs, Lyman J., cited, 55
+ and Lapham, Macy H., cited, 41
+ and McLane, John W., cited, 26
+ Martin, F. O., and Pearce, J. R., cited, 31
+ Brooks, William P., cited, 5
+ Brown, Bailey E., cited, 46
+ quoted, 46, 115
+ Bryan, H. _See_ Davis, R. O. E., and Bryan, H.
+ Buckingham, Edgar, cited, 30
+ Burney, W. B., quoted, 98
+
+ Cameron, Frank K., cited, 110, 114, 115
+ _See also_ Bell, James M., and Cameron, Frank K.;
+ Kearney, Thomas H. and Cameron, Frank K.;
+ Whitney, Milton, and Cameron, Frank K.
+ and Bell, James M., cited, 31, 38, 50, 113, 122
+ and Breazeale, James F., cited, 62
+ and Gallagher, Francis E., cited, 24
+ and Patten, Harrison E., cited, 63, 124
+ and Robinson, William O., cited, 27, 53
+ Bell, James M., and Robinson, William O., cited, 114
+ Calcium nitrate, basic, 108
+ Carbon dioxide in the soil, 53
+ Charpentier, Jean G. F., cited, 113
+ Chemical analysis of soils. _See_ Soil analysis—Chemical.
+ Chesneau, G., cited, 68
+ Christie, W. A. K. _See_ Holland, Sir Thomas H.,
+ and Christie, W. A. K.
+ Clarke, Frank Wigglesworth, cited, 76, 115
+ Coffey, George N., quoted, 23
+ Concentration of mineral constituents, 39
+ Concentration, Plant growth and, 70
+ Cracking of soil, 22
+ Creep, 19
+ Creighton, Henry J. M. _See_ Findlay, Alexander,
+ and Creighton, Henry J. M.
+ Critical moisture content, 24
+ Crop control methods, 7, 105
+ plants defined, 1
+ producing power and aqueous extract, 81
+ rotation, Natural, 97
+ Objects of, 4
+ yields increasing, 16
+ Crumb structure of soils, 25
+ Crumbing, 27, 119
+ Cushman, Allerton S., cited, 36
+ “Cut-off”, 22, 75
+ Cyanamid, 108
+ Czapek, Friedrich, Experiments on root etchings, 9
+ Criticism of Molisch, 101
+
+ Dachnowski, Alfred, cited, 88
+ Darbishire, Francis V., and Russell, Edward J., cited, 103
+ Darwin, Horace, cited, 22
+ Davis, R. O. E., quoted, 63
+ and Bryan, H., cited, 55
+ De Candolle, Augustin P., cited, 97
+ Degradation of rocks, 1
+ De Roode, Rudolph J. J., quoted, 98
+ Diaspore, 34
+ Dittrich, Max., cited, 13
+ Doroshevskii, A., and Bardt, A., cited, 35
+ Dorsey, Clarence W., cited, 110, 122
+ Drainage waters, Composition, 124
+ Drought limits defined, 29
+ Dunnington, Francis P., cited, 98
+ Dust, 20
+ Dyer, Bernard, cited, 40
+ method of soil analysis, 10
+ quoted, 6
+ Dynamic nature of soil phenomena, 18
+
+ Earthworms, 22
+ European soils, analyses, 16
+ Erosion, 20
+ Etchings, Root, 9
+ Ewart, A. J., cited, 18, 72, 73
+ Excreta, Toxic, 99, 100, 103
+
+ “Factors”, 11
+ Failyer, George H., cited, 107
+ _See also_ Schreiner, Oswald, and Failyer, George H. Smith,
+ Joseph G., and Wade, H. R., cited, 32
+ Fairy rings, 98
+ Feldspars, 35, 38, 55
+ Fertilizers, 4, 83, 105
+ Film water, 24
+ tenacity, Experiments, 25
+ Findlay, Alexander, and Creighton, Henry J. M., cited, 53
+ Fine a soil, to, 4
+ Fischer, Emil, and Schmidmer, Edward, cited, 61
+ “Fly-off”, 22, 75
+ Frear, William, cited, 5
+ Free, Edward Elway, cited, 20
+ Friedel, Charles and Sarasin, Edmond, cited, 34
+
+ Gallagher, Francis Edward. _See_ Cameron, Frank K.
+ and Gallagher, Francis E.
+ Gannett, Henry, cited, 76
+ Gaudechon, H. _See_ Muntz, A., and Gaudechon, H.
+ Geikie, _Sir_ Archibald, cited, 75
+ Gels, 36
+ Gilbert, Joseph H., cited, 98
+ Gonnard, F., cited, 35
+ “Good” and “poor” soils compared, 80
+ Graham, Thomas, cited, 67
+ Granulate a soil, to, 4
+ Grass, Effect on apple trees, 98
+ Gravitational water, 23
+ Great Salt Lake, Reaction of water, 113
+ Green manure, Effect on soil extracts, 87
+ Gypsum on alkali soils, 119
+
+ Hardpan, 111
+ Harter, Leonard L. _See_ Kearney, Thomas H., and Harter, L. L.
+ Hartwell, Burt L., Wheeler, H. J., and Pember, F. R., cited, 74
+ Haselhoff, Emil. _See_ König, Joseph, and Haselhoff, E.
+ Haworth, Erasmus, cited, 113
+ Heileman, William H., quoted, 65
+ Heterogeneity of soils, 1, 21, 32, 79
+ Hilgard, Eugene W., cited, 5, 6, 38, 40, 119
+ Method of soil analysis, 10
+ Hillebrand, William F., cited, 13
+ Hills, Joseph L., cited, 5
+ Holland, Sir Thomas H., and Christie, W. A. K., cited, 116
+ Hulett, George A., cited, 68
+ Humic acids, 55
+ Humus, 61
+ Hutchinson, Henry B. _See_ Russell, Edward J.,
+ and Hutchinson, Henry B.
+ Hydrolysis, 33
+
+ Imbibition, 59
+ Irrigation, 120
+
+ Johnson, Samuel W., cited, 40, 77
+ quoted, 2
+
+ Kahlenberg, Louis, and Lincoln, Azariah T., cited, 35
+ Kaolinite, 34
+ Kearney, Thomas H., and Cameron, Frank K., cited, 119
+ and Harter, Leonard L., cited, 119
+ Kentucky agricultural experiment station,
+ Method of soil analysis, 10
+ King, Franklin H., cited, 75, 76, 77
+ quoted, 46, 76
+ Knight, Wilbur C., and Slosson, Edwin E., cited, 114
+ König, Joseph, and Haselhoff, E., cited, 8
+ Kossovich, Petr. S., Experiments on root etchings, 9
+
+ Lagergren, Sten, cited, 26
+ Lake desiccation, 114
+ Lapham, Macy H. _See_ Briggs, Lyman J., and Lapham, Macy H.
+ Lawes, John B., and Gilbert, Joseph H. _See_ Gilbert, Joseph H.
+ Leather, J. Walter, cited, 23
+ Le Clerc, J. Arthur, and Breazeale, James F., cited, 14
+ Lemberg, Johann T., cited, 35
+ Liebig, Justus, cited, 8, 97
+ Liebrich, A., cited, 34
+ Liebreich, quoted, 68
+ Lieving, quoted, 68
+ Lincoln, Azariah T. _See_ Kahlenberg, Louis,
+ and Lincoln, Azariah T.
+ Lipman, Jacob G., cited, 72, 103
+ _See also_ Voorhees, Edward B., and Lipman, Jacob G.
+ Lipman, C. B., cited, 120
+ Litmus, Absorption of, 66
+ as indicator, 66
+ Livingston, Burton E., cited, 85, 88, 97
+ Loughridge, Robert H., cited, 28, 119
+ Lucanus, B. _See_ Birner, H., and Lucanus, B.
+
+ McGee, W. J., quoted, 22, 76
+ McLane, John W. _See_ Briggs, Lyman J., and McLane, John W.
+ Manure, Stable, Effect on soil extracts, 84
+ Martin, F. Oskar. _See_ Briggs, Lyman J., Martin, F. O.,
+ and Pearce, J. R.
+ Maxwell, Walter, Method of soil analysis, 10
+ Mechanical analysis, 31
+ Merrill, George P., cited, 9
+ Meyerhoffer, Wilhelm, cited, 111
+ Meyer, Victor, cited, 67
+ Minchin, George M., cited, 26
+ Mineral constituents of soil solution, 31, 37
+ Mineral plant nutrients, balance between supply and removal, 75
+ Mississippi River, Soil-carrying power, 21
+ Mixing of soils, 33
+ Moisture content, 24
+ Moisture movement into soil, 28
+ Molisch, Hans, cited, 101
+ Mooers, Charles A., cited, 10
+ Motion in soils, 19
+ Movement of soils, 20
+ Muntz, A., and Gaudechon, H., cited, 30
+ quoted, 24
+ Murray, _Sir_ John, cited, 75
+
+ Newell, Frederick H., cited, 75
+ Night-soil, 108
+ Nitrates in agriculture, 108
+ in soil solution, 103
+ Nitrogen carriers, 103
+
+ “Official method” of soil analysis, 10
+ Optimum moisture content, 24
+ Organic compounds, Effect on plants, 82
+ Organic constituents of soil solution, 54, 79
+ Orthoclase, Alteration of, 33
+ Ostwald, Wo., cited, 28
+ Oxidizing power of roots, 101
+ Oxygen in the soil, 53
+ Oxystearic acid, Toxic to plants, 96
+
+ Patten, Harrison E., cited, 24, 25, 60
+ _See_ Cameron, Frank K., and Patten, Harrison E.
+ and Waggaman, William H., cited, 9, 59
+ and Gallagher, F. E., cited, 59
+ Pearce, Julia R. _See_ Briggs, Lyman J., Martin, F. O.,
+ and Pearce, J. R.
+ Pember, F. R. _See_ Hartwell, Burt L., Wheeler, H. J.,
+ and Pember, F. R.
+ Penfield, Samuel L., cited, 13
+ Percolation experiments, 47
+ Peter, Alfred, cited, 54
+ and Averitt, S. D., cited, 10
+ Pfeffer, Wilhelm F. P., cited, 18, 72, 73, 101
+ Phlogiston theory, 17
+ Phosphates, 50
+ Picoline carboxylic acid, toxic to plants, 96
+ Plant-food theory, 16
+ Plant growth and concentration, 70
+ Plant nutrients, Supply and removal, 75
+ Plot experiments, 14
+ “Poor” and “good” soils compared, 80
+ Pot experiments, 14
+ Puddling, 25
+ Pyrogallol, 87
+ Pyrophyllite, 34
+
+ Ragweed, 97, 98
+ Rainfall, 22, 75
+ Rajputana, Salt deposits, 116
+ Rayleigh, Lord, cited, 26
+ Reed, Howard S. _See_ Schreiner, Oswald, and Reed, Howard S.;
+ Schreiner, Oswald, Reed, Howard S.,
+ and Skinner, J. J.
+ Removal of plant nutrients, Supply and, 75
+ Reversible reactions, 34
+ Ries, Heinrich, quoted, 112
+ River waters, Concentration of, 76
+ Robinson, William O. _See_ Cameron, Frank K.,
+ and Robinson, William O.;
+ Cameron, Frank K., Bell, James M.,
+ and Robinson, W. O.
+ Rodewald, H., cited, 24
+ Römer, Hermann. _See_ Wilfarth, Hermann, Römer, Hermann,
+ and Wimmer, G.
+ Root etchings, 9
+ Root growth mechanism, 19
+ Roots of growing plants, 18
+ Rotation of crops, 97
+ Rothmund, V., cited, 68
+ “Run-off”, 22, 75
+ Russell, Edward J., cited, 103
+ _See also_ Darbishire, Francis V., and Russell, Edward J.
+ and Hutchinson, Henry B, cited, 72
+
+ Sachs, Julius, Experiments on root etchings, 9
+ Salt as fertilizer, Common, 108
+ Sarasin, Edmond. _See_ Friedel, Charles,
+ and Sarasin, Edmond, 34
+ Schmidmer, Edward. _See_, Fischer, Emil, and Schmidmer, Edward.
+ Schreiner, Oswald, quoted, 102
+ and Failyer, George H., cited, 41, 47
+ and Reed, Howard S., cited, 100, 101
+ and Shorey, Edmund C., cited, 95
+ and Sullivan, M. X., cited, 100
+ Reed, Howard S., and Skinner. J. J., quoted, 89
+ Sea water, Desiccation of, 111
+ Seedlings, Growth of, 74, 80, 82, 84, 86, 88, 100, 102
+ Seedlings, Toxic action of acids and salts, 62
+ Seidell, Atherton, quoted, 115
+ Shaler, Nathaniel S., cited, 20
+ Shorey, Edmund C., cited, 95
+ _See also_ Schreiner, Oswald, and Shorey, E. C.
+ Shrinking of soils, 22
+ Skinner, J. J., quoted, 99, 102
+ Skinner, J. J. _See also_ Schreiner, Oswald, Reed, Howard S.,
+ and Skinner, J. J.
+ Slosson, Edwin E. _See_ Knight, Wilbur C.,
+ and Slosson, Edwin E.
+ Smith, Joseph G., quoted, 98
+ _See also_ Failyer, George H., Smith, Joseph G.,
+ and Wade, H. R.
+ Sodium chloride as fertilizer, 108
+ Soil, the, 1
+ Soil amendments, 105
+ analysis, Chemical, 8, 22
+ Methods, 10
+ atmosphere, 23
+ bacteria, 23, 103
+ control, 4
+ methods, 4
+ erosion, 20
+ fatigue, 100
+ heaving, 22
+ individuality, 2
+ management, 2, 3, 4
+ minerals, Chief, 32
+ moisture defined, 1
+ not a static system, 18
+ phenomena, Dynamic nature of, 18
+ shrinking, 22
+ solution defined, 1
+ Analyses, 39
+ Importance of, 2
+ Organic constituent of, 79
+ Survey Field Book, cited, 3
+ translocation by water, 20
+ wind, 21
+ Soils, Composition of, 1
+ Mineral constituents of, 32
+ Moisture content, 24
+ Water extracts of, 39
+ Solid solution defined, 59
+ Solubility of minerals, 52, 55
+ Spring, Walthère, cited, 67
+ Structure, 27
+ Subsoils, Infertility of, 88
+ Sullivan, Michael X., cited, 102
+ quoted, 68
+ _See also_ Schreiner, Oswald, and Sullivan, M. X.
+ Supply and removal of plant nutrients, 75
+ Surface effects, 67
+ Surface tension, 27
+ Swan tract, Utah, 123
+ Swingle, Walter T., cited, 119
+
+ Taylor, Frederick W., cited, 5
+ Tennessee agricultural experiment station,
+ Methods of soil analysis, 10
+ Thorne, Charles E., cited, 5
+ Tillage methods, 4
+ Objects of, 4
+ Tollens, Bernhard C. G., cited, 14
+ Toxic excreta of roots, 99, 100, 103
+
+ Udden, Johan August, quoted, 21
+ U. S. Dept. of Agriculture, Bureau of Soils.
+ _See_ Soil Survey Field Book.
+ U. S. Geological Survey, cited, 13
+ Underdrainage, 121
+ Utah Lake water analyses, 115
+
+ Van Hise, Charles R., cited, 35, 36
+ van’t Hoff, Jakob H., cited, 67, 111
+ Voorhees, Edward B., and Lipman, Jacob G., cited, 72, 103
+
+ Wade, Harold R. _See_ Failyer, George H., Smith, Joseph G.,
+ and Wade, H. R.
+ Waggaman, William H. _See_ Patten, Harrison E.,
+ and Waggaman, William H.
+ Walker, James, and Appleyard, James R., cited, 60
+ Washington, Henry S., cited, 13
+ Water, Movement into soils, 28
+ vapor, Movement in soils, 29
+ Way, John T., cited, 9
+ Weeds, Analyses of, 98
+ Weinschenk, E., cited, 35
+ Wheeler, Homer J., cited, 74
+ Wheeler, Homer J. _See also_ Hartwell, Burt L., Wheeler, H. J.,
+ and Pember, F. R.
+ White alkali, 110, 111
+ Whitney, Milton, cited, 16
+ and Cameron, Frank K., cited, 26, 42
+ Wilfarth, Hermann, Römer, Hermann, and Wimmer, G., cited, 14
+ Willard, Julius T., cited, 5
+ Wimmer, G. _See_ Wilfarth, Hermann, Römer, Hermann,
+ and Wimmer, G.
+ Wind, 20
+ Carrying power of, 21
+ Wind-borne soil material, 21, 33
+ Wöhler, Friedrich, cited, 35
+ Wolff, Emil T. von, tables, cited, 77
+ Woburn, Experiments at, 98
+
+ Young, Thomas, cited, 26
+
+ Zeolites, 9, 34, 35
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+*** END OF THE PROJECT GUTENBERG EBOOK 78317 ***
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+<body>
+<div style='text-align:center'>*** START OF THE PROJECT GUTENBERG EBOOK 78317 ***</div>
+
+<hr class="chap x-ebookmaker-drop">
+<h1>THE SOIL SOLUTION</h1>
+
+<hr class="chap x-ebookmaker-drop">
+
+<div class="chapter">
+<p class="center spb2">Published by<br> <span class="fs_150"><b>The Chemical Publishing Co.</b></span><br>
+Easton, Penna.<br>Publishers of Scientific Books</p>
+
+<table class="spb1">
+ <tbody><tr>
+ <td class="tdl">Engineering Chemistry</td>
+ <td class="tdr">Portland Cement</td>
+ </tr><tr>
+ <td class="tdl">Agricultural Chemistry</td>
+ <td class="tdr">Qualitative Analysis</td>
+ </tr><tr>
+ <td class="tdl">Household Chemistry&emsp;&nbsp;</td>
+ <td class="tdr">Chemists’ Pocket Manual</td>
+ </tr><tr>
+ <td class="tdc" colspan="2">Metallurgy, Etc.</td>
+ </tr>
+ </tbody>
+</table>
+</div>
+
+<hr class="chap x-ebookmaker-drop">
+
+<div class="chapter">
+<p class="f200"><b>The Soil Solution</b></p>
+
+<p class="f120">The Nutrient Medium for Plant Growth</p>
+
+<p class="center spa1">By</p>
+<p class="f150"><b>FRANK K. CAMERON</b></p>
+
+<p class="f90 spb2">In Charge, Physical and Chemical Investigations,<br>
+Bureau of Soils,<br>U. S. Department of Agriculture</p>
+
+<p class="center">EASTON, PA.:<br>THE CHEMICAL PUBLISHING CO.<br>
+1911</p>
+
+<p class="center">LONDON, ENGLAND:<br>
+WILLIAMS &amp; NORGATE<br>14 HENRIETTA STREET, COVENT GARDEN, W. C.</p>
+
+<p class="center">Copyright, 1911, by Edward Hart</p>
+</div>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+ <h2 class="nobreak" id="PREFACE">Preface.</h2>
+</div>
+
+<p>It has long been the custom to regard soil chemistry from one of two
+diametrically opposed points of view. Either, it has been considered
+extremely simple, or complex and hopelessly difficult. In either case
+the impression has generally prevailed that practical work in soil
+chemistry consists in treating the soil with some solvent or other and
+analyzing the resulting solution for “available” plant food elements;
+in other words, that the chemist’s role in soil studies is merely that
+of an analyst.</p>
+
+<p>Soil chemistry is complex, but not by any means hopelessly so.
+Unfortunately, the complexity of most of the problems presented has
+deterred the student of pure chemistry from attacking them, and
+because they do not offer any material pecuniary rewards, they have
+not appealed strongly to the investigator in applied chemistry.
+Investigations in soil chemistry, for their own sake, or for the sole
+purpose of increasing the sum total of human knowledge concerning the
+phenomena taking place in the soil, have been comparatively rare. The
+subject has generally been regarded from the analytical point of view
+and as incidental to agronomic studies.</p>
+
+<p>One purpose of this little book is to show the investigator in
+chemistry who is not limited by the condition that his work must bring
+some personal financial return, that the soil and its problems offer
+a field for his efforts quite worthy of ranking along-side the most
+interesting branches of pure chemistry, as well as being of the very
+highest importance to the development of the welfare of the human race.
+Another purpose is to point out the line of attack upon the problems of
+soil chemistry which at this time offers the largest opportunity for
+results. In how far the details of the story in the following pages are
+correct, time with its further investigations will tell. In a sense,
+the correctness of the details is of secondary importance. It is of the
+first importance, however, that there should be a general recognition
+that soil phenomena are essentially dynamic in character, and that the
+investigation of the properties of the soil solution and its relation
+to crop production is a procedure certain to yield results of positive
+value.</p>
+
+<p>Again, it is a purpose of this book to make available for students
+of agriculture, a systematic outline of the work so far accomplished
+in this particular field. It is to the students of to-day from whom
+are to come the investigations of the near future that the book is
+particularly addressed. Some of the details presented in the following
+pages are matters on which opposed opinions are now held strongly
+by different authorities, and to the unbiased minds of the coming
+investigators must be left the decision as to how closely the truth
+has been approximated in what is written to-day. The field of effort
+covered by this book is one in which there is an increasing activity,
+and new facts and deductions will inevitably bring modifications to
+present opinions. To encourage this further acquisition of knowledge is
+the main purpose of the book.</p>
+
+<p>The material brought together in this book has been presented to the
+faculties and students of several of our Agricultural Colleges, in the
+form of a short course of lectures. In large part, moreover, it has
+been published in Volume XIV of the Journal of Physical Chemistry. To
+make it accessible to and more easily read by one familiar with the
+progress of technical soil investigations, it has been recast in its
+present form.</p>
+
+<p>It has been assumed that the reader will have a fair working knowledge
+of the concepts of modern chemistry. Nevertheless, an effort has been
+made to avoid technical terms so far as this can be done without undue
+sacrifice of lucidity of expression. Free references have been made to
+the bulletins of the Bureau of Soils, U. S. Department of Agriculture,
+because they are generally accessible to the American student, and
+because in them will be found detailed discussions and bibliographical
+material pertinent to the subjects outlined here. To his coworkers,
+the author is indebted for many criticisms and suggestions; and more
+especially in the making of the book is he indebted to Mr. S. C. Stuntz.</p>
+
+<p>Washington, D. C.<br><span class="ws3">1911.</span></p>
+
+<hr class="chap x-ebookmaker-drop">
+
+<div class="chapter">
+<p class="f150"><b>Table of Contents.</b></p>
+<hr class="r10">
+
+<table class="spb1">
+ <tbody><tr>
+ <td class="tdc" colspan="2">&nbsp;</td>
+ <td class="tdr fs_80">PAGE</td>
+ </tr><tr>
+ <td class="tdr">&nbsp;</td>
+ <td class="tdl_wsp">Preface</td>
+ <td class="tdr"><a href="#PREFACE">iii</a></td>
+ </tr><tr>
+ <td class="tdr">I.</td>
+ <td class="tdl_wsp">The Soil</td>
+ <td class="tdr"><a href="#Page_1">&nbsp;1</a></td>
+ </tr><tr>
+ <td class="tdr">II.</td>
+ <td class="tdl_wsp">Soil Management or Control</td>
+ <td class="tdr"><a href="#Page_4">&nbsp;4</a></td>
+ </tr><tr>
+ <td class="tdr">III.</td>
+ <td class="tdl_wsp">Soil Analysis and the Historical Methods</td>
+ <td class="tdr">&nbsp;</td>
+ </tr><tr>
+ <td class="tdr">&nbsp;</td>
+ <td class="tdl_ws1">of Soil Investigation</td>
+ <td class="tdr"><a href="#Page_8">&nbsp;8</a></td>
+ </tr><tr>
+ <td class="tdr">IV.</td>
+ <td class="tdl_wsp">The Plant-Food Theory of Fertilizers</td>
+ <td class="tdr"><a href="#Page_16">16</a></td>
+ </tr><tr>
+ <td class="tdr">V.</td>
+ <td class="tdl_wsp">The Dynamic Nature of Soil Phenomena</td>
+ <td class="tdr"><a href="#Page_18">18</a></td>
+ </tr><tr>
+ <td class="tdr">VI.</td>
+ <td class="tdl_wsp">The Film Water</td>
+ <td class="tdr"><a href="#Page_24">24</a></td>
+ </tr><tr>
+ <td class="tdr">VII.</td>
+ <td class="tdl_wsp">The Mineral Constituents of the Soil Solution</td>
+ <td class="tdr"><a href="#Page_31">31</a></td>
+ </tr><tr>
+ <td class="tdr">VIII.</td>
+ <td class="tdl_wsp">Absorption by Soils</td>
+ <td class="tdr"><a href="#Page_59">59</a></td>
+ </tr><tr>
+ <td class="tdr">IX.</td>
+ <td class="tdl_wsp">The Relation of Plant Growth to Concentration</td>
+ <td class="tdr"><a href="#Page_70">70</a></td>
+ </tr><tr>
+ <td class="tdr">X.</td>
+ <td class="tdl_wsp">The Balance Between Supply and Removal</td>
+ <td class="tdr">&nbsp;</td>
+ </tr><tr>
+ <td class="tdr">&nbsp;</td>
+ <td class="tdl_ws1">of Mineral Plant Nutrients</td>
+ <td class="tdr"><a href="#Page_75">75</a></td>
+ </tr><tr>
+ <td class="tdr">XI.</td>
+ <td class="tdl_wsp">The Organic Constituents of the Soil Solution</td>
+ <td class="tdr"><a href="#Page_79">79</a></td>
+ </tr><tr>
+ <td class="tdr">XII.</td>
+ <td class="tdl_wsp">Fertilizers</td>
+ <td class="tdr"><a href="#Page_105">105</a></td>
+ </tr><tr>
+ <td class="tdr">XIII.</td>
+ <td class="tdl_wsp">Alkali</td>
+ <td class="tdr"><a href="#Page_110">110</a></td>
+ </tr><tr>
+ <td class="tdr">&nbsp;</td>
+ <td class="tdl_wsp">Index</td>
+ <td class="tdr"><a href="#Page_127">127</a></td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_1">[Pg 1]</span></p>
+</div>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p class="f150"><b>AN INTRODUCTION TO<br> THE STUDY OF THE<br> SOIL SOLUTION.</b></p>
+
+<hr class="chap x-ebookmaker-drop">
+<h2 class="nobreak">Chapter I.<br>
+<span class="h_subtitle">THE SOIL.</span>
+ </h2>
+</div>
+
+<p>The soil, or that part of the land surface of the earth adapted to
+the growth and support of crops, is a heterogeneous mixture composed
+of solids, gases and a liquid, and containing living organisms. There
+are present: mineral debris from rock degradation and decomposition;
+organic matter from the degradation and decomposition of former plant
+and animal tissues; the soil atmosphere, always richer in carbon
+dioxide and water vapor and possibly other gases than the atmosphere
+above the soil; living organisms, such as various kinds of bacteria and
+fungi, with the products of their activities, notably the “nitrogen
+carriers” and the enzymes; and finally the soil moisture, a solution
+of products yielded by the above components and in equilibrium or
+approaching equilibrium with the solids and gases with which it is in
+contact.</p>
+
+<p>In its relation to crop plants,&#x2060;<a id="FNanchor_1_1" href="#Footnote_1_1" class="fnanchor">[1]</a>
+that part of the soil of immediate importance is the soil moisture.
+From this solution the plants, through their roots, draw all the
+material involved in their growth, except the carbon dioxide absorbed
+through their leaves. The soil solution is the natural nutrient medium
+from which the plants absorb the mineral constituents which have been
+shown to be absolutely essential to their continued existence and
+development. And from this solution plants sometimes absorb dissolved
+organic substances, but such absorptions are probably adventitious and
+<span class="pagenum" id="Page_2">[Pg 2]</span>
+incidental to the growth of the plant in a particular environment.
+While it appears certain that no organic substance in the nutrient
+medium is necessary to the maintenance of plant growth, nevertheless
+organic substances are probably always present under natural
+conditions. They may or may not be absorbed by the plant and may affect
+it beneficially or otherwise.</p>
+
+<p>The study of the soil solution is of the first importance in the
+investigation of the relation of the soil to plant growth, and in the
+following pages there is given an outline of our present knowledge of
+the chemical principles involved, with such discussion of the physical
+and biological factors as is essential to an orderly presentation of
+the subject.</p>
+
+<p>To understand clearly the relations of the soil solution to the soil
+as a whole and to the plant which it nourishes, it is desirable to
+consider some attributes of soils in general. Every soil, no matter
+of what type it may be, is a complex system. In it various processes
+are continually in operation, excepting possibly in the extreme case
+when it remains frozen for a time at some definite temperature. The
+resultant or summation of these processes, whether expressed in
+plant production or otherwise, will vary from time to time, both
+quantitatively and in direction; for instance, as to the amount and
+kinds of plant growth it produces. That is to say, any particular
+soil area is seemingly an organic entity, functioning according to
+its own inherent properties, but subject to the modifying influences
+of environment, as by exceptional climatic extremes, flood, fire, and
+especially by artificially imposed agencies of control.</p>
+
+<p>From the practical point of view the problem of the soil in its
+relation to crop production is like the problem of the factory or of
+any other industrial endeavor, in that it is a problem of management
+or control. The soil possesses this distinction, however, that it is
+both the raw material and the factory.&#x2060;<a id="FNanchor_2_2" href="#Footnote_2_2" class="fnanchor">[2]</a>
+<span class="pagenum" id="Page_3">[Pg 3]</span>
+The processes involved are physical, chemical and biological, are
+always numerous and interdependent, and are never (speaking generally)
+exactly the same, so that each soil possesses marked individuality. No
+matter how soils may be classified, as for instance into provinces,
+series and types,&#x2060;<a id="FNanchor_3_3" href="#Footnote_3_3" class="fnanchor">[3]</a>
+the fact remains that the soil of the individual field has properties
+which give it a crop-producing power, an adaptation to a specific
+crop or crop rotation, or a responsiveness to cultural treatment,
+which can not be anticipated in any other field. Consequently, there
+is no possibility of reducing soil management or agriculture to the
+state of an exact science. That is to say, scientific investigation of
+the problems involved cannot be expected to yield absolute results,
+although furnishing the best possible basis on which to form judgments.
+Soil management, like other agricultural practices, is an art, more or
+less well founded on scientific principles, perhaps, but susceptible of
+much higher development as the scientific principles involved become
+better understood.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_4">[Pg 4]</span></p>
+ <h2 class="nobreak">Chapter II.<br>
+<span class="h_subtitle">SOIL MANAGEMENT OR CONTROL.</span>
+ </h2>
+</div>
+
+<p>Aside from such devices as greenhouses, wind-breaks, etc., which have
+a local application only, there are three general methods of soil
+control: tillage methods, such as plowing and harrowing; rotation of
+crops; and the use of soil amendments or “fertilizers.”</p>
+
+<p>The existing knowledge regarding tillage methods is generally
+considered to be fairly satisfactory. The purposes are well understood,
+namely, to break up and “fine” the soil,&#x2060;<a id="FNanchor_4_4" href="#Footnote_4_4" class="fnanchor">[4]</a>
+to keep down weeds, and by forming mulches to decrease the loss
+of water by evaporation. Not much increase is being made in our
+theoretical knowledge of this subject, although mechanical improvements
+in the implements of tillage are being and will undoubtedly continue to
+be made.</p>
+
+<p>The existing knowledge concerning crop rotations is fairly extensive,
+but it is almost entirely empirical. Some at least of the purposes
+served by a rotation of crops are fairly well known, such as the
+elimination of weeds or lower types of parasitic growth associated with
+particular crops; the introduction of humus by a grass crop or a green
+manure crop, especially by the <i>Leguminosae</i> with their symbiotic
+<i>Azobacteria</i>; the improvement in the structure or arrangement of
+the soil particles by alternating deep-rooted and shallow-rooted crops;
+the avoidance of continually growing a crop in the presence of its
+own excreta, products of decay, etc.; and lastly, economic and market
+considerations.</p>
+
+<p>The existing knowledge of fertilizers, in spite of a vast amount of
+work and an enormous literature, is still very meagre and it also is
+almost entirely empirical; and this because studies on the subject have
+been dominated for three-quarters of a century by one theory almost to
+the exclusion of any other. The exponents of this theory have generally
+<span class="pagenum" id="Page_5">[Pg 5]</span>
+assumed that the action of fertilizers is on the plant rather than on
+the soil, and is independent of other factors. That is, while it is
+admitted that other factors influence plant growth, it has been held
+that the effect of the fertilizer is not to modify the influence of
+the other factors but to directly influence the plant by increasing
+its food supply. As a consequence, it has also been generally assumed
+that the influence of fertilizers is additive, that is, the increase
+in yield of crop is proportional to the increase in fertilizer added,
+and the increase in yield produced by adding two fertilizers is the
+sum of the increases which would have been produced by each alone. In
+this form the theory is essentially a quantitative one, and fertilizer
+practice should be easily susceptible of control by chemical analyses.
+But the large mass of data obtained from plot experiments shows that
+fertilizer effects are not additive. Indeed, the addition of some one
+or more fertilizer constituent is sometimes followed by a decreased
+yield. For example, about 20 per cent. of the trials of fertilizers
+on soils growing corn and reported by the American State Experiment
+Stations show a decreased yield. And furthermore, in spite of the
+quantitative character of the theory, and the numerous analyses
+of soils and of plants which have been made, there is yet lacking
+any authoritative method for determining in quantitative terms the
+fertilizer needs of a soil. That analytical methods have a very
+restricted value in indicating even qualitatively the fertilizer needs
+of the soil is evidenced by the fact that within the past few years a
+number of the State Experiment Stations have publicly announced their
+unwillingness to undertake them.&#x2060;<a id="FNanchor_5_5" href="#Footnote_5_5" class="fnanchor">[5]</a></p>
+
+<p><span class="pagenum" id="Page_6">[Pg 6]</span>
+The common procedure has been to define some arbitrary percentage limit
+in the soil, below which the soil is supposed to require fertilizers.
+But the amount of fertilizer to be applied is suggested on the
+indefinite basis of “experience.” Thus, Hilgard, in an interesting
+discussion of this subject,&#x2060;<a id="FNanchor_6_6" href="#Footnote_6_6" class="fnanchor">[6]</a>
+quotes Dyer as showing that “on Rothamsted soils of known
+productiveness or manurial condition, it appears that when the citric
+acid extraction yields as much as 0.005 per cent. of potash and 0.010
+per cent. of phosphoric acid, the supply is adequate for normal crop
+production, so that the use of the above substances as fertilizers
+would be, if not ineffective, at least not a profitable investment.”
+Hilgard himself sets limits as determined by strong hydrochloric acid
+digestion; thus a soil containing upwards of 0.45 per cent. (K₂O) does
+not need this substance as a fertilizer, while one containing below
+0.25 per cent. does need it at once, and intermediate percentages
+indicate that potash fertilizers would probably be profitable; the
+corresponding upper and lower limits for phosphoric acid are set at
+0.10 per cent. and 0.05 per cent. But Hilgard points out that various
+things, such as the content of lime, or the texture of the soil, may
+materially alter these limits. In a very interesting set of experiments
+in which white mustard was grown in various soils, and these same soils
+diluted with various amounts of dune sand which had previously been
+extracted with strong hydrochloric acid, he found that the plants did
+best when the soils had been diluted with four times their weight of
+the extracted sand. This was the case even with a pulverulent sandy
+loam; and with a black adobe, the best results were obtained when the
+diluted soil contained but 0.15 per cent. potash (K₂O) and 0.04 per
+cent. phosphoric acid (P₂O₅). It also appears that Hilgard regards soil
+analyses of value only in the case of virgin soils or soils which have
+been out of cultivation, and in common with other authorities, he fails
+to point out how to determine the <i>amount</i> of fertilizer needed by
+lands.</p>
+
+<p>It is clear, therefore, that the principles underlying the practice or
+<span class="pagenum" id="Page_7">[Pg 7]</span>
+art of soil management and crop rotation are in a state of development
+far from satisfactory, and scientific methods of soil control yet
+wanting.&#x2060;<a id="FNanchor_7_7" href="#Footnote_7_7" class="fnanchor">[7]</a>
+Recent activities in soil investigations, however, justify the hope
+that much improvement is to be anticipated, and the application of the
+modern methods of physical, chemical, and biological research to the
+soil problem promises a sure and probably rapid advance in this branch
+of applied science.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_8">[Pg 8]</span></p>
+<h2 class="nobreak">Chapter III.<br>
+<span class="h_subtitle">SOIL ANALYSIS AND<br> THE HISTORICAL METHODS<br>
+OF SOIL INVESTIGATION.</span></h2>
+</div>
+
+<p>Owing to the labors of Davy, Boussingault, de Saussure, Liebig, Sachs,
+Knop, Salm-Horstmar, and other scarcely less distinguished savants,
+it has been clearly shown that <i>growing plants need certain mineral
+elements in order to maintain their metabolic functions</i>, and that
+<i>these mineral elements can be obtained, under normal conditions,
+from the soil</i>. All subsequent investigation has confirmed these
+statements and they can now be accepted as facts with as much assurance
+as any known law of nature.</p>
+
+<p>The determination and formulation of these two fundamental facts came
+at a time when analytical chemistry was being rapidly developed and was
+finding wide and useful applications in numerous fields of activity. It
+was natural, therefore, that analytical chemistry should be enlisted
+in this new field of work, obviously of the first importance to the
+welfare of mankind. It was early found, however, that the chemical
+analysis of a soil fails to explain its relative productivity. In
+other words the content of a soil with respect to potash, phosphoric
+acid, or other mineral plant-food constituent, bears no necessary
+relation to its crop-producing power. Many cases were found where one
+soil “analyzed well” but did not produce as large a crop as another
+soil which “analyzed poor.”&#x2060;<a id="FNanchor_8_8" href="#Footnote_8_8" class="fnanchor">[8]</a>
+To meet this difficulty a subsidiary hypothesis was brought forward,
+which rapidly gained general acceptance although lacking experimental
+support.</p>
+
+<p>This hypothesis supposes that the mineral constituents of the soil
+are present in two different chemical conditions or distinct kinds of
+combinations, one of which readily gives up its constituents to growing
+plants, while the other does not; and the constituents have, therefore,
+<span class="pagenum" id="Page_9">[Pg 9]</span>
+been called respectively “available” and “non-available.” It would
+appear from his writings that Liebig regarded this distinction as
+applying to the “absorbed” or “adsorbed” mineral matter; that is, on
+the one hand the material held in or upon the soil grains by surface
+forces, and on the other the chemically combined constituents in the
+minerals themselves. We know that Liebig was much impressed by the
+absorption experiments of Way, and himself did much work in this
+field.&#x2060;<a id="FNanchor_9_9" href="#Footnote_9_9" class="fnanchor">[9]</a>
+But the great body of soil investigators has evidently held
+to the opinion that there are two general classes of minerals in the
+soil. Some have held that the “available” potassium is held in zeolites
+or “zeolitic” minerals, an interesting example often cited being
+glauconite or “green sand marl,” which sometimes contains phosphorus
+as well as potassium;&#x2060;<a id="FNanchor_10_10" href="#Footnote_10_10" class="fnanchor">[10]</a>
+in minerals which are easily broken down by alkaline solutions, as by
+sodium carbonate solutions or ammonia; or in minerals which are easily
+broken down by organic acids supposedly excreted from the roots of
+growing plants, or formed by the decay of plant tissue.&#x2060;<a id="FNanchor_11_11" href="#Footnote_11_11" class="fnanchor">[11]</a></p>
+
+<p><span class="pagenum" id="Page_10">[Pg 10]</span>
+With the advent of this idea of a distinction between the available and
+non-available mineral plant-food elements in the soil, came attempts
+to distinguish them by analytical methods. Of these attempts we now
+have a bewildering array, most of them frankly empirical. For instance,
+Hilgard, in his classical investigation of the cotton soils for the
+Tenth Census, treated his soil samples with an excess of hydrochloric
+acid, evaporated to dryness, extracted with water, and regarded the
+extracted mineral constituents as available. In Germany, a method
+similar to Hilgard’s is now in common use, while in France nitric acid
+is preferred generally because it is supposed to have peculiar solvent
+powers on soil phosphates. In the United States the “official method”
+of the Association of Official Agricultural Chemists is to keep 10
+grams of the soil in contact with 100 cc. of a solution of hydrochloric
+acid (specific gravity 1.115) at the boiling point of water for exactly
+10 hours. In England the popular method is that proposed by Dyer,
+namely, to treat the soil with a 1 per cent. citric acid solution,
+this strength of solution being supposed at one time to represent the
+average acidity of root sap. Maxwell, in Hawaii, and afterwards in
+Australia, claimed good results for the extraction of the soil with a
+1 per cent. solution of aspartic acid, this acid being employed on the
+erroneous ground that the organic acids of the soil are amino acids,
+and that these are the effective agents in dissolving the soil minerals
+and rendering their constituents “available.” The Kentucky Agricultural
+Experiment Station favors an N/5 nitric acid solution,&#x2060;<a id="FNanchor_12_12" href="#Footnote_12_12" class="fnanchor">[12]</a>
+but does not recommend its use for soils of other localities, while in a contiguous
+state, the Tennessee Station favors the “official” method.&#x2060;<a id="FNanchor_13_13" href="#Footnote_13_13" class="fnanchor">[13]</a>
+Many other methods have been proposed, but the foregoing are typical and
+sufficient to illustrate the present status of soil analysis.</p>
+
+<p>It is clear that these several methods must give differing results. And
+it is not clear that any one of them is to be preferred to the others
+for any reasons than analytical convenience. There is no reason to
+expect that the proportion of solvent to soil required in these methods
+bears any relation whatever to the mechanism of absorption by plant
+<span class="pagenum" id="Page_11">[Pg 11]</span>
+roots. And the attempts to simulate the properties of plant sap in
+some of these solvents are obviously illogical, for the plant sap does
+not come in contact with the soil grains, except through an accidental
+destruction of the plant.</p>
+
+<p>Naturally, comparisons were attempted between the amounts of the
+mineral constituents extracted from a soil by these various solvents
+and the amounts taken up by crops growing on the soil. It was found,
+however, that the amount of any given mineral constituent extracted
+from the soil by a solvent is not, generally, the same as that taken up
+by the plant. Moreover, the ratio of one constituent to another in the
+extract bears no definite relation to the ratio of these constituents
+in the plant. Nevertheless many efforts were made to establish
+“factors.” For instance, the percentage of potash extracted from the
+soil of a field by hydrochloric acid is some multiple of the percentage
+removed by a wheat crop; it was sought to determine this multiple,
+assuming it to be a definite ratio and a natural constant, and it was
+designated as the potash factor. But there is a different factor for
+phosphorus, another for calcium, and still others for each and every
+constituent. The factors found for a soil from one area generally
+do not hold for a soil from another area. Again, different factors
+obviously must be used for different crops. And, finally, the whole
+scheme becomes hopeless when it is realized that the same crop will
+yield widely varying ash analyses, depending upon the cultural methods
+employed, the judicious selection of seed, the amount and distribution
+of rainfall and sunlight, and possibly other agencies, all of which
+affect the growth and absorptive functions of the plant to as great an
+extent as does the particular soil upon which it may be growing.</p>
+
+<p>Moreover, from the purely analytical point of view the situation is
+no better. For instance, the addition of potassium in the amounts
+usually employed in ordinary fertilizer practice generally does produce
+a noticeable effect on the yield of crop. The average application
+of potash (K₂O) is certainly less than 50 lbs. to the acre. It is
+customary to consider the surface foot of soil as the region affected
+<span class="pagenum" id="Page_12">[Pg 12]</span>
+by the fertilizer, and an acre foot in good moisture condition weighs
+about 4,000,000 lbs. To be conservative, let it be assumed that 60
+lbs. of potash have been added to 3,000,000 lbs. of soil. The official
+method of the Association of Official Agricultural Chemists calls for
+the determination of the potash in 2 grams of soil, which on the basis
+of the present assumption calls for the estimation of an added amount
+of 0.00004 gram of potash or 0.002 per cent. Taking as an example the
+report of the Association of Official Agricultural Chemists for
+1895&#x2060;<a id="FNanchor_14_14" href="#Footnote_14_14" class="fnanchor">[14]</a>
+there are given the following results obtained independently by a
+number of analysts, on soils which had presumably been sampled by the
+referee with all possible care:</p>
+
+<p class="f120"><b>Potash Calculated As Per Cent.<br>
+ of the Fine Dried Earth.</b></p>
+
+<table class="spb1">
+ <thead><tr class="smcap bt2">
+ <th class="tdc" rowspan="2">Analyst&nbsp;</th>
+ <th class="tdc bl bb fs_120" colspan="2">1</th>
+ <th class="tdc bl bb fs_120" colspan="2">2</th>
+ <th class="tdc bl bb fs_120" colspan="2">3</th>
+ <th class="tdc bl bb fs_120" colspan="2">4</th>
+ </tr><tr class="smcap bb">
+ <th class="tdc bl">Per<br>&nbsp; cent. &nbsp;</th>
+ <th class="tdc bl">&nbsp; &nbsp;Var.&nbsp; &nbsp;</th>
+ <th class="tdc bl">Per<br>&nbsp; cent. &nbsp;</th>
+ <th class="tdc bl">&nbsp; &nbsp;Var.&nbsp; &nbsp;</th>
+ <th class="tdc bl">Per<br>&nbsp; cent. &nbsp;</th>
+ <th class="tdc bl">&nbsp; &nbsp;Var.&nbsp; &nbsp;</th>
+ <th class="tdc bl">Per<br>&nbsp; cent. &nbsp;</th>
+ <th class="tdc bl">&nbsp; &nbsp;Var.&nbsp; &nbsp;</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdc">A</td>
+ <td class="tdc bl">0.359</td>
+ <td class="tdc bl">0.044</td>
+ <td class="tdc bl">0.154</td>
+ <td class="tdc bl">-0.002&nbsp;</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ </tr><tr>
+ <td class="tdc">B</td>
+ <td class="tdc bl">0.345</td>
+ <td class="tdc bl">0.030</td>
+ <td class="tdc bl">0.112|</td>
+ <td class="tdc bl">-0.044&nbsp;</td>
+ <td class="tdc bl">0.380</td>
+ <td class="tdc bl">0.051</td>
+ <td class="tdc bl">0.104</td>
+ <td class="tdc bl">-0.050</td>
+ </tr><tr>
+ <td class="tdc">C</td>
+ <td class="tdc bl">0.354</td>
+ <td class="tdc bl">0.039</td>
+ <td class="tdc bl">0.235</td>
+ <td class="tdc bl">0.079</td>
+ <td class="tdc bl">0.396</td>
+ <td class="tdc bl">0.067</td>
+ <td class="tdc bl">0.225</td>
+ <td class="tdc bl">0.071</td>
+ </tr><tr>
+ <td class="tdc">D</td>
+ <td class="tdc bl">0.260</td>
+ <td class="tdc bl">-0.055&nbsp;</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ </tr><tr>
+ <td class="tdc">E</td>
+ <td class="tdc bl">0.373</td>
+ <td class="tdc bl">0.058</td>
+ <td class="tdc bl">0.179</td>
+ <td class="tdc bl">0.023</td>
+ <td class="tdc bl">0.365</td>
+ <td class="tdc bl">0.036</td>
+ <td class="tdc bl">0.175</td>
+ <td class="tdc bl">0.021</td>
+ </tr><tr>
+ <td class="tdc">F</td>
+ <td class="tdc bl">0.210</td>
+ <td class="tdc bl">-0.105&nbsp;</td>
+ <td class="tdc bl">0.130</td>
+ <td class="tdc bl">-0.026&nbsp;</td>
+ <td class="tdc bl">0.220</td>
+ <td class="tdc bl">0.109</td>
+ <td class="tdc bl">0.109</td>
+ <td class="tdc bl">-0.045&nbsp;</td>
+ </tr><tr>
+ <td class="tdc">G</td>
+ <td class="tdc bl">0.304</td>
+ <td class="tdc bl">-0.011&nbsp;</td>
+ <td class="tdc bl">0.125</td>
+ <td class="tdc bl">-0.031&nbsp;</td>
+ <td class="tdc bl">0.286</td>
+ <td class="tdc bl">0.043</td>
+ <td class="tdc bl">0.158</td>
+ <td class="tdc bl">0.004</td>
+ </tr><tr class="bb">
+ <td class="tdc">Mean</td>
+ <td class="tdc bl">0.315</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">0.156</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">0.329</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">0.154</td>
+ <td class="tdc bl">—</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>Not only do the individual determinations show differences far in
+excess of 0.002 per cent., but the differences between each individual
+reading and the mean is greater than 0.002 per cent., so that it is
+evident from these results that the analytical procedure fails to
+recognize appreciable amounts of the so-called available plant foods.
+Consequently the “acid digestion” of a soil fails of the purpose for
+which it was designed, and it is one of the mysteries of chemical
+history that so much time and energy have been devoted to such a
+hopeless quest.
+<span class="pagenum" id="Page_13">[Pg 13]</span></p>
+
+<p>This state of affairs is the more surprising when the limitations of
+the analytical procedure are considered. The data tabulated above
+indicate that the analyses were made with an exactness that justifies
+a statement to three decimal places, that is, to three significant
+figures; and in fact, as was shown, such is necessary if the figures
+are to have any significance regarding fertilizer applications. It is
+obvious that the analysis of a finely pulverized definite mineral or
+rock is less subject to error than a sample of soil sifted through
+a 2 mm. mesh. Yet the U. S. Geological Survey commonly reports its
+analytical data to only hundredths of a per cent., that is, to
+two decimal places. What variation may be expected in duplicate
+determinations by the same analysts it is difficult to say, for such
+duplicates are not commonly published.&#x2060;<a id="FNanchor_15_15" href="#Footnote_15_15" class="fnanchor">[15]</a>
+In spite of the widespread view that the chemical analysis of a
+soil is a statement of great accuracy, it is improbable that as
+usually determined the potash content is correct to three or even
+two significant figures; it is also doubtful if the phosphoric acid
+content is correct to even one significant figure, if the total amount
+is below 0.1 per cent. of the soil. That these determinations have a
+higher accuracy than here stated is not shown by an inspection of the
+literature including the fairly numerous results reported in the annual
+Proceedings of the Association of Official Agricultural Chemists.</p>
+
+<p>It was early felt by some investigators that soil analyses were
+unsatisfactory for studying the relation of the soil to the food
+requirements of a crop, and a second method was devised, namely, the
+growing of a crop, and determining the amount of mineral constituents
+removed from the soil by analyzing the ash of the crop. From the
+point of view of practical soil management this procedure involves
+the serious difficulty of being first obliged to get the crop before
+determining what must be done to best get it. It apparently has the
+<span class="pagenum" id="Page_14">[Pg 14]</span>
+scientific advantage of directness in determining the mineral needs
+of the plant from the plant itself. If these needs were constant, the
+advantage would be real, but as already mentioned, one and the same
+plant may have a very different ash content as the result of different
+cultural methods, different climatic and seasonal factors, as well
+as different soils. Generally, a poor crop has a higher percentage
+of ash content than a good crop, and sometimes the poor crop may
+remove from the soil more in absolute amounts of some one or other of
+the ash constituents than does the good crop. The ratio of the ash
+constituents is by no means constant for any one crop, and of course
+varies with different crops.&#x2060;<a id="FNanchor_16_16" href="#Footnote_16_16" class="fnanchor">[16]</a>
+Finally, it is now known that the amount of the several mineral
+nutrients which a soil must furnish to a crop in the earlier stages of
+growth is greater than the crop contents at maturity,&#x2060;<a id="FNanchor_17_17" href="#Footnote_17_17" class="fnanchor">[17]</a>
+consequently an analysis of the ripe crop would not indicate the
+plant’s drain upon the soil at all growing periods. So that, while
+ash analyses have taught some important things concerning plant
+growth, they have of necessity failed as guides or criteria of the
+crop-producing power of a soil, its fertilizer requirements, or its
+content of “available” plant-food.</p>
+
+<p>A third method of soil investigation, also essentially analytical in
+character, is the plot or pot test. The difference between a plot or
+pot experiment is mainly one of size, although it is claimed, and with
+a certain amount of justice, that the plot experiment more nearly
+approximates actual practice, and should be given a somewhat different
+consideration than the more readily controlled pot experiment. Here
+again it has to be considered that seasonal factors and factors other
+than the soil play a relatively large part in the production of the
+crop, so that conclusions regarding the productivity of a soil can not
+<span class="pagenum" id="Page_15">[Pg 15]</span>
+be drawn from one season’s crop. Also, nowadays it is recognized
+generally that continuous growing of one crop is an incorrect practice,
+and a rotation should be followed and repeated several times before
+conclusions regarding the productivity of the soil are justified.
+If, however, the rotation has been well managed, the cultivation,
+fertilizing and soil management generally been well done for sixteen,
+twenty or more years, the soil has materially changed, and there can
+be no assurance that the treatment then best for it, is that which was
+best at the beginning of the experiment. Therefore the method throws no
+certain light on the productive power of the soil, or the availability
+of its mineral plant-food constituents. Although much has been learned
+from plot experiments, and especially from the better controlled pot
+experiments, they are inadequate to meet the fundamental problem
+of the relation of the chemical characteristics of the soil to its
+crop-producing powers.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_16">[Pg 16]</span></p>
+<h2 class="nobreak">Chapter IV.<br>
+<span class="h_subtitle">THE PLANT-FOOD THEORY<br> OF FERTILIZERS.</span></h2>
+</div>
+
+<p>The guiding principle in soil investigations for about three-quarters
+of a century and until the past few years has been the assumption that
+the principal function of the soil is to furnish mineral nutrients to
+the plant, and that, to supply a lack in the soil, fertilizers are
+added because of the mineral plant nutrients they contain. This theory
+has apparently much to support it; actually, however, the evidence
+usually cited accords better with a more comprehensive generalization
+which will be formulated in a later chapter. It is attractively simple.
+It will be shown later, however, that this very simplicity is an
+argument against its validity.</p>
+
+<p>Those substances which experience has shown to be useful soil
+amendments usually contain one or more of the constituents necessary
+to plant metabolism, commonly phosphorus, potassium, nitrogen or
+calcium. Fertilizers do not always produce increased yields of crops,
+but it has been usual to consider bad results as due to other more or
+less extraneous causes. Moreover, as will appear later, crop yield is
+as strongly affected by some substances containing no mineral plant
+nutrient as by ordinary fertilizers. Again, the plant-food theory
+has been apparently confirmed by the popular misconception that crop
+yields are decreasing. Government statistics, however, indicate very
+positively that crop yields are increasing in Europe as well as in
+America, more in areas where the acreage is stationary than in areas
+where the acreage is increasing, and in areas where fertilizers are
+not used as well as in areas where they are used. Analyses of European
+soils which have been cropped for centuries show no characteristic
+differences from the newer soils of the United States.&#x2060;<a id="FNanchor_18_18" href="#Footnote_18_18" class="fnanchor">[18]</a>
+It is true that, from bad management or other causes, individual fields
+where crop production has fallen off are not uncommon. But that such
+a condition is general or that it can be associated generally with a
+decreased content in the soil of any particular mineral substance or
+substances, is a conclusion not sustained by the available data.
+<span class="pagenum" id="Page_17">[Pg 17]</span></p>
+
+<p>The plant-food theory of fertilizers must now be regarded as entirely
+insufficient. Granting that it has been useful in the past and has
+occasioned much valuable work, it seems to have reached the point
+which another simple and temporarily useful theory, the phlogiston
+theory of combustion, reached shortly before the plant-food theory of
+fertilizers was evolved. Just as the phlogiston theory passed away when
+the elementary nature of oxygen was established and Lavoisier taught
+the scientific world to use the balance, so the plant-food theory of
+fertilizers must pass with increasing knowledge of the relation of
+soil to plant and the application of modern methods of research to the
+problem.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_18">[Pg 18]</span></p>
+<h2 class="nobreak">Chapter V.<br>
+<span class="h_subtitle">THE DYNAMIC NATURE OF<br> SOIL PHENOMENA.</span></h2>
+</div>
+
+<p>In soil investigations, until recently, the assumption has been made,
+more or less explicitly, that any given soil mass, as for instance a
+field, remains fixed or in place indefinitely. It has been admitted, of
+course, that some physical, chemical and biological processes might be
+taking place in the soil, but these have been regarded as relatively
+unimportant in their effects upon the soil mass <i>in toto</i>. It
+has been assumed that the only important change taking place in the
+soil is a loss of mineral plant nutrients, partly by leaching, partly
+by removal in the garnered crops. In other words, the soil has been
+regarded as a static system. This is a fundamental error. In studying
+the soil as a medium for crop production, we must consider the plant
+itself, or at least that part of the plant which enters the soil,
+namely, the root; the solid particles of the soil; the soil water,
+or the aqueous solution from which the plant draws all the materials
+for its sustenance, excepting the carbon dioxide absorbed by its
+aerial portions; the soil atmosphere; the biological processes taking
+place. The one common characteristic of all these things is that they
+are continually in a state of change; therefore the soil problem is
+essentially dynamic.</p>
+
+<p>The root of a growing plant is always moving.&#x2060;<a id="FNanchor_19_19" href="#Footnote_19_19" class="fnanchor">[19]</a>
+The amount of motion may be small or large, depending upon the surrounding conditions or
+<span class="pagenum" id="Page_19">[Pg 19]</span>
+attendant circumstances, but cessation of motion means the death of the
+root. This becomes evident from a consideration of the mechanism of
+root growth. The living root absorbs and excretes water and dissolved
+substances through a restricted area just back of the root tip or the
+tips of the root hairs. While absorption is taking place, however,
+there is a deposition of denser material over the absorbing area,
+or “root corking.” But coincident with the corking process, the tip
+is pushed forward between the soil grains into the nutrient medium,
+new cells are formed and a new absorbing surface continually brought
+into functional activity. A failure of the plant root to move forward
+in this way would mean a reabsorption of root effluvia with harmful
+consequences to the plant, or a corking over of the root without
+further formation of absorbing surface and with consequent cessation
+of its functioning. This would mean the inevitable death of the root,
+and, if general, of the whole plant. It is clear, therefore, that root
+penetration and absorption of plant nutrients are essentially dynamic.</p>
+
+<p>The solid components of the soil are always in motion. Every soil, no
+matter how flat the area or how well protected by vegetal covering,
+suffers some translocation of soil material through rains, as is
+evidenced by suspended material in the run-off waters. On hillsides
+this is shown by the soil accumulating on the “up” sides of fences,
+especially stone fences. In the aggregate this movement is probably
+quite large everywhere. It is manifestly so in the watersheds of many
+of the world’s important rivers as shown by their muddy waters and
+the formation of deltas, sometimes of great area and agricultural
+importance.</p>
+
+<p>With the saturation or approach to saturation of the surface soil the
+particles are more easily moved among themselves by an extraneous
+force. It is very rarely that the surface of a field is a dead level.
+Consequently when the soil is wetted, the gravitational force on the
+individual soil grains produces a more or less pronounced “creeping”
+<span class="pagenum" id="Page_20">[Pg 20]</span>
+effect down hill. On decided slopes this soil creep is believed to be
+of great importance in connection with soil erosion.&#x2060;<a id="FNanchor_20_20" href="#Footnote_20_20" class="fnanchor">[20]</a></p>
+
+<p>As important as is the translocation of material by water, quite as
+important probably is that produced by the winds. These are blowing all
+the time, uphill as well as down, and their range of action is thus
+far wider than is that of rain and flood. The effectiveness of the
+wind as a translocating agency is seldom realized or even suspected by
+the layman, although it is commonly known that the air always contains
+some dust, and dust storms are familiar phenomena. That soil material
+can be carried long distances is certain, however, as for instance
+the sirocco dust, often carried from the Sahara over Europe.&#x2060;<a id="FNanchor_21_21" href="#Footnote_21_21" class="fnanchor">[21]</a>
+Dust carried high into the air by volcanic eruptions sometimes travels
+enormous distances, as in the case of the eruption of Krakatoa, when
+such material is reported to have traveled thousands of miles, and
+volcanic debris from the eruptions at Soufrière fell upon ships several
+hundred miles distant. Arctic explorers have reported the finding of
+wind-borne soil materials over the polar ice, and mountaineers have
+observed similar deposits on snow-capped peaks. Soil material on roofs
+and similar inaccessible places has been observed many times, and
+testifies to the continual activity of the wind. The burial of objects
+even of considerable size by wind-borne soil gives like testimony.
+<span class="pagenum" id="Page_21">[Pg 21]</span></p>
+
+<p>Measurements of the amount of action of wind in translocating soil
+material are rare and probably have a qualitative value only. But
+Udden&#x2060;<a id="FNanchor_22_22" href="#Footnote_22_22" class="fnanchor">[22]</a>
+in what appears to be a conservative calculation, finds “the
+capacity of the atmosphere [over the Mississippi Valley] to transport
+dust is 1000 times as great as that of the [Mississippi] River.” The
+wind seldom is carrying anything like so great a load as it is capable
+of carrying. That is, the wind in its attack upon the land surface
+does not ordinarily obtain so large an amount of material capable of
+being wind-borne as it is possible for the wind to carry when suitable
+material is artificially provided. It should be remembered that,
+speaking generally, the velocity of the wind is lower just at the
+surface of the ground than at heights above, and it is necessary to get
+the soil material above the surface before the wind can exercise its
+full efficiency as a carrying agent.</p>
+
+<p>Moreover, wind-borne material is constantly being deposited as well
+as being removed from the land surface. It is evident, however, that
+this movement of soil material by winds is very great, and there
+is no reason to believe that it is of any less importance in other
+areas than in the Mississippi Valley. It is also evident that the
+individual grains in any surface soil of any particular field or area
+are continually and more or less rapidly changing, and the farmer is
+not dealing to-day with just the same soil complex he faced a few years
+back, or will face a few years hence.</p>
+
+<p>But besides the movements of the solid components of the soil by
+translocating agencies, other movements are constantly taking place.
+Whenever a moderately dry soil becomes wetted, it “swells up” until a
+certain critical amount of moisture is present above which there is a
+<span class="pagenum" id="Page_22">[Pg 22]</span>
+shrinking. But as a wet soil dries out again below the critical
+amount, there is again a shrinking. As it is always either raining or
+not raining, soils are always either getting wetted or are drying.
+Consequently the individual grains are continually moving about among
+themselves. A heavy object, such as stone, when left on the ground
+gradually sinks into it.&#x2060;<a id="FNanchor_23_23" href="#Footnote_23_23" class="fnanchor">[23]</a>
+Earthworms, burrowing animals and insects are continually at work
+in most arable soils. The action of frost in “heaving” a soil is
+familiar to everyone. Not so well known, however, is the fact that the
+apparently superficial cracks which occur to a greater or less extent
+in every soil, under drought conditions, are in reality quite deep,
+extending well into the subsoil. By the edges breaking off, and by
+wind- and water-borne material being carried in, considerable surface
+soil is thus brought into the subsoil. Through these various agencies,
+therefore, the solid components of the soil are continually subject
+to much mixing; subsoil is becoming surface soil, and to some extent
+<i>vice versa</i>. An important result of these various processes is
+the bringing into the surface soil of degradation and decomposition
+products from underlying rocks. The processes involved are essentially
+dynamic.&#x2060;<a id="FNanchor_24_24" href="#Footnote_24_24" class="fnanchor">[24]</a></p>
+
+<p>The soil solution is also a dynamic problem. When the rain falls on the
+soil, a part, the “run-off,” flows over the surface and finds its way
+into the regional drainage; a part immediately evaporates into the air,
+and is designated as the “fly-off;” a third part, the “cut-off,” enters
+the soil.&#x2060;<a id="FNanchor_25_25" href="#Footnote_25_25" class="fnanchor">[25]</a>
+The cut-off water penetrates the soil by way of the larger
+<span class="pagenum" id="Page_23">[Pg 23]</span>
+openings and interstices, and mainly under the influence of gravity.
+For convenience this downward-moving water is designated as
+“gravitational” water. It moves through the soil with comparative
+rapidity and a portion reappears elsewhere as seepage water, springs,
+etc. But with the return of fair-weather conditions at the surface,
+there is increased evaporation and augmentation of the fly-off, and
+there is developed a drag or “capillary pull” on the water below.
+A large portion of the cut-off thus returns to the surface, mainly
+through films over the surface of the soil grains and in the finest
+interstices.&#x2060;<a id="FNanchor_26_26" href="#Footnote_26_26" class="fnanchor">[26]</a></p>
+
+<p>The soil atmosphere is continually in motion, following with more or
+less decided lag the barometric changes in the atmosphere above the
+soil. Moreover, the chemical and physical processes continually taking
+place in the soil involve the absorption or the formation of free
+carbonic acid, and it seems probable that all rain water penetrating
+the soil gives up some oxygen to the soil atmosphere. The bacteria
+and lower life forms are necessarily undergoing changes continually.
+In fact all components of the soil are continually undergoing, or are
+involved in, changes of one kind or another.</p>
+
+<p>It is certain that investigation of the various motions and changes
+taking place in the soil is quite as important as investigation of the
+soil components, and that no clear idea of the chemistry of the soil
+can be obtained without it. The development of a rational practice of
+soil control is possible only when the soil is regarded from a dynamic
+viewpoint.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_24">[Pg 24]</span></p>
+<h2 class="nobreak">Chapter VI.<br>
+<span class="h_subtitle">THE FILM WATER.</span></h2>
+</div>
+
+<p>When a relatively small quantity of water is added to an absolutely dry
+soil or other powdered solid, there is some shrinkage in the apparent
+volume of the soil or powder. The water spreads over the surfaces of
+the solid particles in a film, and a rise in temperature shows that a
+noticeable energy change accompanies the formation of the film.&#x2060;<a id="FNanchor_27_27" href="#Footnote_27_27" class="fnanchor">[27]</a>
+With further increments of water the apparent volume of the soil increases
+until a maximum is reached. The water content at which this maximum
+volume of soil can be attained is a definite physical characteristic
+for any given soil. What is popularly known as the “optimum water
+content” corresponds to this critical content.&#x2060;<a id="FNanchor_28_28" href="#Footnote_28_28" class="fnanchor">[28]</a>
+It is the point at which further additions of water will not increase
+the thickness of the moisture film on the soil grains, but will give
+free water in the soil interstices. Just as the apparent volume of a
+given mass of soil varies with the water content, and reaches a maximum
+at a critical moisture content, so do all the physical properties vary
+<span class="pagenum" id="Page_25">[Pg 25]</span>
+and have either a maximum or minimum value at this same critical
+moisture content. Thus the apparent specific gravity of a soil reaches
+a minimum, the force required to insert a penetrating tool becomes a
+minimum, while the rate at which a soil warms up reaches a
+maximum,&#x2060;<a id="FNanchor_29_29" href="#Footnote_29_29" class="fnanchor">[29]</a>
+and the ease with which aeration takes place reaches a maximum. In
+fine, this critical water content is that at which the soil can be
+brought into the best possible physical condition for the growth of
+crops. The practical significance of the optimum water content is far
+greater than would be supposed from the attention given it hitherto
+by students of the soil. It is the content of soil water which the
+greenhouse man should strive to maintain, and which the irrigation
+farmer should seek to provide, instead of the over-wetting so common to
+the practice of both. In general farming it is that moisture content
+at which the farmer will attain the best results in plowing and
+cultivating, and attain these results most readily.</p>
+
+<p>With additions of water beyond the critical point, there is a presence
+of free water in the soil interstices accompanied by important changes
+in the soil structure. With continued additions, there is a more or
+less rapid decrease in the apparent volume; there is a tendency for
+the soil aggregates to break down and the “crumb structure” so greatly
+desired by agriculturists is less and less readily obtained, and
+working of the soil tends in some cases to produce that phenomenon
+known as “puddling.” However desirable the property of puddling may
+be to the potter or the brick maker, to the farmer it is a bane to be
+avoided above all things. To overcome it requires his best skill, and
+it usually takes several years of patient effort to restore a puddled
+soil to good tilth.</p>
+
+<p>The force with which the film water is held against the soil grains
+has not been determined as yet with any degree of precision, but it is
+certainly very great. If a soil be saturated, that is, if so much water
+be added that further additions will cause a flow of free water, and
+the soil be then submitted to some mechanical device for abstracting
+<span class="pagenum" id="Page_26">[Pg 26]</span>
+the water, the moisture content of the soil can be readily diminished
+to the critical water content; but to diminish it further by mechanical
+means is not easy. The tenacity with which film water is held by the
+soil grains has been shown in several ways. In one of these, for
+instance, a semi-permeable membrane was precipitated in the walls
+of a porous clay cell, which was then filled with sugar solution
+having an osmotic pressure of about 35 atmospheres. When this cell was
+buried in a soil having a moisture content above the optimum, water
+flowed into the cell. On the contrary, when the cell was buried in
+another sample of the same soil having a moisture content well below
+the optimum, there was a marked flow of water from the cell. It would
+appear, therefore, that the attraction between the soil grains and the
+film-forming water was certainly greater than the solution pressure of
+the sugar.&#x2060;<a id="FNanchor_30_30" href="#Footnote_30_30" class="fnanchor">[30]</a>
+Again, by whirling wetted soils in a rapidly revolving
+centrifuge,&#x2060;<a id="FNanchor_31_31" href="#Footnote_31_31" class="fnanchor">[31]</a>
+fitted with a filtering device in the periphery, and
+developing a force equivalent on the average to 3,000 times the
+attraction of gravitation, the soils could not be reduced below the
+critical water content. From the results of Lagergren,&#x2060;<a id="FNanchor_32_32" href="#Footnote_32_32" class="fnanchor">[32]</a>
+Young,&#x2060;<a id="FNanchor_33_33" href="#Footnote_33_33" class="fnanchor">[33]</a>
+and Lord Rayleigh,&#x2060;<a id="FNanchor_34_34" href="#Footnote_34_34" class="fnanchor">[34]</a>
+it appears that the force holding a very thin moisture film on the
+soil grains would be of an order of magnitude from 6,000 to 25,000
+atmospheres. This force, however, must greatly decrease with thickening
+of the film, as is shown by the fact that at the critical moisture
+content a small further addition of water produces no marked heat
+manifestation, though making a noticeable difference in the physical
+properties of the soil. Therefore, while recognizing that our knowledge
+of this force still lacks a desirable precision, it is nevertheless
+clear that the force is very great.
+<span class="pagenum" id="Page_27">[Pg 27]</span></p>
+
+<p>The function of the film water in maintaining the soil structure is
+undoubtedly important. A soil in good tilth, or good condition for
+crop growth, shows a peculiar structural arrangement of the individual
+soil grains or soil particles, which it is very difficult to describe
+in precise terms, but which is readily recognized in practice. This
+condition is usually described as a “crumb structure,” either because
+of its appearance or because of the peculiar crumbly feeling which
+a soil in this condition gives when rubbed between the fingers. The
+individual grains of soil are gathered into groups or floccules.
+While other causes may be more or less operative in particular cases,
+it seems very probable that the film water is primarily the agency
+holding together the grains in these floccules. The obvious explanation
+is that the film is exerting a holding power because of its surface
+tension. It follows, therefore, that anything which affects the surface
+tension of water should affect the structure of the soil; that is,
+the flocculation or granulation of the particles. But certain agents
+which produce respectively flocculation or deflocculation, nevertheless
+modify the surface tension of the solution in the same direction, and
+in not widely varying degree. Similar difficulties arise in attempting
+to correlate “crumbing” phenomena with the viscosity of the film
+water,&#x2060;<a id="FNanchor_35_35" href="#Footnote_35_35" class="fnanchor">[35]</a>
+and it must be admitted frankly that present views on this subject are
+very unsatisfactory, and that more careful investigation is urgently
+needed on this fundamental and important problem. Not only is the
+absence of a satisfactory theory embarrassing in considering the
+problems of soil structure and a rational control, but the difficulties
+are no less in the equally important problems of the movement of film
+moisture, and the distribution of moisture in a soil.
+<span class="pagenum" id="Page_28">[Pg 28]</span></p>
+
+<p>The movement of moisture into a soil from an illimitable supply is a
+comparatively simple phenomenon, controlled by a rate law which may be
+expressed by the equation <b><i>yⁿ</i> = <i>kt</i></b> when <i>y</i> is the
+distance through which the movement has taken place; <i>t</i> is the
+time, and <i>k</i> and <i>n</i> are characteristic constants for the
+particular soil and solution.&#x2060;<a id="FNanchor_36_36" href="#Footnote_36_36" class="fnanchor">[36]</a>
+This expression may be more readily recognized as a rate formula when
+written <b><i>dy/at</i> = A<i>yᵐ</i></b>, where A and <i>m</i> are
+constants for the particular system. The first form of the equation
+promises to be the more useful. This formula also describes the rate of
+advance of a dissolved substance into the soil.</p>
+
+<p>Owing to irregularities in the soil column this equation is more
+readily studied with capillary tubes or with such absorbents as
+filter-paper or blotting paper. The following tables will, however,
+give an idea as to its validity for soils.</p>
+
+<p class="f120"><b><span class="smcap">Alluvial Soil, Gila River.</span></b>&#x2060;<a id="FNanchor_37_37" href="#Footnote_37_37" class="fnanchor">[37]</a></p>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc">&nbsp;Time,<sup><i>t</i></sup> min.&nbsp;</th>
+ <th class="tdc bl">&nbsp;Height, <sup><i>y</i></sup> inches&nbsp;</th>
+ <th class="tdc bl">&nbsp;<i>k</i> (<i>n</i> = 1.86)&nbsp;</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdc">&#8199;2</td>
+ <td class="tdc bl">1.5</td>
+ <td class="tdc bl">1.05</td>
+ </tr><tr>
+ <td class="tdc">&#8199;5</td>
+ <td class="tdc bl">2.4</td>
+ <td class="tdc bl">1.02</td>
+ </tr><tr>
+ <td class="tdc">10</td>
+ <td class="tdc bl">3.6</td>
+ <td class="tdc bl">1.08</td>
+ </tr><tr>
+ <td class="tdc">15</td>
+ <td class="tdc bl">4.3</td>
+ <td class="tdc bl">1.01</td>
+ </tr><tr>
+ <td class="tdc">30</td>
+ <td class="tdc bl">6.3</td>
+ <td class="tdc bl">1.05</td>
+ </tr><tr class="bb">
+ <td class="tdc">60</td>
+ <td class="tdc bl">9.2</td>
+ <td class="tdc bl">1.07</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center"><b><span class="smcap fs_120">Distilled Water in Penn. Loam</span></b><br>
+(<i>t</i> = 21° C).</p>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc">&nbsp; Time,<sup><i>t</i></sup> &nbsp;<br> min.</th>
+ <th class="tdc bl">&nbsp; Height, <sup><i>y</i></sup> &nbsp;<br>cm.</th>
+ <th class="tdc bl">&nbsp;<i>k</i><br>&nbsp; (<i>n</i> = 2.25) &nbsp;</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdc">&#8199;1</td>
+ <td class="tdc bl">1.15</td>
+ <td class="tdc bl">1.37</td>
+ </tr><tr>
+ <td class="tdc">&#8199;2</td>
+ <td class="tdc bl">1.54</td>
+ <td class="tdc bl">1.33</td>
+ </tr><tr>
+ <td class="tdc">&#8199;3</td>
+ <td class="tdc bl">1.85</td>
+ <td class="tdc bl">1.33</td>
+ </tr><tr>
+ <td class="tdc">&#8199;4</td>
+ <td class="tdc bl">2.08</td>
+ <td class="tdc bl">1.30</td>
+ </tr><tr>
+ <td class="tdc">&#8199;5</td>
+ <td class="tdc bl">2.28</td>
+ <td class="tdc bl">1.28</td>
+ </tr><tr>
+ <td class="tdc">&#8199;7</td>
+ <td class="tdc bl">2.59</td>
+ <td class="tdc bl">1.21</td>
+ </tr><tr>
+ <td class="tdc">10</td>
+ <td class="tdc bl">2.97</td>
+ <td class="tdc bl">1.16</td>
+ </tr><tr>
+ <td class="tdc">15</td>
+ <td class="tdc bl">3.47</td>
+ <td class="tdc bl">1.10</td>
+ </tr><tr>
+ <td class="tdc">20</td>
+ <td class="tdc bl">3.90</td>
+ <td class="tdc bl">1.07</td>
+ </tr><tr>
+ <td class="tdc">30</td>
+ <td class="tdc bl">4.67</td>
+ <td class="tdc bl">1.06</td>
+ </tr><tr>
+ <td class="tdc">40</td>
+ <td class="tdc bl">5.39</td>
+ <td class="tdc bl">1.11</td>
+ </tr><tr>
+ <td class="tdc">50</td>
+ <td class="tdc bl">5.90</td>
+ <td class="tdc bl">1.09</td>
+ </tr><tr>
+ <td class="tdc">60</td>
+ <td class="tdc bl">6.47</td>
+ <td class="tdc bl">1.12</td>
+ </tr><tr>
+ <td class="tdc">75</td>
+ <td class="tdc bl">7.20</td>
+ <td class="tdc bl">1.13</td>
+ </tr><tr>
+ <td class="tdc">90</td>
+ <td class="tdc bl">8.03</td>
+ <td class="tdc bl">1.21</td>
+ </tr><tr class="bb">
+ <td class="tdc">105&#8199;</td>
+ <td class="tdc bl">8.72</td>
+ <td class="tdc bl">1.25</td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_29">[Pg 29]</span></p>
+
+<p class="center"><b><span class="smcap fs_120">Indigo Carmine in Penn. Loam Soil</span></b><br>
+(<i>t</i> = 21° C.).</p>
+<p class="center">Solution contained 2 grains dye per liter</p>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc">&nbsp; Time,<sup><i>t</i></sup> &nbsp;<br> min.</th>
+ <th class="tdc bl">&nbsp; Height, <sup><i>y</i></sup> &nbsp;<br>wet cm.</th>
+ <th class="tdc bl">&nbsp;<i>k</i> for water&nbsp;<br>(<i>n</i> = 2.25)</th>
+ <th class="tdc bl">&nbsp; Height<br>&nbsp;colored&nbsp;<br>cm.</th>
+ <th class="tdc bl">&nbsp;<i>k</i> for dye<br>&nbsp; (<i>n</i> = 2.25) &nbsp;</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdc">&#8199;1</td>
+ <td class="tdc bl">1.28</td>
+ <td class="tdc bl">1.75</td>
+ <td class="tdc bl">0.64</td>
+ <td class="tdc bl">0.37</td>
+ </tr><tr>
+ <td class="tdc">&#8199;2</td>
+ <td class="tdc bl">1.67</td>
+ <td class="tdc bl">1.59</td>
+ <td class="tdc bl">0.90</td>
+ <td class="tdc bl">0.39</td>
+ </tr><tr>
+ <td class="tdc">&#8199;3</td>
+ <td class="tdc bl">2.05</td>
+ <td class="tdc bl">1.68</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">&#8199;4</td>
+ <td class="tdc bl">2.26</td>
+ <td class="tdc bl">1.56</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">&#8199;5</td>
+ <td class="tdc bl">2.49</td>
+ <td class="tdc bl">1.56</td>
+ <td class="tdc bl">1.02</td>
+ <td class="tdc bl">0.21</td>
+ </tr><tr>
+ <td class="tdc">&#8199;7</td>
+ <td class="tdc bl">2.74</td>
+ <td class="tdc bl">1.38</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">10</td>
+ <td class="tdc bl">3.20</td>
+ <td class="tdc bl">1.40</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">15</td>
+ <td class="tdc bl">3.72</td>
+ <td class="tdc bl">1.29</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">20</td>
+ <td class="tdc bl">4.28</td>
+ <td class="tdc bl">1.32</td>
+ <td class="tdc bl">1.92</td>
+ <td class="tdc bl">0.22</td>
+ </tr><tr>
+ <td class="tdc">30</td>
+ <td class="tdc bl">5.10</td>
+ <td class="tdc bl">1.31</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">40</td>
+ <td class="tdc bl">5.77</td>
+ <td class="tdc bl">1.29</td>
+ <td class="tdc bl">2.69</td>
+ <td class="tdc bl">0.23</td>
+ </tr><tr>
+ <td class="tdc">50</td>
+ <td class="tdc bl">6.41</td>
+ <td class="tdc bl">1.26</td>
+ <td class="tdc bl">3.20</td>
+ <td class="tdc bl">0.28</td>
+ </tr><tr>
+ <td class="tdc">60</td>
+ <td class="tdc bl">6.90</td>
+ <td class="tdc bl">1.29</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">75</td>
+ <td class="tdc bl">7.46</td>
+ <td class="tdc bl">1.23</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr><tr>
+ <td class="tdc">90</td>
+ <td class="tdc bl">8.74</td>
+ <td class="tdc bl">1.46</td>
+ <td class="tdc bl">3.59</td>
+ <td class="tdc bl">0.20</td>
+ </tr><tr class="bb">
+ <td class="tdc">105&#8199;</td>
+ <td class="tdc bl">9.00</td>
+ <td class="tdc bl">1.33</td>
+ <td class="tdc bl">..</td>
+ <td class="tdc bl">..</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>It has also been shown repeatedly by experiment that the movement of
+moisture is relatively rapid when the moisture content of the soil
+is above the optimum, but that the movement is exceedingly slow when
+the soil has a lower water content than the optimum; that is, the
+point at which the water is entirely in the form of film water. For
+instance, if a moderately wet sample of soil be brought into intimate
+contact with an air-dry sample of the same soil, there will, at first,
+be a relatively rapid movement of the moisture, but as soon as the
+wetted portion has been brought to the “optimum” condition, no further
+movement can be detected, although the experiment has been tried of
+leaving such samples together for months and with a difference of
+water content amounting, in the case of clay soils, to 15 or 20 per
+cent. Since the drought limit, or the soil moisture content at which
+plants wilt, is, for most soils, considerably below the optimum water
+content, the movement of film water is obviously a problem of the first
+importance from a practical point of view as well as of the highest
+theoretical interest.</p>
+
+<p>The movement of water vapor, or its distillation from place to place
+in the soil, is another problem often confused with the above. Its
+<span class="pagenum" id="Page_30">[Pg 30]</span>
+importance is not yet clear, although according to some
+investigators&#x2060;<a id="FNanchor_38_38" href="#Footnote_38_38" class="fnanchor">[38]</a>
+it would appear that the addition of soluble fertilizer salts by
+causing a lowering of the vapor pressure of the water induces a
+distillation to that region from other regions of the soil as well as
+from the atmosphere above. This brings up the problem of the diffusion
+of water and other vapors through the soil. It has been shown that the
+soil “plug” retards the rate at which diffusion takes place but induces
+no other effect in the ordinary phenomenon of free diffusion. This fact
+is obviously of the first importance in the theory of mulches, but
+requires no further consideration here.&#x2060;<a id="FNanchor_39_39" href="#Footnote_39_39" class="fnanchor">[39]</a></p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_31">[Pg 31]</span></p>
+<h2 class="nobreak">Chapter VII.<br>
+<span class="h_subtitle">THE MINERAL CONSTITUENTS OF<br>
+THE SOIL SOLUTION.&#x2060;<a id="FNanchor_40_40" href="#Footnote_40_40" class="fnanchor">[40]</a></span></h2>
+</div>
+
+<p>The mineral constituents of the soil are products of the
+disintegration, degradation and decomposition of rocks. The
+decomposition products are mainly silica in the form of quartz,
+ferruginous material consisting of more or less hydrated ferric
+oxide and alumina, and hydrated aluminum silicate. The ferruginous
+material, being deposited or formed in the soil in a very finely
+divided condition, frequently coats the soil fragments to such an
+extent as completely to mask their true character. But if a soil be
+thoroughly shaken with water, and especially in the presence of some
+deflocculating agent such as a slight excess of ammonia, as in the
+ordinary preparation of a soil sample for mechanical
+ analysis&#x2060;<a id="FNanchor_41_41" href="#Footnote_41_41" class="fnanchor">[41]</a>
+the coating material is generally removed quite readily, and the
+mineral particles appear as fragments and splinters of the ordinary
+rock-forming minerals. Sometimes these fragments are more or less
+worn and rounded at the edges, showing mechanical abrasion or solvent
+action; sometimes they show evidences of partial alteration and
+decomposition; but surfaces of the unaltered mineral individuals always
+are found. These unaltered minerals occur as fragments of all sizes,
+and are to be found in the sands, silts, and presumably in the clays.
+As might be anticipated, the minerals other than quartz generally show
+a tendency to segregate in the finer mechanical separations of the
+soil. The presence of these unaltered mineral fragments in the clays
+has so far defied direct experimental proof because of the limitations
+of the microscope, but from chemical reasoning and <i>a priori</i>
+<span class="pagenum" id="Page_32">[Pg 32]</span>
+considerations there can be but little doubt that they exist in the
+clays as in the coarser separations.&#x2060;<a id="FNanchor_42_42" href="#Footnote_42_42" class="fnanchor">[42]</a></p>
+
+<p>The minerals to be anticipated in the soil are those commonly occurring
+in the rocks; but as a result of the action of mixing and transporting
+agencies, a soil normally contains minerals from rocks other than those
+from which it is primarily derived.</p>
+
+<p>It would hardly be fair to regard a beach sand, for instance, as a
+normal soil. Yet it is surprising how many minerals other than quartz
+can usually be found even in a beach sand. Opinions may differ as to
+just what are the common rock-forming minerals, and perhaps no two
+mineralogists or petrographers would give identical lists, but there
+are a number of minerals which would appear undoubtedly in every list,
+and these would be found generally in any soil. Again, it might happen
+that in any given sample of soil, no pyroxene, for instance, could be
+found; but experience shows that it would never happen in such a case
+that no amphibole, chlorite, serpentine, or other ferro-magnesian
+silicates would be present. However distinct these minerals cited may
+be from each other morphologically or optically, they are much the
+same in their chemical characteristics, their solubilities and their
+reactions with water and such dilute solutions as exist in the soil.
+Hence from the point of view of the soil chemist they may be considered
+for all practical purposes varieties of one and the same mineral
+species. Consequently an important result of researches on the minerals
+of the soil is the generalization that soils are far more heterogeneous
+than are rocks, and that <i>practically every soil contains all the
+common rock-forming minerals</i>.&#x2060;<a id="FNanchor_43_43" href="#Footnote_43_43" class="fnanchor">[43]</a></p>
+
+<p>It is not difficult to account for the heterogeneity of the mineral
+<span class="pagenum" id="Page_33">[Pg 33]</span>
+content of the soil. Many of our rocks are reconsolidated soils, and
+the alternating formation of rock and soil from the same materials
+is probably an agency, in some part at least, in the mixing of soil
+material. The action of water in carrying off and transporting surface
+material and in gullying and eroding sloping surfaces is probably a
+large factor. But this agency, like the first, is rather restricted
+and localized. Just as important as a mixing agency is the wind. This,
+unlike water, works uphill as well as down, and is more or less in
+action at all times, continually transporting soil material from place
+to place. Wind-borne dust on roofs of dwellings, on rocky mountain tops
+and similar places, where it could have been brought by no other agency
+than the wind, is sometimes found supporting vegetation. Many chemical
+and mineralogical analyses of wind-borne dust obtained from various
+locations show it to have generally the same essential characteristics
+as ordinary soils.</p>
+
+<p>Aside from the quartz and ferruginous materials mentioned above,
+the major part of the soil minerals are silicates, ferro-silicates,
+alumino-silicates, or ferro-alumino-silicates, of the common bases,
+sodium, potassium, calcium, magnesium, and ferrous iron. Other
+bases, such as lithium, barium, or the heavy metals may occasionally
+be present in appreciable amounts as may other types of silicates,
+or other mineral salts, but these may be regarded as more or less
+incidental and rarely affecting in any essential way the general
+character of the soil mass. These silicates or silico minerals are all
+somewhat soluble in water, and being salts of weak acids with strong
+bases, are greatly hydrolyzed. A convenient illustration is afforded
+by the well-known rock and soil mineral, orthoclase. Assuming its type
+formula, the reaction with water may be represented,</p>
+
+<p class="f110 no-wrap">K.AlSi₃O₈ + HOH ⇆ H.AlSi₃O₈ + KOH.</p>
+
+<p>Under ordinary soil conditions, with a relatively large proportion of
+carbon dioxide in the soil atmosphere, the potash formed would be more
+or less completely transformed to the bicarbonate,</p>
+
+<p class="f110 no-wrap">KOH + CO₂ + H₂O ⇆ KHCO₃ + H₂O.</p>
+
+<p>Confirmation of this view is afforded by the natural associations and
+known alteration products of orthoclase.
+<span class="pagenum" id="Page_34">[Pg 34]</span></p>
+
+<p>The acid of the formula H.AlSi₃O₈ is not known and is probably entirely
+instable under ordinary conditions, and breaks down with the separation
+of silica, to form the minerals pyrophyllite, kaolinite or kaolin, and
+diaspore according to the following equations:</p>
+
+<table class="spb1">
+ <tbody><tr>
+ <td class="tdl">H.AlSi₃O₈ - SiO₂</td>
+ <td class="tdl_wsp">= H.AlSi₂O₆</td>
+ <td class="tdl_ws1">(Pyrophyllite)</td>
+ </tr><tr>
+ <td class="tdl">H.AlSi₃O₈ - 2SiO₂</td>
+ <td class="tdl_wsp">= H.AlSiO₄</td>
+ <td class="tdl_ws1">(Kaolinite)</td>
+ </tr><tr>
+ <td class="tdl">H.AlSi₃O₈ - 3SiO₂</td>
+ <td class="tdl_wsp">= H.AlO₂</td>
+ <td class="tdl_ws1">(Diaspore).</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>All three of these minerals and their corresponding salts have been
+found in nature as alteration products of orthoclase. It is probable
+that, under soil conditions, the principal metamorphic product of
+feldspar is kaolin (or kaolinite when it is crystalline), hydrated
+aluminum oxide being of much less importance&#x2060;<a id="FNanchor_44_44" href="#Footnote_44_44" class="fnanchor">[44]</a>
+and pyrophyllite of doubtful occurrence. A still more interesting case,
+perhaps, because of the well recognized tendency of magnesium salts
+to form basic compounds, is the alteration of pyroxene, amphibole
+and olivine with the formation of a chlorite or serpentine, common
+associations in nature, which may be represented</p>
+
+<p class="f110 no-wrap">MgSiO₃ + HOH ⇆ MgSiO₃.<i>n</i>Mg(OH)₂ + SiO₂.</p>
+
+<p>It is tacitly assumed in the foregoing statements that the reaction
+between a silicate mineral and water is a reversible reaction. This is
+not definitely known to be the case, for the formation of the ordinary
+silicate rock-forming minerals in the wet way at ordinary temperatures
+has as yet been realized in only a few cases. The assumption has,
+however, some experimental support. Minerals have been often made in
+the wet way at somewhat elevated temperatures, especially interesting
+cases in this connection being the formation of orthoclase by Friedel
+and Sarasin&#x2060;<a id="FNanchor_45_45" href="#Footnote_45_45" class="fnanchor">[45]</a>
+at slightly elevated temperatures, and the formation of
+<span class="pagenum" id="Page_35">[Pg 35]</span>
+zeolites by Gonnard&#x2060;<a id="FNanchor_46_46" href="#Footnote_46_46" class="fnanchor">[46]</a>
+ and by Doroshevskii and Bardt,&#x2060;<a id="FNanchor_47_47" href="#Footnote_47_47" class="fnanchor">[47]</a>
+and the formation of apatite by Weinschenk.&#x2060;<a id="FNanchor_48_48" href="#Footnote_48_48" class="fnanchor">[48]</a>
+Feldspars and zeolites are common natural associations, it being
+generally conceded that zeolites are alteration products of the
+feldspars through the action of water; but Van Hise&#x2060;<a id="FNanchor_49_49" href="#Footnote_49_49" class="fnanchor">[49]</a>
+has pointed out that under conditions of weathering such as would
+obtain in the soil, the tendency is for the zeolites to alter to
+feldspars. Wöhler’s classical experiment of recrystallizing apophyllite
+from hot water&#x2060;<a id="FNanchor_50_50" href="#Footnote_50_50" class="fnanchor">[50]</a>
+is significant, for only the products of hydrolysis should be obtained
+if there is an irreversible reaction between the mineral and water.
+Lemberg found that leucite (KAlSi₂O₆) when treated with an aqueous
+solution containing 10 per cent. or more of sodium chloride, was
+partially transformed to analcite (NaAlSi₂O₆.<i>n</i>H₂O), potassium
+chloride being formed at the same time. The reverse reaction was also
+realized, that is, the partial conversion of analcite to leucite
+by treatment with a solution of potassium chloride, and similar
+transformations were carried out with the feldspars.&#x2060;<a id="FNanchor_51_51" href="#Footnote_51_51" class="fnanchor">[51]</a>
+Lemberg’s experiments are of especial value as they were carried out
+at ordinary as well as at high temperatures. It appears probable,
+therefore, that the hydrolysis of a silicate of the alkalis or alkaline
+earths is a reversible reaction. It should be noted, however, that
+Kahlenberg and Lincoln&#x2060;<a id="FNanchor_52_52" href="#Footnote_52_52" class="fnanchor">[52]</a>
+have shown that probably, in very dilute solutions of alkali silicates,
+<span class="pagenum" id="Page_36">[Pg 36]</span>
+the hydrolysis is practically complete and the silica is nearly all
+present as colloidal silica and not as silicic acid. Nevertheless at
+higher concentrations silicates are formed, and there is abundant
+evidence in nature that the alumino- or ferro-silicates are reacting
+with bases to form salts, for example such as the micas.&#x2060;<a id="FNanchor_53_53" href="#Footnote_53_53" class="fnanchor">[53]</a>
+If the hydrolysis were quite complete, it would appear to follow that
+the reaction between water and the silicate is irreversible. In that
+case it is difficult to see how any silicate mineral could persist
+in the soil for any length of time, and all soils should soon become
+sterile wastes composed essentially of quartz, kaolin and ferruginous
+oxides. It has been suggested that the original mineral particles are
+protected from decomposition by the formation of a coating “gel.”
+That is, that silica, alumina, ferruginous or other materials result
+from the decomposition of the minerals in a jelly-like form on the
+surface of the soil grains, protecting them from further action of
+the soil solution.&#x2060;<a id="FNanchor_54_54" href="#Footnote_54_54" class="fnanchor">[54]</a>
+If diffusion can take place through the gel, solution and hydrolysis
+of the mineral would proceed, although the presence of the gel would
+probably retard the rate of the reaction. If it be postulated, however,
+that diffusion through the gel does not take place, the minerals of the
+soil can have no influence on the composition of the soil solution,
+which is an unthinkable alternative. The presence of such gels in the
+soil has frequently been assumed, but satisfactory proof is generally
+wanting.</p>
+
+<p>In general, the same kind of considerations developed for orthoclase
+hold for the other soil minerals. If minerals of this character be
+<span class="pagenum" id="Page_37">[Pg 37]</span>
+pulverized or ground reasonably fine and then be shaken with distilled
+water which has been previously boiled to eliminate the dissolved
+carbon dioxide, the resulting solution will give an alkaline reaction
+with such indicators as phenolphthalein or litmus.&#x2060;<a id="FNanchor_55_55" href="#Footnote_55_55" class="fnanchor">[55]</a>
+If a soil be shaken up thoroughly with water, the resulting solution filtered
+free of suspended matter, as by passing through a Pasteur-Chamberland
+bougie, and then boiled to eliminate the carbon dioxide, in the vast
+majority of cases the solution will also give an alkaline reaction
+with phenolphthalein or litmus. The waters of most of our springs,
+ponds, creeks or rivers being natural soil solutions, give an alkaline
+reaction after boiling.</p>
+
+<p>But the mineral content of these natural waters varies greatly. These
+waters are composed in part of the “run-off,” in part of a portion of
+the “cut-off” waters, described above. This portion of the cut-off,
+normally, in passing through the soil goes mainly through the larger
+interstices. It is not long in contact with the individual soil
+particles and floccules, and because diffusion of dissolved mineral
+substances is quite slow, especially in dilute solutions, it takes up
+but little mineral matter from such aqueous films as it may intercept.</p>
+
+<p>A different state of things exists with that portion of the cut-off
+water which returns towards the surface by reason of capillary
+forces, to form the great natural nutrient medium for plants. This
+water is moving over the soil particles in films, and with slowness.
+It <i>is</i> long in contact with successive fragments of any
+particular mineral and all the different minerals making up the soil.
+Consequently, it tends towards a saturated solution with respect to
+the mineral mass; and it follows that if every soil contains all the
+common rock-forming minerals, every soil should give the same saturated
+<span class="pagenum" id="Page_38">[Pg 38]</span>
+solution, barring the presence of disturbing factors.&#x2060;<a id="FNanchor_56_56" href="#Footnote_56_56" class="fnanchor">[56]</a>
+Disturbing factors, however, enter into all cases under field conditions,
+such for instance as the presence of some uncommon or unusual mineral in
+appreciable amounts, differences in temperature, surface effects, or
+extraneous substances. These will be considered later, but another
+disturbing factor requires immediate consideration.</p>
+
+<p>In every soil, varying proportions of the soluble mineral constituents
+are present otherwise than as definite mineral species; that is, they
+are present as solid solutions, or absorbed on the soil grains or
+perhaps absorbed in some other manner. The concentration of the liquid
+solution in contact with a solid solution or complex of absorbent and
+absorbed material is dependent upon the relative masses of solution and
+solid. Thus, the concentration of a solution with respect to phosphoric
+acid, when brought into contact with so-called basic phosphates of lime
+or iron, is dependent in a marked way upon the proportion of solution
+to solid.&#x2060;<a id="FNanchor_57_57" href="#Footnote_57_57" class="fnanchor">[57]</a>
+Consequently it is to be expected that an aqueous extract of a soil
+will vary in concentration with the proportion of water used; and that
+with the same proportion of water, different soils or different samples
+of the same soil will yield different concentrations.</p>
+
+<p>How far absorbed mineral constituents affect the solubility of the
+definite minerals in the soil or influence the concentration of the
+soil solution, it is not possible to predict with any approach to
+certainty. Those soils which hold the most moisture are generally the
+best absorbers. Moreover, the soluble mineral constituents of the soil,
+for instance potassium or phosphoric acid, are absorbed to a very high
+<span class="pagenum" id="Page_39">[Pg 39]</span>
+degree from dilute solutions. Consequently it is to be expected that
+variations in the concentration of the natural soil solution would be
+less than in aqueous extracts, when there is employed a constant and
+relatively large proportion of water to soil. These considerations
+are of great theoretical importance since they appear to negative
+the possibility of getting, with present experimental resources,
+any <i>exact</i> knowledge of the concentrations of the mineral
+constituents in the soil solution when the soil is in condition to
+grow the common crop plants. Moreover, they furnish a guide to the
+limitations which must be recognized in attempting to postulate what
+these concentrations may be on the basis of analytical data obtained
+from aqueous soil extracts.</p>
+
+<p>Many attempts have been made to extract the solution naturally existing
+in the soil and to analyze it. The results obtained have not been very
+satisfactory, owing mainly to the mechanical difficulties involved. As
+pointed out above, the solution in a soil under suitable conditions for
+crop growth is held by a force of great magnitude. Nevertheless, by
+using powerful centrifuges, with saturated soil, it has been possible
+to throw out the excess of solution over the critical water content
+of the soil. In this way small quantities, generally a very few cubic
+centimeters at a time, have been obtained. The analysis of a few cubic
+centimeters of a very dilute solution is in itself difficult, involving
+necessarily more or less uncertainty as to the absolute value of the
+results. Nevertheless, the concentration of the soil solutions thus
+obtained, with respect to phosphoric acid and potash, varied but little
+for soils of various textures from sands to clays, and the variations
+observed could not be correlated with the known crop-producing power
+of the soils. The average concentrations of the soil solutions thus
+obtained lies in the neighborhood of 6-8 parts per million (p.p.m.) of
+solution for phosphoric acid (P₂O₅) and 25-30 parts per million for
+potash (K₂O).&#x2060;<a id="FNanchor_58_58" href="#Footnote_58_58" class="fnanchor">[58]</a>
+ In the following table are given the results obtained
+<span class="pagenum" id="Page_40">[Pg 40]</span>
+by analyzing solutions extracted from different samples of loams and
+sands by means of a centrifuge. The crop growing on these soils and the
+crop condition at the time the samples were collected are given in the
+table, and the percentages of water in the samples when placed in the
+centrifuge are also given.</p>
+
+<p class="f120"><b><span class="smcap">Analysis of Soil Solution Removed from<br>
+Fresh Soils by the Centrifuge.</span></b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Soil</th>
+ <th class="tdc bl bb" rowspan="2">Crop</th>
+ <th class="tdc bl bb" rowspan="2">&nbsp;Condition&nbsp;<br>of crop</th>
+ <th class="tdc bl bb" rowspan="2">Per cent<br>&nbsp;moisture.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million<br>of solution</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">PO₄</th>
+ <th class="tdc bl">Ca</th>
+ <th class="tdc bl">K</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">Leonardtown loam &nbsp;</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">22.0</td>
+ <td class="tdc bl">&#8199;6</td>
+ <td class="tdc bl">17</td>
+ <td class="tdc bl">22</td>
+ </tr><tr>
+ <td class="tdl">Leonardtown loam</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Poor</td>
+ <td class="tdc bl">25.2</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">&#8199;9</td>
+ <td class="tdc bl">19</td>
+ </tr><tr>
+ <td class="tdl">Leonardtown loam</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">17.6</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">22</td>
+ <td class="tdc bl">38</td>
+ </tr><tr>
+ <td class="tdl">Sassafras loam</td>
+ <td class="tdl_wsp bl">Clover &nbsp;</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">19.7</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">18</td>
+ <td class="tdc bl">19</td>
+ </tr><tr>
+ <td class="tdl">Sassafras loam</td>
+ <td class="tdl_wsp bl">Corn</td>
+ <td class="tdl_wsp bl">Medium</td>
+ <td class="tdc bl">17.5</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">13</td>
+ <td class="tdc bl">36</td>
+ </tr><tr>
+ <td class="tdl">Sassafras loam</td>
+ <td class="tdl_wsp bl">Corn</td>
+ <td class="tdl_wsp bl">Medium</td>
+ <td class="tdc bl">18.3</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">83</td>
+ <td class="tdc bl">25</td>
+ </tr><tr>
+ <td class="tdl">Sassafras loam</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">18.8</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">44</td>
+ <td class="tdc bl">34</td>
+ </tr><tr>
+ <td class="tdl">Sassafras loam</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Poor</td>
+ <td class="tdc bl">20.0</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">27</td>
+ <td class="tdc bl">24</td>
+ </tr><tr>
+ <td class="tdl">Sassafras loam</td>
+ <td class="tdl_wsp bl">Corn</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">17.3</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">24</td>
+ <td class="tdc bl">25</td>
+ </tr><tr>
+ <td class="tdl">Norfolk sand</td>
+ <td class="tdl_wsp bl">Forest</td>
+ <td class="tdl_wsp bl">Poor</td>
+ <td class="tdc bl">10.0</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">18</td>
+ <td class="tdc bl">31</td>
+ </tr><tr>
+ <td class="tdl">Norfolk sand</td>
+ <td class="tdl_wsp bl">Corn</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">11.9</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">36</td>
+ <td class="tdc bl">31</td>
+ </tr><tr>
+ <td class="tdl">Norfolk sand</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Good</td>
+ <td class="tdc bl">10.7</td>
+ <td class="tdc bl">18</td>
+ <td class="tdc bl">45</td>
+ <td class="tdc bl">31</td>
+ </tr><tr>
+ <td class="tdl">Norfolk sand</td>
+ <td class="tdl_wsp bl">Wheat</td>
+ <td class="tdl_wsp bl">Poor</td>
+ <td class="tdc bl">11.2</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">38</td>
+ <td class="tdc bl">24</td>
+ </tr><tr class="bb">
+ <td class="tdl">Norfolk sand</td>
+ <td class="tdl_wsp bl">Corn</td>
+ <td class="tdl_wsp bl">Medium</td>
+ <td class="tdc bl">10.6</td>
+ <td class="tdc bl">&#8199;9</td>
+ <td class="tdc bl">65</td>
+ <td class="tdc bl">35</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>The concentrations of the solutions obtained from the samples do not
+justify any correlation with the crop-producing power of the soils, nor
+with the texture of the soils. The wide variation in the concentrations
+with respect to calcium is probably due to the fact that all of the
+samples came from fields which had been limed, some quite recently,
+and that the content of carbon dioxide in the different samples
+varied. It is of special interest to note that the content of calcium
+in the solutions does not show any obvious relation to the content of
+phosphoric acid.&#x2060;<a id="FNanchor_59_59" href="#Footnote_59_59" class="fnanchor">[59]</a></p>
+
+<p>An effort has been made to ascertain the mineral concentration of soil
+<span class="pagenum" id="Page_41">[Pg 41]</span>
+solutions as they occur naturally in the field. Because of the
+practical impossibility of extracting the actual soil solution, an
+empirical method was employed. Areas were selected where good and
+poor crops were growing near each other on the same soil types, and
+preferably in the same field. Samples of soil from under these crops
+were taken at several intervals during the growing season, quickly
+removed to a nearby laboratory, shaken thoroughly with distilled water
+in the proportion of one part of soil to five parts of water, allowed
+to stand twenty minutes and the supernatant solution passed through a
+Pasteur-Chamberland filter.&#x2060;<a id="FNanchor_60_60" href="#Footnote_60_60" class="fnanchor">[60]</a></p>
+
+<p>As has been pointed out above, the aqueous extract of a soil thus
+arbitrarily prepared has no definite or causal relation to the
+soil solution in the field. It is certain that the solutions would
+not generally be the same. It should also be emphasized that such
+a procedure can not, as some investigators have assumed, afford a
+criterion between soluble and insoluble salts in the soil, else the
+proportion of water to soil used above some minimum would be immaterial
+as far as the amounts which go into solution are concerned. The
+proportion of water to soil is not immaterial, however, considering the
+chemical nature of the soil components and the results of experiment.
+Consequently, it is clear that the concentration of the soil solution
+is not simply the ratio of the amounts found in the aqueous extract, to
+the percentage of moisture in the soil, but something quite different.</p>
+
+<p>Artificial solutions prepared in the manner described above should,
+however, furnish evidence as to whether or not there are recognizable
+differences in the soluble mineral constituents of good and poor
+soils respectively; and if such differences exist, whether they are
+consistent. That is to say, if the more productive soils also uniformly
+yield aqueous extracts of a higher concentration, then it would be a
+fair inference that their natural soil solutions are maintained at a
+higher concentration than in the less productive soils.
+<span class="pagenum" id="Page_42">[Pg 42]</span></p>
+
+<p>Results obtained for several localities and several crops, taken from
+the original records, are given in the following tables.&#x2060;<a id="FNanchor_61_61" href="#Footnote_61_61" class="fnanchor">[61]</a></p>
+
+<p class="f120 spa1"><b><span class="smcap">Water Soluble Constituents of Soil.</span></b></p>
+<p class="center"><b>Locality, Salem, N. J.&emsp;Soil type, Norfolk sand.<br>
+Crop, wheat. Yield, good.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">March 10&nbsp;</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">13.2</td>
+ <td class="tdc bl">12&#8199;</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">12</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">11.5</td>
+ <td class="tdc bl">7</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">16</td>
+ </tr><tr>
+ <td class="tdl">June 8</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">4.3</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">13</td>
+ </tr><tr>
+ <td class="tdl">June 13</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">4.6</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">13</td>
+ <td class="tdc bl">17</td>
+ </tr><tr class="bb">
+ <td class="tdl">June 19</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">9.6</td>
+ <td class="tdc bl">2</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">24</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center spa2"><b>Locality, Salem, N. J.&emsp;Soil type, Norfolk sand.<br>
+Crop, wheat. Yield, poor.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">April 3</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">12.0</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">32</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">12.0</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">&#8199;3</td>
+ <td class="tdc bl">22</td>
+ </tr><tr class="bb">
+ <td class="tdl">June 16&nbsp;</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">9.3</td>
+ <td class="tdc bl">&#8199;4</td>
+ <td class="tdc bl">29</td>
+ <td class="tdc bl">20</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center spa2"><b>Locality, Salem, N. J.&emsp;Soil type, Norfolk sand.<br>
+Crop, wheat. Yield, medium.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">March 10</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">23.2</td>
+ <td class="tdc bl">19</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">&#8199;8</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">21.6</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">14</td>
+ </tr><tr>
+ <td class="tdl">March 14</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">22.3</td>
+ <td class="tdc bl">18</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">18</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">20.2</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">21</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">20.3</td>
+ <td class="tdc bl">18</td>
+ <td class="tdc bl">17</td>
+ <td class="tdc bl">16</td>
+ </tr><tr>
+ <td class="tdl">March 20&nbsp;</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">19.3</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">21</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">18.6</td>
+ <td class="tdc bl">&#8199;4</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">21</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">12.6</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">21</td>
+ </tr><tr class="bb">
+ <td class="tdl">June 16</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">22.5</td>
+ <td class="tdc bl">&#8199;4</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">23</td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_43">[Pg 43]</span></p>
+
+<p class="center spa2"><b>Locality, Salem, N. J.&emsp;Soil type, Sassafras loam.<br>
+Crop, grass. Yield, fair.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">March 10</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">25.0</td>
+ <td class="tdc bl">13</td>
+ <td class="tdc bl">28</td>
+ <td class="tdc bl">18</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">23.8</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">26</td>
+ <td class="tdc bl">13</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">19.9</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">15</td>
+ </tr><tr>
+ <td class="tdl">March 14</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">25.8</td>
+ <td class="tdc bl">21</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">21</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">23.1</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">15</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">21.8</td>
+ <td class="tdc bl">&#8199;9</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">21</td>
+ </tr><tr>
+ <td class="tdl">March 31&nbsp;</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">23.0</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">23</td>
+ <td class="tdc bl">43</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">21.6</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">20</td>
+ <td class="tdc bl">34</td>
+ </tr><tr>
+ <td class="tdl">April 2</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">24.8</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">41</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">24.0</td>
+ <td class="tdc bl">&#8199;6</td>
+ <td class="tdc bl">21</td>
+ <td class="tdc bl">38</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">21.4</td>
+ <td class="tdc bl">&#8199;3</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">25</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center spa2"><b>Locality, Salem, N. J.&emsp;Soil type, Sassafras loam.<br>
+Crop, wheat. Yield, good.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">March 17</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">22.0</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">&#8199;6</td>
+ <td class="tdc bl">10</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">18.1</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">14</td>
+ </tr><tr>
+ <td class="tdl">March 17</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">18.3</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">Lost</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">18.1</td>
+ <td class="tdc bl">&#8199;9</td>
+ <td class="tdc bl">24</td>
+ <td class="tdc bl">25</td>
+ </tr><tr>
+ <td class="tdl">March 24</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">24.7</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">30</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">22.3</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">38</td>
+ </tr><tr>
+ <td class="tdl">March 26&nbsp;</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">23.4</td>
+ <td class="tdc bl">&#8199;4</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">16</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">23.9</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">20</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">22.4</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">&#8199;3</td>
+ <td class="tdc bl">21</td>
+ </tr><tr>
+ <td class="tdl">April 2</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">25.6</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">30</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">24.4</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">17</td>
+ <td class="tdc bl">47</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">21.6</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">38</td>
+ </tr><tr>
+ <td class="tdl">June 5</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">&#8199;5.2</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">51</td>
+ <td class="tdc bl">23</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">&#8199;8.0</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">55</td>
+ <td class="tdc bl">32</td>
+ </tr><tr>
+ <td class="tdl">June 8</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">10.6</td>
+ <td class="tdc bl">&#8199;2</td>
+ <td class="tdc bl">20</td>
+ <td class="tdc bl">13</td>
+ </tr><tr>
+ <td class="tdl">June 11</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">15.5</td>
+ <td class="tdc bl">&#8199;6</td>
+ <td class="tdc bl">26</td>
+ <td class="tdc bl">14</td>
+ </tr><tr>
+ <td class="tdl">June 13</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">&#8199;8.2</td>
+ <td class="tdc bl">&#8199;6</td>
+ <td class="tdc bl">19</td>
+ <td class="tdc bl">22</td>
+ </tr><tr>
+ <td class="tdl">June 16</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">15.0</td>
+ <td class="tdc bl">&#8199;5</td>
+ <td class="tdc bl">21</td>
+ <td class="tdc bl">19</td>
+ </tr><tr class="bb">
+ <td class="tdl">June 17</td>
+ <td class="tdr_wsp bl">1-24</td>
+ <td class="tdr_ws1 bl">10.6</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">63</td>
+ <td class="tdc bl">17</td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_44">[Pg 44]</span></p>
+
+<p class="center spa2"><b>Locality, Salem, N. J.&emsp;Soil type, Sassafras loam.<br>
+Crop, clover. Yield, fair.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">March 20</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">20.8</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">32</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">20.2</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">27</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">18.6</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">36</td>
+ </tr><tr>
+ <td class="tdl">March 26&nbsp;</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">26.8</td>
+ <td class="tdc bl">9</td>
+ <td class="tdc bl">31</td>
+ <td class="tdc bl">20</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">22.9</td>
+ <td class="tdc bl">8</td>
+ <td class="tdc bl">20</td>
+ <td class="tdc bl">18</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">24-36</td>
+ <td class="tdr_ws1 bl">22.5</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">20</td>
+ </tr><tr>
+ <td class="tdl">June 6</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">8.1</td>
+ <td class="tdc bl">8</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">17</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">12.7</td>
+ <td class="tdc bl">9</td>
+ <td class="tdc bl">18</td>
+ <td class="tdc bl">20</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center spa2"><b>Locality, St. Marys, Md.&emsp;Soil type, Leonardtown loam.<br>
+Crop, wheat. Yield, good.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">April 27</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">21.8</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">10</td>
+ <td class="tdc bl">12</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">21.3</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">10</td>
+ </tr><tr>
+ <td class="tdl">April 29</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">22.2</td>
+ <td class="tdc bl">8</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">52</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">21.8</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">38</td>
+ </tr><tr>
+ <td class="tdl">May 1</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">22.4</td>
+ <td class="tdc bl">7</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">23</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">21.8</td>
+ <td class="tdc bl">7</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">30</td>
+ </tr><tr>
+ <td class="tdl">May 1</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">17.0</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">16</td>
+ <td class="tdc bl">25</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">21.0</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">19</td>
+ </tr><tr>
+ <td class="tdl">May 9</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">15.0</td>
+ <td class="tdc bl">13&#8199;</td>
+ <td class="tdc bl">34</td>
+ <td class="tdc bl">28</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">15.9</td>
+ <td class="tdc bl">9</td>
+ <td class="tdc bl">17</td>
+ <td class="tdc bl">26</td>
+ </tr><tr>
+ <td class="tdl">May 15</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">14.2</td>
+ <td class="tdc bl">3</td>
+ <td class="tdc bl">14</td>
+ <td class="tdc bl">24</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">19.9</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">13</td>
+ <td class="tdc bl">25</td>
+ </tr><tr>
+ <td class="tdl">August 14</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">15.0</td>
+ <td class="tdc bl">6</td>
+ <td class="tdc bl">11</td>
+ <td class="tdc bl">13</td>
+ </tr><tr>
+ <td class="tdl">August 15&nbsp;</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">15.7</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">&#8199;3</td>
+ <td class="tdc bl">17</td>
+ </tr><tr class="bb">
+ <td class="tdl">August 15</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">16.4</td>
+ <td class="tdc bl">8</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">15</td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_45">[Pg 45]</span></p>
+
+<p class="center spa2"><b>Locality, St. Marys, Md.&emsp;Soil type, Leonardtown loam.<br>
+Crop, wheat. Yield, poor.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">May 14</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">14.7</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">8</td>
+ <td class="tdc bl">35</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">19.9</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">30</td>
+ </tr><tr>
+ <td class="tdl">May 23</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">&#8199;7.8</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">7</td>
+ <td class="tdc bl">22</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">14.9</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">11&#8199;</td>
+ <td class="tdc bl">23</td>
+ </tr><tr>
+ <td class="tdl">August 14</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">16.0</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">16</td>
+ </tr><tr class="bb">
+ <td class="tdl">August 15&nbsp;</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">19.5</td>
+ <td class="tdc bl">6</td>
+ <td class="tdc bl">4</td>
+ <td class="tdc bl">13</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center spa2"><b>Locality, St. Marys, Md.&emsp;Soil type, Leonardtown loam.<br>
+Crop, corn. Yield, good.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">May 8</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">18.2</td>
+ <td class="tdc bl">9</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">29</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">18.9</td>
+ <td class="tdc bl">10&#8199;</td>
+ <td class="tdc bl">&#8199;7</td>
+ <td class="tdc bl">26</td>
+ </tr><tr>
+ <td class="tdl">May 18</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">18.2</td>
+ <td class="tdc bl">3</td>
+ <td class="tdc bl">24</td>
+ <td class="tdc bl">38</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">18.8</td>
+ <td class="tdc bl">6</td>
+ <td class="tdc bl">19</td>
+ <td class="tdc bl">28</td>
+ </tr><tr class="bb">
+ <td class="tdl">August 8&nbsp;</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">17.5</td>
+ <td class="tdc bl">7</td>
+ <td class="tdc bl">30</td>
+ <td class="tdc bl">18</td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="center spa2"><b>Locality, St. Marys, Md.&emsp;Soil type, Leonardtown loam.<br>
+Crop, corn. Yield, poor.</b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2">
+ <th class="tdc bb" rowspan="2">Date</th>
+ <th class="tdc bl bb" rowspan="2">Depth<br>&nbsp;inches&nbsp;</th>
+ <th class="tdc bl bb" rowspan="2">Moisture<br>content<br>&nbsp;Per cent.&nbsp;</th>
+ <th class="tdc bl bb" colspan="3">&nbsp;Parts per million of oven-dried soil</th>
+ </tr><tr class="bb">
+ <th class="tdc bl">Phosphoric<br>acid (PO₄)</th>
+ <th class="tdc bl">Calcium<br>(Ca)</th>
+ <th class="tdc bl">Potassium<br>(K)</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">May 23</td>
+ <td class="tdr_wsp bl">0-12</td>
+ <td class="tdr_ws1 bl">16.6</td>
+ <td class="tdc bl">5</td>
+ <td class="tdc bl">12</td>
+ <td class="tdc bl">22</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdr_wsp bl">12-24</td>
+ <td class="tdr_ws1 bl">17.4</td>
+ <td class="tdc bl">6</td>
+ <td class="tdc bl">&#8199;8</td>
+ <td class="tdc bl">22</td>
+ </tr><tr>
+ <td class="tdl">August 8</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">19.9</td>
+ <td class="tdc bl">9</td>
+ <td class="tdc bl">25</td>
+ <td class="tdc bl">20</td>
+ </tr><tr class="bb">
+ <td class="tdl">August 15&nbsp;</td>
+ <td class="tdr_wsp bl">0-24</td>
+ <td class="tdr_ws1 bl">21.6</td>
+ <td class="tdc bl">7</td>
+ <td class="tdc bl">15</td>
+ <td class="tdc bl">13</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>It will be observed that the results given in the above tables are
+expressed in parts per million of oven-dried soils, in order to have
+some definite basis of comparison, and because it was anticipated at
+<span class="pagenum" id="Page_46">[Pg 46]</span>
+the time the investigation was made that larger quantities of dissolved
+minerals would be found under the better crops, and <i>vice versa</i>.
+An inspection of the results, however, shows that no such correlation
+can be made, nor in fact can any consistent correlation be made between
+the dissolved material and crop, soil type, water content, depth of
+soil or part of the growing season.&#x2060;<a id="FNanchor_62_62" href="#Footnote_62_62" class="fnanchor">[62]</a>
+It appears, therefore, that in so far as the field method of analyzing
+an arbitrarily prepared aqueous extract is competent, there is no
+evidence that there are important characteristic differences in the
+concentration of the mineral constituents in different soil solutions
+in the field.</p>
+
+<p>The order of concentration of the soil solution can be approximated
+from the given data, if the assumption be made that in the preparation
+of the aqueous extract, soluble mineral constituents are of minor
+importance, other than the constituents already dissolved in the soil
+solution. The calculation is very laborious, is not exact, and on
+account of the assumptions made the actual figures obtained are of no
+especial value in any particular case. Remembering the method of making
+up the solutions from which these results were obtained, it would be
+sufficiently near the truth to assume an average moisture content of 20
+per cent., when the figures given here for the soil approximate those
+which would be obtained for the soil solution. More exact calculations
+have been made for a large number of such cases, and it has been
+found from this method of estimation that the average composition
+with respect to phosphoric acid would be about 6-8 parts per million,
+and for potash about 25 parts per million, figures which agree with
+the results obtained for the examination of solutions extracted from
+saturated soils by means of the centrifuge.
+<span class="pagenum" id="Page_47">[Pg 47]</span></p>
+
+<p>The results given in the foregoing tables were obtained under
+great difficulties, and in some part the variations they show are
+undoubtedly due to inevitable inaccuracies of analytical work done
+under such circumstances. Some of the variations may also be due to
+the disturbing influences in the soil referred to above. Experience
+has shown, however, that the preparation of an aqueous extract of the
+soil of any particular field is by no means a simple matter. Extracts
+made from samples taken within a few feet of one another frequently
+show variations of the same order as with samples from entirely
+different fields, or even soil types. Differences in the preliminary
+drying out of the sample before the addition of the water, seems to
+result in the same order of differences as obtained between different
+soils. In consequence of these facts, and of the further fact that an
+arbitrary aqueous extract of a soil cannot be assumed to represent in
+any definite way the natural soil solution, the results of the field
+examination are inconclusive as to the concentration of the soil
+solution <i>in situ</i>. It is more necessary, therefore, that other
+lines of evidence should be sought as to the mineral characteristics
+and concentration of the soil solution. Such a line of evidence is
+found in certain percolation experiments.&#x2060;<a id="FNanchor_63_63" href="#Footnote_63_63" class="fnanchor">[63]</a></p>
+
+<p>If a solution of a soluble phosphate be percolated through a soil, a
+part of the phosphate will be removed from the solution and absorbed
+by the soil; that is, there will be a redistribution of the phosphate
+between the soil and the water. As the process continues, however,
+relatively less and less phosphate is absorbed by the soil and the
+concentration of the percolate becomes more and more nearly that of
+the added solution. This absorption takes place more or less closely
+in accordance with the simple law that the absorption of phosphates by
+the soil, per unit of solution which is percolating, is proportional
+to the total amount of phosphate which the soil may yet take from that
+solution if percolated indefinitely. This law is expressed by the equation</p>
+
+<table class="spb1 fs_120">
+ <tbody><tr>
+ <td class="tdl bb">&nbsp;<i>dy</i>&nbsp;</td>
+ <td class="tdl_wsp" rowspan="2">= <i>K</i>(<i>A</i> - <i>y</i>)</td>
+ </tr><tr>
+ <td class="tdl"><i>dx</i></td>
+ </tr>
+ </tbody>
+</table>
+
+
+<p class="no-indent"><span class="pagenum" id="Page_48">[Pg 48]</span>
+where <b><i>y</i></b> is the amount absorbed, <b><i>x</i></b> amount of solution
+that has passed, and <b><i>A</i></b> is the total amount which can ultimately
+be absorbed by that particular soil from that particular solution.
+<b><i>K</i></b> is also a characteristic constant. If the percolation be
+maintained at constant rate, then <b><i>t</i></b>, time, can be substituted
+for <b><i>x</i></b> and the equation becomes</p>
+
+<table class="spb1 fs_120">
+ <tbody><tr>
+ <td class="tdl bb">&nbsp;<i>dy</i>&nbsp;</td>
+ <td class="tdl_wsp" rowspan="2">= <i>K</i>(<i>A</i> - <i>y</i>)</td>
+ </tr><tr>
+ <td class="tdl"><i>dt</i></td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="no-indent">the ordinary rate equation for a mono-molecular
+reaction of the first order, whether chemical or physical.</p>
+
+<p>With such absorptions as are involved in soils, a clay exposes a
+greater amount of absorbing surface than does a loam or sand, and it
+will show the greatest absorption towards any particular solution,
+other things being equal. The curve showing the concentration of
+percolate would lie lower for a clay than for a loam, or for a sand.
+This is illustrated in the accompanying sketch diagram, where <i>y</i>
+represents concentration of percolate and <i>t</i> represents time.</p>
+
+<div class="figcenter">
+ <img src="images/fig_1.jpg" alt="" width="600" height="234" >
+ <p class="f120 spb1"><b><span class="smcap">Fig. 1.</span></b></p>
+</div>
+
+<p>If after percolation has proceeded for some time (in some experiments
+for several weeks and until the soil contained 1 or 2 per cent. of
+phosphoric acid) pure water be passed through the soil, then, as soon
+as the previously used phosphate solution has been displaced, the
+concentration of the percolate drops and continues practically constant
+for an indefinite period. Moreover, no matter what the soil may be
+as to texture or composition, the same concentration of percolate is
+obtained, namely, 6-8 parts per million, the concentration which the
+soils yielded prior to treatment with the phosphate solution. Similar
+experiments when the soils were treated with salts of potassium have
+given like results, although the curves obtained from passing pure
+water through the soils do not lie quite so close together; but the
+<span class="pagenum" id="Page_49">[Pg 49]</span>
+concentration of the percolate with respect to potassium generally lies
+somewhere between 25 and 30 parts per million.</p>
+
+<p>The removal of a soluble constituent from the soil by percolating water
+appears to be described by a rate equation similar to that given above
+for absorption. If the rate of percolation be maintained constant this
+formula is</p>
+
+<table class="spb1 fs_120">
+ <tbody><tr>
+ <td class="tdl bb">&nbsp;<i>dx</i>&nbsp;</td>
+ <td class="tdl_wsp" rowspan="2">= <i>K</i>(<i>B</i> - <i>x</i>)</td>
+ </tr><tr>
+ <td class="tdl"><i>dt</i></td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="no-indent">where <b><i>x</i></b> is the amount removed by
+the percolation, with time <b><i>t</i></b>, <b><i>K</i></b> is a
+constant characteristic for the particular system under consideration,
+and <b><i>B</i></b> is the total amount of the constituent which may
+ultimately be leached out. In other words, the rate in any particular
+soil will depend upon the amount of the constituent still absorbed in
+that soil but has no necessary connection with the rate which would
+hold for the same amount of the constituent in any other soil.</p>
+
+<p>Theoretically, two consequences follow from this law which require
+consideration here. The rate at which a constituent is removed
+gradually becomes less as percolation proceeds. If the soil contains
+an amount of the constituent approaching the total amount which it
+can absorb, as for instance is probably the case sometimes when large
+applications of lime have been made to the soil, the concentration
+of the percolating solution might be expected to change noticeably.
+Generally, however, a soil contains nowhere near as much phosphoric
+acid or potassium as it is capable of absorbing, so that the
+concentration of the percolating water changes but very little with
+respect to these constituents. It follows from the equation that
+if percolation continues uninterrupted, the concentration of the
+percolate, so far as it is determined by an absorbed constituent, must
+get less and less until it becomes a vanishing quantity. This state
+of affairs does not exist in the soil, however, for percolation by
+pure water does not continue uninterrupted for any length of time. The
+rise of the capillary water in the soil will, under normal conditions,
+enable the soil to reabsorb more of the ordinary mineral constituents
+<span class="pagenum" id="Page_50">[Pg 50]</span>
+than is removed by percolating waters. Further attention will be given
+the matter in another chapter.</p>
+
+<div class="figcenter">
+ <img src="images/fig_2.jpg" alt="" width="600" height="387" >
+ <p class="f120 spb1"><b><span class="smcap">Fig. 2.</span></b></p>
+</div>
+
+<p>Another but quite different line of evidence as to the probable
+concentration of the soil solution is furnished by the investigation of
+the solubility of certain phosphates.&#x2060;<a id="FNanchor_64_64" href="#Footnote_64_64" class="fnanchor">[64]</a>
+It is popularly supposed that when superphosphate containing
+mono-calcium phosphate, CaH₄(PO₄)₂.H₂O, is added to a soil there is
+a more or less permanent increase of readily soluble phosphoric acid
+in the soil, although a part “inverts” to the somewhat less soluble
+dicalcium phosphate, Ca₂H₂(PO₄)₂·2H₂O. Such probably is far from a
+correct view of what actually takes place. The results obtained by
+studying the solubility of the different lime phosphates in water at
+ordinary temperature (25° C.) can be expressed in a diagram similar
+to the accompanying sketch, which is much distorted for convenience
+in lettering. As the diagram indicates, when the concentration of the
+solution increases with respect to phosphoric acid, the lime is at
+first less and less soluble until the point represented by <i>B</i> is
+reached, then becomes more and more soluble until the point <i>D</i>
+is reached, from then on becoming less and less soluble, until the
+solution reaches a syrupy consistency. In contact with all solutions
+<span class="pagenum" id="Page_51">[Pg 51]</span>
+represented by points on the line <i>DE</i> the stable solid substance
+which can exist is mono-calcium phosphate, CaH₄(PO₄)₂.H₂O. Along
+the line <i>CD</i> the only solid which is stable and can continue
+to persist is the dicalcium phosphate. From the point <i>C</i>
+the composition of the stable solid varies continuously with the
+concentration of the liquid solution. Therefore, these solids form
+a series varying in composition from pure dicalcium phosphate to
+pure calcium hydroxide. One of these basic phosphates, as they would
+ordinarily be called, has a less solubility than any other, as
+indicated by the point <i>B</i>. All solutions to the right of the
+point <i>B</i> have an acid reaction, while all solutions to the left
+possess an alkaline reaction. It follows from these facts that if
+we start with any lime phosphate corresponding to some point to the
+right of <i>B</i> and dilute it, or what amounts to the same thing
+in case it has been added to the soil, if we leach it, phosphoric
+acid will go into solution more rapidly than will lime until the
+composition of the residue is that of the basic phosphate stable at
+<i>B</i>. Similarly, if we start with a phosphate more basic, lime
+will be removed more rapidly than phosphoric acid, until the residue
+has the composition of the phosphate of lowest solubility. From this
+point, with continued leaching, the lime and phosphoric acid will
+dissolve in a definite ratio, which ratio is obviously that of the
+phosphate of least solubility. That is to say, if the leaching process
+is slow, as would be the case under soil conditions, the solution
+would have a perfectly definite concentration with respect to lime
+and phosphoric acid. What the ratio of lime to phosphoric acid may
+be, is of no particular interest in this connection, but the order
+of concentration of phosphoric acid is of interest. Owing to serious
+analytical difficulties, this has not yet been determined with any
+great precision, but by interpolating on the experimentally determined
+curve <i>AC</i>, this concentration is found to be somewhere in the
+neighborhood of 5-10 parts per million, figures close to those obtained
+for the concentration of the soil solution with respect to phosphoric
+acid by the previously described investigations.</p>
+
+<p>Under ordinary circumstances, however, it is not probable that lime is
+<span class="pagenum" id="Page_52">[Pg 52]</span>
+the dominant base controlling the concentration of phosphoric acid
+in the soil solution, since the great majority of agricultural soils
+contain vastly more ferric oxide (more or less hydrated) than is
+equivalent to any amount of phosphoric acid that will ever be brought
+into the soil; and ferric phosphates are less soluble relatively than
+lime phosphates. Investigation of the relation of ferric oxide to
+solutions of phosphoric acid shows that the system is quite similar in
+many respects to the basic lime phosphates and water just described.
+When the ratio of iron to phosphoric acid in the solid is greater
+than that required by the formula of the normal phosphate, FePO₄, the
+aqueous solution will have an acid reaction and contain a mere trace
+of iron and an amount of phosphoric acid determinedly the composition
+of the solid and by the proportion of solid to water. The basic ferric
+phosphates seem to be solid solutions which yield a very dilute aqueous
+solution when brought into contact with water. What the concentration
+will be under soil conditions is shown by the percolation experiments
+cited above.</p>
+
+<p>The addition of other substances will in many cases affect more
+or less the solubility of the soil minerals. If these substances
+be electrolytes, they will generally, but not always, affect the
+solubility of the minerals as would be anticipated from the hypothesis
+of electrolytic dissociation. Thus, the addition of potassium sulphate
+lessens the solubility and hydrolysis of a potash feldspar or a
+potash mica. Contrary, however, to the indications of the hypothesis,
+sodium nitrate decreases the solubility of a ferric phosphate. While
+appreciable solubility effects take place with sufficiently high
+concentrations, laboratory experiments indicate that the addition of
+such substances, even in a liberal application of fertilizers, is not
+sufficient to produce any great effect on the concentration of the
+soil solution. Similarly, it has often been supposed that the ammonia,
+and nitrous and nitric oxides of the atmosphere carried into the
+soil by rain, or formed in the soil by bacterial action, affect the
+solubility of the soil minerals, but it is highly improbable that the
+concentration with respect to these agents ever becomes sufficiently
+high, as laboratory investigations show to be necessary to affect
+appreciably the solubility of the ordinary rock- or soil-forming minerals.
+<span class="pagenum" id="Page_53">[Pg 53]</span></p>
+
+<p>Rain brings from the atmosphere into the soil two agents, however,
+which do markedly affect the solubility of the soil minerals, namely,
+oxygen and carbon dioxide. The atmosphere within the soil contains
+normally a somewhat smaller proportion of oxygen than does the air
+above the soil. Rain in falling through the air absorbs or dissolves
+relatively more oxygen than nitrogen. Therefore when the rain water
+has penetrated the soil to any considerable depth there should be,
+and probably is, a liberation of dissolved oxygen into the atmosphere
+of the soil interstices. This dissolved oxygen in becoming liberated
+or when dissolved in the film water appears to be especially active
+towards the ferrous or ferro-magnesian silicates. These minerals are,
+moreover, as a class probably the most soluble of the rock-forming
+silicates. Consequently oxygen brought into the soil in this manner is
+one of the most important agencies in breaking down and decomposing
+such minerals as the amphiboles, pyroxenes, chlorites, certain
+serpentines, phlogopites and biotites; at the same time there is
+formed ferric oxide (more or less hydrated) and silica (probably as
+quartz) and magnesium, potassium, calcium or sodium pass into solution,
+probably as bicarbonates. That the concentration of the soil moisture
+may thus be made temporarily abnormal is not impossible, though
+scarcely probable.</p>
+
+<p>The soil atmosphere has normally a decidedly higher content of carbon
+dioxide than the atmosphere above the soil. Consequently the soil water
+is always more or less “charged” with carbon dioxide, and the presence
+of the carbon dioxide decidedly augments the solvent powers of the
+water towards a great many and different kinds of rock-forming or soil
+minerals.&#x2060;<a id="FNanchor_65_65" href="#Footnote_65_65" class="fnanchor">[65]</a></p>
+
+<p><span class="pagenum" id="Page_54">[Pg 54]</span>
+What the mechanism of the reaction may be is far from clear. The
+obvious explanation, at least in the case of the ordinary silicates of
+the alkalis or alkaline earths, is that by forming bicarbonates of the
+hydrolyzed bases, the active mass of the reaction product with water
+is decreased and hydrolysis thereby increased. But this explanation is
+apparently insufficient to account for the effects sometimes observed.
+It has been shown that the passage of carbon dioxide through solutions
+of the silicates, will produce more or less slowly a precipitation of
+silica, and there seems little reason to doubt that it does induce to
+some degree a decomposition and consequent greater solubility of the
+silicates of the alkalis and alkaline earths. It also increases to an
+appreciable extent the solubility of the phosphates of iron, alumina,
+and lime. Therefore, the variation in the content of carbon dioxide in
+different soils, and its continual variation from time to time in any
+one soil, must be expected to produce corresponding changes in the soil
+solution with respect to such bases as potassium and lime, and also
+with respect to phosphoric acid. This has been verified experimentally
+with aqueous extracts of soils, the solutions being charged with carbon
+dioxide while in contact with the soils.&#x2060;<a id="FNanchor_66_66" href="#Footnote_66_66" class="fnanchor">[66]</a>
+It is not conceivable, however, that any great difference can exist in
+the partial pressures of carbon dioxide in different soils which are in
+a condition to support crops, and therefore great absolute differences
+in the mineral content of the soil solution are not to be anticipated,
+nor are they actually observed.</p>
+
+<p>It has long been held that the organic substances in the soil have an
+important solvent effect on the minerals. This assumption seems quite
+unwarranted in the light of our present knowledge, although it is
+not to be denied that occasionally there may be present in the soil
+some soluble organic substance which influences the mineral content.
+Generally it has been assumed that the effective organic substances
+influencing the solubility of the minerals are organic acids, of which
+a number have found their way into past and even current literature,
+<span class="pagenum" id="Page_55">[Pg 55]</span>
+and which have been designated as humic, ulmic, crenic, apocrenic,
+azohumic acids, etc. Their existence has been predicated upon two
+facts: First, humus is soluble in alkaline solutions but is more or
+less completely reprecipitated on the addition of an excess of a
+strong mineral acid, a phenomenon also characteristic of many organic
+acids. But many other organic substances than acids are also soluble
+in the presence of alkalis and insoluble in the presence of an excess
+of strong mineral acids. Second, organic-copper complexes have been
+obtained from humus constituents, and supposed to be copper salts of
+various humus acids. The descriptions of these complexes so far given
+do not show that they met the usual criteria for definite compounds,
+but indicate on the contrary that they were the results of absorption
+or possibly adsorption phenomena. Consequently the existence of
+“humic” acids is purely hypothetical and without experimental or other
+scientific verification, and calls for no further consideration here.</p>
+
+<p>It is a widespread and popular notion that substances with a slight
+solubility also dissolve slowly, and that consequently the solubility
+of the minerals in the soil water must necessarily be a very slow
+process. This is, however, a misapprehension. It has been shown with a
+number of the common rock-forming minerals, that if they be powdered
+and then stirred into a relatively small volume of water, they dissolve
+very rapidly at first, and in a very short time, generally a few
+minutes, the solution is nearly saturated with respect to the mineral.
+Complete saturation, however, may require many days. The general shape
+of curve expressing the rate of solubility is shown in the accompanying
+figure.&#x2060;<a id="FNanchor_67_67" href="#Footnote_67_67" class="fnanchor">[67]</a>
+For soils, this fact has been verified repeatedly, in the
+following way: A cell fitted with parallel electrodes is placed in
+circuit with a slide-wire&#x2060;<a id="FNanchor_68_68" href="#Footnote_68_68" class="fnanchor">[68]</a>
+or Wheatstone bridge in such a manner that the resistance of the cell
+contents can be quickly determined. Distilled water is then placed in
+<span class="pagenum" id="Page_56">[Pg 56]</span>
+the cell and its resistance found. Generally this will be upwards of
+100,000 ohms. The soil or rock powder under examination is then added
+to the cell, being rapidly stirred into the water contained therein.
+The resistance drops to about 5,000 ohms within a short space of time,
+usually three or four minutes. A further slight drop in the resistance
+generally takes place, but it requires days, and sometimes even months
+to become more than barely appreciable. In this manner it has been
+shown that the soil and many of the common soil minerals dissolve
+quite rapidly if they are sufficiently fine to offer a large surface
+to the action of the water. It would seem to follow, therefore, that
+in the case of the soil solution the concentration with respect to
+these constituents derived from the soil minerals, will be rapidly
+restored whenever disturbed through absorption by plants, leaching,
+or otherwise.</p>
+
+<div class="figcenter">
+ <img src="images/fig_3.jpg" alt="" width="600" height="335" >
+ <p class="f120 spb1"><b><span class="smcap">Fig. 3.</span></b></p>
+</div>
+
+<p>That the minerals of the soil, or a powdered mineral or rock-powder,
+will dissolve continually as the concentration of the solution in
+contact with it is disturbed by abstraction of a dissolved mineral
+substance, has been shown by numerous experimenters. An apparently
+obvious way to test this point would be to treat the soil sample with
+successive portions of water, and to analyze the successive portions
+for the dissolved mineral substances. This method, however, involves
+serious experimental difficulties, owing to the smaller sized mineral
+particles being suspended in the mother liquor, thus precluding
+satisfactory decantation and clogging filters. Moreover, such a process
+in no case simulates field conditions. To meet these difficulties, the
+<span class="pagenum" id="Page_57">[Pg 57]</span>
+soil or mineral powder has been placed between two porous media, as in
+the space between two concentric cylinders of unglazed porcelain, the
+space being closed by a rubber stopper. To the interior cylinder is
+fitted a stopper carrying a tube of insoluble metal, such as platinum
+or tin. This tube is bent into a goose-neck form, and just below
+the stopper the tube is perforated with a small opening. The whole
+apparatus is filled with water and set in a beaker, also filled with
+water. The metal tube is made the cathode in an electric circuit, a
+platinum or other suitable anode being introduced into the beaker.
+In a few minutes the dissolved and hydrolyzed bases pass into the
+cathode chamber, and as the water also accumulates in the chamber by
+electrolytic endosmosis, a solution of the bases dissolved from the
+soil minerals drops from the end of the metal goose-neck. By adding
+water to the outer beaker from time to time, a steady stream of
+alkaline solution has been obtained for months, and in no case yet
+has a soil thus treated failed to continue to yield up the bases it
+contains in its mineral particles. The acids, such as phosphoric acid
+for example, are of course found in the water outside the porous cells,
+and in the case of the phosphoric acid it also appears to continue
+indefinitely to be withdrawn from the soil.&#x2060;<a id="FNanchor_69_69" href="#Footnote_69_69" class="fnanchor">[69]</a>
+It thus appears that as the products of solution and hydrolysis are
+removed, by such an endosmotic device as that just described or by the
+roots of growing plants, by leaching or otherwise, the soil minerals
+will continue to dissolve.</p>
+
+<p>The foregoing arguments as to the concentration of the soil solution
+with respect to those constituents derived from the soil minerals, are
+based on the generally recognized principle that a material system left
+to itself tends towards a condition of stable equilibrium or final
+rest, that is, a condition where such changes as are taking place are
+so balanced that no change occurs in the system as a whole. But the
+soil is a system continually subject to outside forces and influences,
+and as pointed out above, is of necessity a dynamic system. It is
+doubtful in the extreme if any soil in place is ever in a state of
+final stable equilibrium. It would be natural, therefore, to expect and
+<span class="pagenum" id="Page_58">[Pg 58]</span>
+to find that even if the solution in the soil were dependent on the
+solubility of the soil minerals alone and were continually tending
+towards a definite normal concentration, actually this concentration
+would seldom if ever be realized. Most important in this connection
+is the fact that the concentration of the soil solution is always
+dependent in some degree upon the concentration of the soluble
+constituents in the solid phases in other than definite chemical
+combinations. Other factors affecting the concentration of the
+mineral constituents in the soil solution are always existent,
+and theoretically at least, can not be ignored. Nevertheless <i>a
+priori</i> reasoning as well as the experimental evidence at hand
+indicates that the various processes taking place in the soil as a
+whole continually tend to form and maintain a normal concentration of
+mineral constituents in the soil solution.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_59">[Pg 59]</span></p>
+<h2 class="nobreak">Chapter VIII.<br>
+<span class="h_subtitle">ABSORPTION BY SOILS.</span></h2>
+</div>
+
+<p>A property of soils, affecting profoundly the composition and
+concentration of the soil solution, is absorption.&#x2060;<a id="FNanchor_70_70" href="#Footnote_70_70" class="fnanchor">[70]</a>
+It is generally recognized that soils are good absorbers for vapors,
+and this fact finds practical expression in the common practice of
+burying things with a disagreeable odor, such as animal carcasses,
+night-soil, etc. It is also well-known that dissolved as well as
+suspended material can be more or less completely removed from water
+by passing it through sand or soil, and this fact finds important
+application in water supplies for cities and towns, sewage disposal,
+etc. It was known as long ago as Aristotle’s time that ordinary salt
+is partly removed from water by passing through sand or soil. In
+recent times the practical as well as theoretical importance of this
+phenomenon has led to considerable study and experimental research,
+so that our knowledge of absorption effects is now fairly extensive,
+though it can hardly be claimed that it is satisfactory. The absorption
+of a dissolved substance from solution by a soil may be one or more of
+at least three kinds of phenomena. It may be a mechanical inclusion
+or trapping, distinguished by the term <i>imbibition</i>, the most
+familiar and striking case being the absorption of water itself by
+soil or sponge or similar medium. It may be a partial taking up of the
+dissolved substance to form a new compound or a <i>solid solution</i>,&#x2060;<a id="FNanchor_71_71" href="#Footnote_71_71" class="fnanchor">[71]</a>
+<span class="pagenum" id="Page_60">[Pg 60]</span>
+as probably is the absorption of phosphoric acid by lime or ferric
+oxide. Or it may be a condensation or concentration of the dissolved
+substance on or about the surface of the absorbing medium, a phenomenon
+known as <i>adsorption</i>. To prove the existence of adsorption
+definitely and conclusively in any given case is always difficult, if
+ever possible, but the existence of this phenomenon is the most logical
+explanation of many observations, and is generally admitted by chemists
+and physicists at the present time.&#x2060;<a id="FNanchor_72_72" href="#Footnote_72_72" class="fnanchor">[72]</a>
+It is by adsorption, probably, that potash and ammonia are held by the
+soil when added in fertilizers.</p>
+
+<p>That absorption is dependent in some manner upon the solubility of the
+dissolved substance in the particular solvent employed would seem to
+be obvious. But what the relation may be, if it exists at all, is not
+known. For instance, silk absorbs picric acid from solutions in water
+and alcohol but not from solutions in benzene, although the solubility
+of picric acid in benzene lies between its solubility in water and in
+alcohol.&#x2060;<a id="FNanchor_73_73" href="#Footnote_73_73" class="fnanchor">[73]</a></p>
+
+<p>The absorption of any given dissolved substance from different solvents
+is markedly different. Most soils absorb methylene blue from aqueous
+solutions with great avidity, but washing out the absorbed dye with
+water is an extremely tedious and unsatisfactory process, although the
+dye can be readily and more or less completely removed from the soil
+by alcohol. As might be anticipated from this, it is known that the
+presence of one dissolved substance affects the absorption of another,
+but in what way can not, generally, be anticipated, although it would
+seem that the importance of this subject for manurial practice would
+invite further research.
+<span class="pagenum" id="Page_61">[Pg 61]</span></p>
+
+<p>From the same solution, different absorbents remove a dissolved
+substance in different degrees. Speaking generally, paper absorbs dyes
+more readily than do soils, while soils absorb bases more readily than
+does paper. Hence the reddening of litmus paper when in contact with a
+moist soil. Heavy soils or soils containing much hydrated ferric oxide
+absorb bases more readily than do light soils, but this is probably
+owing to relative amounts of surface exposed, for the same relation
+holds true with respect to phosphoric acid. Soils rich in humus are
+better absorbers than soils not so rich. But here again there is yet
+doubt as to whether the explanation lies in the amount or in the kind
+of surface acting.</p>
+
+<p>From the same solvent different dissolved substances are absorbed quite
+differently by any given absorbent. This can be readily illustrated
+again by dyes. If an aqueous solution of a mixture of methylene
+blue and sodium eosine, for instance, be shaken up with a soil, or
+percolated through a column of soil, the methylene blue is absorbed the
+more quickly and completely and a partial separation of the two dyes
+can be readily effected, the separation being more or less complete
+according to the conditions of the experiment. In the same manner two
+salts in solution can be separated partially at least.&#x2060;<a id="FNanchor_74_74" href="#Footnote_74_74" class="fnanchor">[74]</a>
+Soils absorb potassium more readily than sodium; magnesium more readily
+than lime; and ammonia more readily than any of these bases.&#x2060;<a id="FNanchor_75_75" href="#Footnote_75_75" class="fnanchor">[75]</a></p>
+
+<p>The absorption from aqueous solutions of inorganic salts involves a
+most interesting complication. Just as a mixture of two or more dyes
+or salts in solution can be separated by the selective action of an
+absorbent, so can an electrolyte itself be decomposed or resolved.
+<span class="pagenum" id="Page_62">[Pg 62]</span>
+Thus, if a solution of potassium chloride be passed through a column
+of soil, or cotton, or paper, or any similar absorbent, the filtrate
+will not only be less concentrated than the original solution, but the
+potassium will be found to have been absorbed to a greater extent than
+the chlorine, that is, the percolate contains free hydrochloric acid.
+The importance of this phenomenon for the conservation of the desirable
+constituents of manurial salts, and the elimination or leaching out
+of the less desirable constituents is obviously great. Equally great
+perhaps, is the effect upon the reaction of the soil, whether it be
+rendered temporarily alkaline or acid, an effect of the very greatest
+importance for the growth of some of our common crop plants&#x2060;<a id="FNanchor_76_76" href="#Footnote_76_76" class="fnanchor">[76]</a>
+and for the lower soil organisms, such as the bacteria, molds, together
+with ferments, enzymes, etc., many of which are very sensitive to the
+reaction of the media in which they may be, and which in turn are of
+undoubted importance in determining the fertility of the soil for
+higher plants.</p>
+
+<p>The absorption of a dissolved substance from solution by an absorbent
+is in effect a distribution phenomenon and the simplest formula to give
+quantitative expression to such a distribution is C/C¹ = K when C is
+the concentration in the liquid phase and C¹ the concentration in the
+solid phase, K being a characteristic constant for the particular case
+under consideration. When a chemical reaction or a change of state,
+chemical or physical, is involved in the absorption in either dissolved
+substance or absorbent the formula becomes Cⁿ/C¹ = K when <i>n</i> is a
+function which may be very simple or very complex. Attempts to develop
+a precise formula of this general type for the absorption by some given
+soil, although such a formula would be desirable for theoretical and
+<span class="pagenum" id="Page_63">[Pg 63]</span>
+practical reasons alike, have uniformly failed. A sufficient reason for
+this failure seems to lie in the fact that most dissolved substances
+produce an appreciable effect on the granulation or flocculation of
+the soil particles, which is progressive with the absorption so that
+a continual change of absorbing or effective surface is taking place
+as the absorption proceeds.&#x2060;<a id="FNanchor_77_77" href="#Footnote_77_77" class="fnanchor">[77]</a>
+Moreover, in the case of an absorption, with the formation of a
+continuous film of the dissolved substance, a new kind of absorbing
+surface is developed. Hence <i>n</i> is a function of so difficult a
+character as to defy thus far any attempt at formulation.&#x2060;<a id="FNanchor_78_78" href="#Footnote_78_78" class="fnanchor">[78]</a></p>
+
+<p>We cannot therefore predict in any quantitative way what will be
+the distribution of a soluble substance such as salts in commercial
+fertilizers, for instance, between the solid soil particles and the
+soil solution. Empirical experiments show, however, that with the
+amount of a soluble salt present under normal conditions in a humid
+climate, or as used in fertilizer practice, the absorption of ammonia,
+lime, potassium or phosphoric acid is relatively very great, and in a
+general way in about the order named.</p>
+
+<p>Absorption is not an instantaneous process. However, the rate at which
+a dissolved substance is absorbed is generally quite rapid. That is, if
+<span class="pagenum" id="Page_64">[Pg 64]</span>
+a soil be stirred or mixed with an aqueous solution, the absorption
+takes place very quickly, in the absence of any outside disturbing
+influences. The law governing the rate of absorption by soils has
+not therefore possessed any great practical interest and has not
+been studied from a quantitative point of view, although it is
+known qualitatively that the rate is increased by increasing the
+concentration of the solution, or by increasing the amount of the
+absorbent or at least its effective surface. Two rate equations are
+of interest in this connection, and have been carefully studied. The
+rate at which a salt or other dissolved substance will advance into
+an absorbing soil from a solution is given by the same equation as
+that describing the rate of advance of the water itself, <i>yⁿ</i> =
+<i>kt</i> where <i>y</i> is the distance and <i>t</i> the
+time.&#x2060;<a id="FNanchor_79_79" href="#Footnote_79_79" class="fnanchor">[79]</a>
+The constants <i>n</i> and <i>k</i> for the slower moving dissolved
+substance are different from those for the water. This equation has
+probably little importance for ordinary agriculture, for absorption by
+the soil from a large (and relatively illimitable) mass of solution
+is unusual. That it may have considerable importance in seepage,
+irrigation, and some soil engineering problems, seems quite likely.</p>
+
+<p>The rate at which a soil will absorb a dissolved substance from a
+percolating solution is given by the equation</p>
+
+<table class="spb1 fs_120">
+ <tbody><tr>
+ <td class="tdl bb">&nbsp;<i>dx</i>&nbsp;</td>
+ <td class="tdl_wsp" rowspan="2">= K(A - <i>x</i>),</td>
+ </tr><tr>
+ <td class="tdl"><i>dt</i></td>
+ </tr>
+ </tbody>
+</table>
+
+<p class="no-indent">as has been pointed out above.&#x2060;<a id="FNanchor_80_80" href="#Footnote_80_80" class="fnanchor">[80]</a>
+More interesting and important, however, is the fact that this same
+equation describes the rate at which an absorbed substance is removed
+from the soil by leaching. In the case of soils in humid areas
+<i>dx</i>/<i>dt</i> rapidly becomes exceedingly small as <i>x</i>
+approaches A, that is, when the amount of soluble material in the soil
+becomes small, and is practically constant under such conditions, as
+has been pointed out above when describing the removal of potassium
+and phosphoric acid from soils by percolating waters. This formula has
+a special interest in considering the reclamation of alkali lands by
+underdrainage, a problem to which reference will be made later.</p>
+
+<p>Both percolation experiments, as those cited above, and direct
+absorption experiments made by shaking up soils with solutions of the
+<span class="pagenum" id="Page_65">[Pg 65]</span>
+salts in question, show conclusively that the absorption phenomena
+taking place in the soil are in harmony with the direct solubility
+effects in tending to produce and maintain a solution of a normal
+concentration as regards those constituents which it happens are also
+derived from the soil minerals.&#x2060;<a id="FNanchor_81_81" href="#Footnote_81_81" class="fnanchor">[81]</a>
+It is an interesting coincidence that nitric acid (in combination with
+various bases of course) is very little absorbed by most soils, and
+does vary in concentration, not only in different soils but in the same
+soil, between wide limits, and within short intervals of time.&#x2060;<a id="FNanchor_82_82" href="#Footnote_82_82" class="fnanchor">[82]</a>
+The nitrates of the soil are not derived from minerals, and should
+more properly be considered with the organic constituents of the soil
+solution.</p>
+
+<p>An important application of these views concerning absorption arises
+in connection with certain widespread notions concerning soil acidity.
+There is a popular belief that most soils are acid, that the soil
+solution contains some free acid, mineral or organic, other than
+dissolved carbon dioxide, and that a neutral or alkaline solution is
+necessary to the successful production of most of our crops. This
+belief is, however, unwarranted, for the vast majority of soils yield
+an aqueous extract which is alkaline when boiled to expel carbon
+dioxide, and some of our crops, for instance wheat, seem to thrive
+better in a slightly acid medium. This popular fallacy seems to have its
+<span class="pagenum" id="Page_66">[Pg 66]</span>
+origin in the fact that most soils when moistened and pressed against
+blue litmus paper, redden it. This reddening may sometimes be due to
+the actual presence of some acid, or to dissolved carbon dioxide, but
+is undoubtedly due in the majority of cases to selective absorption.
+Litmus is a red dye of an acid-like character, which forms a soluble
+blue salt with the ordinary bases. But it has been shown that most
+soils are better absorbents of bases than is paper, whereas paper
+is a better absorbent of dye, speaking generally, than is a soil.
+Consequently when moist soil is brought into contact with wetted blue
+litmus paper the base is absorbed more readily by the soil, and the dye
+by the paper, the latter therefore becoming reddened.</p>
+
+<p>The reddening of blue or “neutral” litmus paper can be accomplished
+with various absorbents. By pressing the litmus paper between moistened
+wads of absorbent cotton the reddening can be readily accomplished,
+usually in the course of ten minutes to a half hour. That the
+phenomenon is not due to any adhering acid on the cotton can be shown
+in the following way: A litmus solution is carefully prepared so that
+there is a very small excess of base present over that required to
+give the blue color. A wad of absorbent cotton is carefully washed by
+repeatedly sousing it in distilled water from which carbon dioxide has
+been expelled by boiling. When the cotton has been thoroughly washed,
+it is stirred thoroughly in a portion of distilled water, free from
+carbon dioxide, then withdrawn by some appropriate instrument and
+allowed to drain for a few minutes. The litmus is added in fairly large
+quantity to the drainings, which should then have a blue color. Again
+stir the cotton in the water, and more or less quickly, depending on
+the amount and purity of the litmus preparation as well as the quantity
+of cotton used, the solution will become red. The only criterion for
+determining surely that a soil is acid, is to make an aqueous extract,
+expel the dissolved carbon dioxide by boiling, or by passing through
+the solution an inactive gas, such as nitrogen, and then to test the
+reaction of the solution. Acid soils undoubtedly do exist, but they are
+by no means common or widespread, and are to be regarded as exceptional
+and abnormal.
+<span class="pagenum" id="Page_67">[Pg 67]</span></p>
+
+<p>The phenomena of selective absorption suggest the important part which
+surfaces play in modifying and changing chemical reactions.&#x2060;<a id="FNanchor_83_83" href="#Footnote_83_83" class="fnanchor">[83]</a>
+For instance, Becquerel&#x2060;<a id="FNanchor_84_84" href="#Footnote_84_84" class="fnanchor">[84]</a>
+observed that a solution of copper nitrate or cobalt chloride diffusing
+from a cracked test-tube placed in a solution of sodium sulphide, led
+to the formation of the corresponding sulphide, but in the crack the
+metal itself was precipitated. Experiments of Graham&#x2060;<a id="FNanchor_85_85" href="#Footnote_85_85" class="fnanchor">[85]</a>
+show that when a solution of silver nitrate is percolated through
+charcoal, not only is there a selective absorption as is shown by
+the percolate containing free acid, but there is a chemical reaction
+involved, since the silver is deposited in metallic spangles in the
+interstices of the absorbent. Graham has shown, and since his time
+others, that often metals can be separated from solutions of their
+salts by such absorbents as charcoal. Spring&#x2060;<a id="FNanchor_86_86" href="#Footnote_86_86" class="fnanchor">[86]</a>
+has shown that at bounding surfaces of dilute solutions, chemical
+action is increased.</p>
+
+<p>It has been shown that the amount and kind of surface has a marked
+influence on the decomposition of hypochlorous acid, carbon dioxide,
+phosphine, arsine, and other compounds. Meyer and his associates, as
+well as a number of other investigators, have shown that the character
+of the surface of the containing vessel greatly affects the combination
+of hydrogen and oxygen. Many reactions have been investigated by van’t
+Hoff, who concludes that both the nature and amount of surface exposed
+have an influence. The inversion of sugar is affected by the nature
+of the walls of the containing vessel, and its reduction by Fehling’s
+solution is affected both by the walls of the vessel and the amount of
+cuprous oxide formed in the reaction. Alteration in the character as
+well as degree of a number of reactions by having them take place in
+<span class="pagenum" id="Page_68">[Pg 68]</span>
+capillary spaces has been observed by Liebreich, Becquerel, Lieving
+and other investigators. So-called “contact reactions,” as in the
+production of sulphuric acid, are now familiar processes finding
+commercial applications. And the solubility of some substances at
+least, notably gypsum, has been shown to vary considerably with the
+size and consequent shape of the particles in the solid substance in
+contact with its solution.&#x2060;<a id="FNanchor_87_87" href="#Footnote_87_87" class="fnanchor">[87]</a></p>
+
+<p>It has been shown that some soils will at times produce the blue
+coloration in alcoholic solutions of guiac, which is characteristic
+of oxidases, and yellow aloin solutions are sometimes colored red.
+Hydrogen peroxide is decomposed by some soils even after they have been
+thoroughly ignited to get rid of all organic matter. But in how far
+these effects may be due to surface influences can not be positively
+stated; yet uncompleted investigations by Dr. M. X. Sullivan indicate
+that some of these phenomena at least must be attributed to specific
+influences (although probably of catalytic character) of particular
+soil components, such possibly as manganous oxide or ferric oxide; but
+the mechanism of the reactions is as yet largely speculative.</p>
+
+<p>The soil is composed in large part of very fine particles of rounded
+shape, exposing relatively an enormous surface to the soil solution,
+and normally this solution is mainly under capillary conditions, so
+that we should expect that many reactions would take place quite
+differently in the soil from the way they would in a beaker or flask.
+This fact has been generally overlooked or ignored, and is probably
+the explanation of many of the apparently anomalous results hitherto
+reported in chemical investigations of soils. Abnormal solubilities,
+precipitations, oxidations or reductions are frequently found in the
+literature, and when their abnormality is noted at all, they are too
+often and with slight show of reason ascribed to indefinite bacterial
+action or more mysterious vital agencies. Many of them are undoubtedly
+the results of surface actions. Unfortunately, aside from some few
+<span class="pagenum" id="Page_69">[Pg 69]</span>
+studies of absorption phenomena, surface effects have received little
+or no attention from soil investigators, although obviously one of the
+most important and apparently fruitful fields, requiring immediate
+attention. Enough is known to justify the statement that the chemistry
+of the soil need not be, and probably is not, the chemistry of the beaker.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_70">[Pg 70]</span></p>
+<h2 class="nobreak">Chapter IX.<br>
+<span class="h_subtitle">THE RELATION OF PLANT GROWTH<br> TO CONCENTRATION.</span></h2>
+</div>
+
+<p>That the concentration of the mineral constituents in the soil solution
+under normal conditions is competent for plant support, is shown by
+numerous experiments. Birner and Lucanus&#x2060;<a id="FNanchor_88_88" href="#Footnote_88_88" class="fnanchor">[88]</a>
+in an experiment that has long since become classic, found that they
+could raise wheat to maturity in a well-water, the concentration of
+which was approximately 18 parts per million with respect to potassium,
+and 2 parts per million with respect to phosphoric acid, while the
+corresponding concentrations of the soil solution are normally about
+25-30 parts per million of potassium and 6-8 parts per million of
+phosphoric acid. Nevertheless Birner and Lucanus report that the wheat
+grown in the well-water throve even better than that grown at the same
+time in a rich garden mold. Since then many investigators in numerous
+trials have obtained similar results. Recently wheat, corn, and some of
+the common grasses have been grown to a satisfactory maturity in tap
+water with a concentration of about 7 parts per million of potassium
+and 0.5 parts per million of phosphoric acid. And repeatedly wheat
+plants, grasses, cowpeas, vetches, potatoes and other plants have
+grown in a satisfactory way in solutions made by shaking up a soil in
+distilled water and separating from the solid particles by means of
+filters of unglazed porcelain.</p>
+
+<p>There can be no doubt, therefore, that the soil solution is normally
+of a concentration amply sufficient to support ordinary crop plants,
+and is maintained at a sufficient concentration, so far as mineral
+plant nutrients are concerned. Undoubtedly, however, variations in
+the concentration of the soil solution can, and often do, take place,
+and the results of laboratory experiment indicate that they probably
+produce effects on plants.</p>
+
+<p>It has been shown in water-culture experiments with wheat, that if a
+given ratio of mineral nutrients be maintained, relatively small effect
+<span class="pagenum" id="Page_71">[Pg 71]</span>
+is produced on the growing plants by varying the concentration over
+a wide range, in one case from 75 parts per million to 750 parts per
+million,&#x2060;<a id="FNanchor_89_89" href="#Footnote_89_89" class="fnanchor">[89]</a>
+and this effect seems to be largely independent of the nature of the
+particular mixture of solutes. But varying the relative proportions
+of the mineral constituents has been shown by numerous experiments to
+produce very marked changes in the growth of plants. Not only does a
+control of the concentration and proportion of the mineral constituents
+of a solution produce a more rapid, or a slower growth, a greater or
+lesser total growth, but it produces differences in the character of
+growth; as for instance, causing the tops to grow relatively faster
+than the roots, or <i>vice versa</i>. However, many effects of this
+type can be produced, and sometimes more readily, by soluble organic
+substances, or mechanical agencies. The mechanism of these effects
+is by no means clear, in many cases. That other causes obtain than a
+sufficient supply of mineral nutrients will be shown in the following
+chapters. Experiments with wheat seedlings in water cultures, where the
+weights of the green tops were taken as the measure of growth, showed
+that the most-favorable ratio was one of phosphoric acid (PO₄) to three
+or four of potassium (K), about the ratio which has been found to exist
+normally in the soil solution of humid areas of the United States,
+namely, 6-8 parts per million of phosphoric acid to 25-30 parts per
+million of potassium.</p>
+
+<p>All growing plants require for their growth and development various
+organic compounds containing carbon, hydrogen, oxygen and nitrogen. The
+higher crop plants with which agricultural investigations appear to
+be more immediately concerned, seem to have inherent power to produce
+these needed substances within themselves. But it is becoming more and
+more evident that the large problem of soil fertility, or the relation
+of the soil to crop production, frequently if not generally involves
+the growth and development of lower organisms including ferments and
+bacteria. These may or may not in particular cases, favor the growth
+of the desired higher plants. Many of these lower organisms require
+<span class="pagenum" id="Page_72">[Pg 72]</span>
+certain organic compounds or thrive better if these are brought to
+them in the soil solution, and indeed evidence is not lacking that
+such may sometimes be the case even with the higher plants. Certainly
+their growth can be much affected by the presence of different organic
+substances in the nutrient solution. Enough work has been done in
+this field of investigation to show that the concentration of the
+soil solution or artificial nutrient solution with respect to the
+organic compounds must generally be low; too high a concentration
+always inhibits growth or even produces death; and there is probably
+an optimum concentration, or one at which the plant will grow best;
+but this optimum concentration varies with the specific nature of the
+plant, the presence of other dissolved substances, mineral or organic,
+and possibly with other factors. While a notable amount of work has
+thus been done in a field of inquiry obviously of practical as well as
+theoretical interest, almost no definite information has as yet been
+obtained as to the concentration of organic substances in the soil
+solution, or its effect upon plants under field conditions, excepting
+in the case of the nitrates, the products of bacterial activities. The
+concentration with respect to nitrates is known to vary greatly from
+a few parts to several thousand parts per million, and this sometimes
+within a few days or even hours. The great changes in concentration
+with respect to nitrates, the rapidity of the changes, and the
+correspondingly large effects on growing plants make this a subject
+requiring special treatment by itself. This at present seems more
+easily appreciated from a consideration of the bacteria involved, and
+will not be discussed more fully here.&#x2060;<a id="FNanchor_90_90" href="#Footnote_90_90" class="fnanchor">[90]</a></p>
+
+<p>Of the ash constituents of plants, there must be in the soil solution,
+potassium, magnesium, phosphorus, sulphur and iron for any plant
+<span class="pagenum" id="Page_73">[Pg 73]</span>
+growth, and for the higher crop plants, calcium must also be present.
+Of these, iron is usually present in barely appreciable concentration
+and more than this is not desirable, or is even harmful for common crop
+plants. Under the normal conditions for soils in humid areas, sulphur
+also is usually present in scarcely more than appreciable quantities
+and there is no positive evidence to show that higher concentrations
+are especially desirable, though this may be the case for certain
+crops, such for instance as the onion. Phosphorus is usually present to
+the extent of 5 or 6 parts per million of phosphoric acid (P₂O₅),
+while it has repeatedly been shown that such crops as wheat can thrive
+and make a good growth with a concentration a tenth of this. It appears
+to be clear therefore that as far as food supply is concerned there is
+normally an ample supply of phosphorus in the soil solution; but it
+does not follow that increasing the concentration of the solution if
+only temporarily would not result in favorable effects upon growing plants.</p>
+
+<p>A consideration of the bases, however, introduces serious difficulties,
+which will probably require much further research by the plant
+physiologist as well as the soil chemist. It is impossible as yet to
+determine the concentrations at which different plants will not grow.
+It is even impossible to determine the concentrations at which they
+will thrive best. It seems certain that different crop plants require
+different amounts of these minerals, but whether or not they require
+different concentrations of the constituents in the nutrient solution
+for their several best growths is yet not clearly shown. It now seems
+probable that to some extent at least these basic mineral nutrients
+can replace one another for the plant’s metabolism. It has been shown
+in the case of certain lower plant organisms that potassium can be
+more or less successfully replaced by rubidium and caesium, and in the
+case of some higher plants, possibly calcium, magnesium and potassium
+can partially replace one another.&#x2060;<a id="FNanchor_91_91" href="#Footnote_91_91" class="fnanchor">[91]</a>
+In spite of the fact that sodium as well as potassium is a necessary
+<span class="pagenum" id="Page_74">[Pg 74]</span>
+constituent for the metabolism of higher animals which feed upon
+plants, it is generally held that sodium can not replace potassium in
+the processes of plant growth, although Wheeler and his colleagues have
+advanced evidence to show that a partial replacement is
+possible.&#x2060;<a id="FNanchor_92_92" href="#Footnote_92_92" class="fnanchor">[92]</a>
+It seems evident, however, that no generalizations can hold concerning
+the effect of the concentration of any one base on plant growth which
+do not include recognition of possible modifications due to the
+presence of other bases; and the formulation of such generalizations
+must needs wait upon a more thorough knowledge of the parts played by the
+several mineral nutrients in the metabolism of different classes of plants.</p>
+
+<p>As to forms or chemical combinations in which the inorganic
+constituents of the soil solution are best adapted to plant growth,
+but little can yet be said other than that the different combinations
+do have an importance. Some empirical information is available, such
+as for instance, that potassium sulphate or carbonate is a better
+fertilizer for some crops than is potassium chloride. It is known that
+the mineral nutrients in the plant are partly in inorganic combinations
+but largely in organic combinations. But the causal relationships are
+yet to be worked out. And finally, although some meagre experimental
+data have been obtained as to the effect of certain inorganic
+constituents on the absorption of others, by particular plants, the
+mechanism of absorption itself, including the selective powers of the
+plant, is yet wanting an adequate explanation.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_75">[Pg 75]</span></p>
+<h2 class="nobreak">Chapter X.<br>
+<span class="h_subtitle">THE BALANCE BETWEEN SUPPLY AND<br>REMOVAL OF MINERAL PLANT NUTRIENTS.</span></h2>
+</div>
+
+<p>The mechanism of the solution and transport of mineral nutrients
+developed in the preceding pages makes it of interest to determine
+the relation between the possible or probable supply of mineral
+plant nutrients and crop demands over large areas. The inquiry can
+be formulated more specifically: Is the movement of mineral plant
+nutrients towards the surface soil equal to or in excess of the removal
+by drainage waters and garnered crops? Satisfactory data are yet
+wanting for anything like exact computations, but approximate figures
+are available which appear sufficient for the present purpose.</p>
+
+<p>The rainfall (R) can be considered as disposed in three portions, the
+fly-off (<i>f</i>), the run-off (<i>r</i>), and the cut-off (<i>c</i>).
+Stating this as an equation,</p>
+
+<p class="f120">R = <i>f</i> + <i>r</i> + <i>c</i>.</p>
+
+<p class="no-indent">The cut-off can be resolved into the portion
+(<i>a</i>) seeping through the soil to ultimately join the run-off, and
+the portion (<i>b</i>) returning to the surface to ultimately join the
+fly-off. Stated as equations,</p>
+
+<p class="f120">R = <i>f</i> + <i>r</i> + <i>a</i> + <i>b</i></p>
+<p class="f120"><span class="ws2">= <i>f</i> + <i>b</i> + (<i>r</i> + <i>a</i>).</span></p>
+
+<p class="no-indent">In other words, the rainfall can also be considered as made
+up of the fly-off, the capillary water of the soil and the drainage from the
+area. According to Murray,&#x2060;<a id="FNanchor_93_93" href="#Footnote_93_93" class="fnanchor">[93]</a>
+Geikie,&#x2060;<a id="FNanchor_94_94" href="#Footnote_94_94" class="fnanchor">[94]</a>
+Newell,&#x2060;<a id="FNanchor_95_95" href="#Footnote_95_95" class="fnanchor">[95]</a>
+and others, the drainage water for humid areas, or such an area as
+the United States as a whole, would be between 20 and 30 per cent. of
+the rainfall, the major portion coming from seepage water rather than
+<span class="pagenum" id="Page_76">[Pg 76]</span>
+surface drainage. Assuming the higher figure, and making the further
+very probable assumption that the capillary water in the soil
+(<i>b</i>) is never less than the fly-off or the water that evaporates
+during rain (<i>f</i>), it follows from the equations given that
+the capillary water is at least 35 per cent. of the rainfall. If we
+assume the lower value for the drainage, then the capillary water is
+at least 40 per cent. of the rainfall, and if we assume the extreme
+case—that the fly-off is practically negligible—the capillary water
+becomes 80 per cent. of the rainfall. It appears, therefore, that in
+all probability the proportion of the cut-off water which returns to
+the surface as film water or capillary water is always greater, and
+generally much greater, than the portion which seeps through the soil
+to join the run-off.</p>
+
+<p>From the available data, it appears that the average concentration of
+the run-off waters of the United States is about 1.8 parts per million
+of potassium (K) and about 0.6 parts per million of phosphoric acid
+(PO₄),&#x2060;<a id="FNanchor_96_96" href="#Footnote_96_96" class="fnanchor">[96]</a>
+while the concentration of the capillary groundwater is some ten or
+twelve times greater. But even if these concentrations were the same,
+it is altogether probable that very much the greater part of the
+mineral plant nutrients dissolved by meteoric waters is continually, if
+slowly, moving towards the surface of the soil.</p>
+
+<p>The average rainfall of the United States may be taken as approximately
+30 inches.&#x2060;<a id="FNanchor_97_97" href="#Footnote_97_97" class="fnanchor">[97]</a>
+If it be assumed that the discharge into the sea is 25 per cent., then
+the capillary cut-off water is at least 37.5, and probably nearer 70
+per cent. of the rainfall. King’s experimental work&#x2060;<a id="FNanchor_98_98" href="#Footnote_98_98" class="fnanchor">[98]</a>
+indicates that the higher figure is much nearer the truth. Computing
+from the concentrations just cited, with the equations given above, it
+is found that approximately 3,500,000 tons of potassium (K)
+<span class="pagenum" id="Page_77">[Pg 77]</span>
+and 1,200,000 tons of phosphoric acid (PO₄) are carried into the sea
+annually from the United States, while from 48,000,000 to 100,000,000
+tons of potassium and 18,000,000 to 40,000,000 tons of phosphoric acid
+are being carried towards the surface of the soil. If it be assumed
+that an average of one ton per acre of dry crop containing one per
+cent. potash and 0.6 per cent. phosphoric acid&#x2060;<a id="FNanchor_99_99" href="#Footnote_99_99" class="fnanchor">[99]</a>
+be removed from the entire area of the United States, then the annual
+loss from this source would be 24,000,000 tons of potassium and
+14,000,000 tons of phosphoric acid. Consequently, there is an ample
+margin between the losses by cropping and seepage waters, and the
+supply of capillary waters. It is true that cases exist where the
+production of vegetable matter is much greater than a ton to the acre,
+productions of five tons or even more being on record. But such cases
+occur only where the water supply is also greater, either through
+natural rainfall or artificial irrigation; and it should also be borne
+in mind that the production of so large a mass of green crop involves
+a considerable drawing power on the water in the soil in addition to
+the evaporation which would take place at the surface under ordinary
+conditions. In other words, the plant would then be playing no small
+part in drawing to itself its needed supplies of water and dissolved
+mineral nutrients.</p>
+
+<p>The question may be asked, if the processes outlined above are
+generally operative, why accumulations of soluble mineral substances
+are not usually found at the surface of the soil. As a matter of fact
+such accumulations do occur normally when the evaporation at the
+surface is relatively large, that is, under arid conditions. And under
+humid conditions it appears to be a general rule that the surface
+soil contains more readily soluble or absorbed mineral matter than do
+<span class="pagenum" id="Page_78">[Pg 78]</span>
+subsoils.&#x2060;<a id="FNanchor_100_100" href="#Footnote_100_100" class="fnanchor">[100]</a>
+No great accumulation occurs at the surface normally under humid
+conditions because the rainfall is sufficiently distributed throughout
+the year to enable the cut-off water to carry back promptly into the
+lower soil levels any excessive amount of soluble material, there to
+start anew its slower ascent towards the surface.</p>
+
+<p>Calculations such as those here presented are at the best open to many
+objections, and it is wise to avoid giving them too much emphasis. So
+far as the available data justify any conclusion, however, it appears
+that the rise of capillary water is entirely capable of maintaining
+a sufficient supply of mineral nutrients for crop requirements; and
+furthermore, it is obvious that the problem of the supply of mineral
+plant nutrients is dynamic and cannot be successfully attacked by
+considerations which are essentially static.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_79">[Pg 79]</span></p>
+<h2 class="nobreak">Chapter XI.<br>
+<span class="h_subtitle">THE ORGANIC CONSTITUENTS OF<br> THE SOIL SOLUTION.</span></h2>
+</div>
+
+<p>The organic substances in the soil are tissue remains, to a large
+extent of plants, and to a less extent of animals; and it is to be
+expected that there may be found also in the soil the substances which
+were in the organisms at the time of their death, and degradation and
+decomposition products derived from these. Moreover, there are to
+be anticipated numerous products of bacterial origin, secretions of
+algae, fungi, etc., so that the organic complex in the soil may contain
+numerous substances of widely different chemical characteristics.
+Degradation products of proteins, fats, and carbohydrates, as well
+as decomposition products may be expected in almost any soil. But it
+does not follow that any particular organic substance (excluding, of
+course, carbon dioxide or nitrates) is to be found in every soil. No
+generalization regarding the organic substances in the soil can be made
+such as that formulated for the inorganic compounds. It is probable
+that further investigation will show certain organic substances or
+classes of substances to be common to most soils, but it is reasonably
+certain that many other organic substances will be found in only a few
+soils, or occasionally, and these latter will be often a prominent
+factor characterizing the particular soil in which they may occur.</p>
+
+<p>Although no broad generalization is justified regarding the composition
+of the soil solution with respect to organic substances dissolved,
+nevertheless the extension of the methods developed in the study of the
+inorganic substances dissolved has led to a considerable knowledge of
+the organic ones.</p>
+
+<p>In view of the facts shown in the preceding chapters, and at the same
+time recognizing that good and poor soils respectively must show
+differences in the soil solution if the fundamental thesis is valid as
+to the relation of soils to crop production, experiments have been made
+to investigate in a comparative way solutions obtained from good and
+poor soils of the same type, locality, and physical characteristics.
+For this purpose two samples of soil were taken from adjacent fields
+<span class="pagenum" id="Page_80">[Pg 80]</span>
+which had been under observation for two years. The soils were of
+the same type, Cecil clay, and were so similar in their physical
+characteristics as to be distinguished with difficulty in the
+laboratory. On one field a good crop of wheat was grown, followed
+by a good crop of clover and tame grasses. On the other field, the
+corresponding crops had been quite poor. The field yielding the good
+crops had been plowed somewhat deeper, and had previously received a
+moderate application of stable manure. Otherwise, so far as could be
+learned, the cultural history of the fields had been the same. For
+convenience, the sample from the first field will be designated “good,”
+and from the other “poor.”</p>
+
+<p>Aqueous extracts from these soils were prepared, the same proportion
+of distilled water to soil being taken in each case, and the time of
+contact being the same. The solutions were freed from suspended matter
+by being passed through Pasteur-Chamberland bougies under pressure.
+Young wheat seedlings germinated at the same time, and selected
+carefully for uniformity of size and apparent vigor, were grown in
+these solutions for three days. At the expiration of this period the
+seedlings in the extract from the good soil were about five inches in
+height, and the roots were clear, clean and turgid. The plants in the
+poor extract were scarcely three inches in height, and the roots were
+assuming a slimy, unhealthy appearance and becoming flaccid at the
+tips. The plants were then all removed, the roots washed carefully in
+tap water; the plants which had been in the poor solution were placed
+in the good solution, and those which had been in the good solution
+were placed in the poor solution. At the end of four days further,
+the poor plants had surpassed in height the ones which had previously
+been in the good solution, and the roots had acquired the general
+characteristics of healthy plants. These which had been originally in
+the good solution and then transferred to the poor, had made little
+additional growth, and the roots had become somewhat flaccid.&#x2060;<a id="FNanchor_101_101" href="#Footnote_101_101" class="fnanchor">[101]</a></p>
+
+<p><span class="pagenum" id="Page_81">[Pg 81]</span>
+This experiment was repeated several times, not only with the soils
+cited but with samples from adjacent good and poor spots in fields
+on several soil types from widely separated areas; for instance,
+Cecil clay from near Statesville, North Carolina; Sassafras loam
+from Maryland; Windsor sand from Delaware; and similar results were
+obtained. In other words, these water cultures produced plants which
+showed much the same differences, in kind and degree, as had been
+observed in the field. This was recognized as an important step
+forward, for it indicated that <i>whatever was making a difference in
+the crop-producing power of these soils in the field was transmitted
+to their aqueous extracts</i>, and methods for studying the chemical
+properties of solutions are far in advance of methods for studying
+mixtures of solids.</p>
+
+<p>The soil extracts described above were subjected to a careful analysis
+for their mineral constituents. They were found to be practically
+identical in this respect. Further, the poor extract contained
+decidedly more nitrates than the good—from three to four times as
+much. It follows, therefore, that the difference in the soils which
+produced a good and a poor crop respectively, was not due to a
+difference in mineral plant nutrients, or other mineral differences
+probably, nor to their respective content of nitrates. Consequently,
+the poor solution was such, not because of the lack of anything, but
+because of the presence of something inimical or “toxic” to plant
+growth; and further, this something must be an organic substance or
+substances more or less soluble in water. This conclusion was confirmed
+in the following way.</p>
+
+<p>Samples of the poor solution from the soil obtained near Statesville,
+N. C., were diluted twice, five times, and ten times, and wheat
+seedlings were grown in these solutions, using a sample of the good
+solution as a check. It was found after several days growth that the
+plants in the solution diluted tenfold were about as good, or perhaps
+slightly better, than those grown in the check solution. In every
+case diluting the poor solution had improved it for plant growth,
+and the higher the dilution the greater the improvement, in spite
+of the consequent dilution of the mineral plant nutrients. The only
+<span class="pagenum" id="Page_82">[Pg 82]</span>
+explanation of these results which has yet suggested itself is that
+the toxic organic substances present were less effective on dilution
+until the concentration reached a point where they actually became
+stimulative, as is common with toxins of every character.</p>
+
+<p>Another set of experiments confirmed the conclusion that the poor
+solution contained some organic substance inhibitory to plant growth.
+A number of water cultures was prepared from the aqueous extract of
+the poor soil, and lime in various forms was added to the cultures. To
+two of the cultures lime carbonate and lime sulphate respectively were
+added in excess, so that there was in each case a powdered solid at
+the bottom of the containing vessel. At the end of two days the wheat
+seedlings which were growing in the vessels containing the powdered
+solids had decidedly outstripped those growing in all the others, the
+tops having the appearance of unusually good and healthy plants. The
+roots were of a very remarkable character, being exceptionally long,
+very turgid, clear, clean and translucent.</p>
+
+<p>At once, new experiments were carried out in which there were added
+to the poor solution, precipitated ferric hydroxide freed from all
+adhering salts, precipitated alumina, shredded filter-paper, absorbent
+cotton, or carbon black. In every case the same result was obtained
+as before, a much improved growth of top and a vastly better root
+development. Since, by no possibility could these various added
+substances have increased the concentration with respect to mineral
+nutrients, another explanation must be sought. Aside from their
+insolubility, the one property common to these various substances
+was the large amount of surface they brought into contact with the
+solution. The one obvious explanation of their effects on the growth of
+the wheat seedlings, therefore, is that they withdrew or absorbed from
+the solution some substance or substances deleterious to plant growth.
+As diluting with respect to mineral nutrients could not possibly be
+expected to improve the cultural value of the solution, the conclusion
+seems evident that the effect produced by these various absorbents
+was due to more or less complete removal from the solution of organic
+<span class="pagenum" id="Page_83">[Pg 83]</span>
+substances inhibitory to plant growth. These experiments were then
+repeated in a modified form by shaking the poor solution with such
+absorbents as precipitated ferric oxide or carbon black and filtering
+before adding the seedling plants. The solutions thus prepared proved
+very satisfactory nutrient media, although the decided elongation of
+the roots, always observed when the absorbents were in contact with the
+solutions, was not so noticeable with these filtered solutions.</p>
+
+<p>The experiments just described were repeated with extracts from a
+number of soils which were supporting or had recently supported poor
+crops. The accumulated mass of evidence admits of no doubt that in many
+cases the apparent lack of fertility of a soil is due to the presence
+of some organic substance or substances soluble in soil water. This
+point established, there was studied the effect of fertilizers when
+added to aqueous extracts from poor soils.</p>
+
+<p>A large amount of experimenting has been done on this subject. It has
+been found that the common commercial fertilizers, as well as many
+other substances, when added to the soil extract containing growing
+plants, sometimes improve the plants, sometimes the contrary. But, in
+general, those particular substances which improve any given soil for
+a crop also improve the aqueous extract of the soil for the growth of
+the same crop plant: <i>i. e.</i>, should a soil be known to respond
+well to the application of superphosphates when planted to wheat, then
+the probability is great that the aqueous extract of the soil will be
+improved as a culture medium for the wheat plant by addition of calcium
+phosphate. Particularly important in this connection are certain
+experiments with organic fertilizers.</p>
+
+<p>A soil which had been found to be quite unproductive with regard to
+wheat and ordinary tame grasses yielded, however, a much better growth
+of plants if pyrogallol or better pyrogallol and lime were added to the
+soil some days before planting. An aqueous extract of this soil tested
+with young wheat seedlings produced but a poor growth, as did the soil
+itself. But with the addition of pyrogallol or pyrogallol and lime to
+<span class="pagenum" id="Page_84">[Pg 84]</span>
+the soil extract, and especially if the extract so treated were allowed
+to stand for a few days with free access of air, there was obtained
+a culture medium which yielded remarkably good results with wheat
+seedlings. Not only was there an excellent and increased development of
+tops, but the roots of the seedlings grown in the solution treated with
+pyrogallol were unusually long, turgid, clear and translucent. Here,
+then, there was obtained an increased amount and improved character
+of growth by the addition of a substance which contained only carbon,
+hydrogen and oxygen, and no recognized plant food. Other organic
+substances, such for instance as tannin, gave similar results.</p>
+
+<p>With the recognition that the presence of organic dissolved substances
+in the nutrient medium produced effects on a growing plant of as great
+or even greater magnitude than those produced by inorganic dissolved
+substances, there was carried out a number of experiments to test
+more specifically such substances as might reasonably be expected to
+be present naturally in soils. The results thus obtained suggested
+experiments with other related substances. The first substance to
+suggest itself is stable manure. Taking it all in all, this substance
+is probably the most efficient as well as the most generally used soil
+amendment in the experience of mankind. The good effects produced by
+this substance have in the past been generally considered as due to the
+readily “available” potash, phosphoric acid and nitrogen it contains,
+but thoughtful experimenters and agriculturists have long doubted
+that this explanation is sufficient, since, after all, the mineral
+constituents of stable manure are usually small in amount, and out of
+all proportion to the effects resulting from its use. That some of the
+results are due to an improvement in the physical condition of the soil
+when manure is used has quite rightly been generally assumed; but to
+its content of nitrogenous components its value has in the main been
+ascribed.</p>
+
+<p>A well-fermented aqueous extract of stable manure was prepared, and
+filtered free of suspended solids. Four equal volumes of this solution
+were taken. Three of these portions were evaporated to dryness in
+<span class="pagenum" id="Page_85">[Pg 85]</span>
+platinum dishes, and the residues incinerated. To the dishes
+containing: the ash were added respectively nitric acid, sulphuric
+acid, and hydrochloric acid in slight excess, and the dishes again
+brought to dryness. Water cultures for wheat seedlings were then
+prepared.&#x2060;<a id="FNanchor_102_102" href="#Footnote_102_102" class="fnanchor">[102]</a>
+Into one was introduced the given volume of manure extract; into
+another the ash from an equal volume of the extract which had
+subsequently been treated with nitric acid; and cultures with the ash
+which had been treated respectively with sulphuric and hydrochloric
+acid were similarly prepared. After ten days growth, the plants from
+the several cultures were compared. The plants from the cultures which
+contained the sulphates and the chlorides were not materially different
+from the plants grown in the check culture. The plants from the nitrate
+culture had larger shoots, but shorter roots than the check plants.
+But the plants grown in the culture to which the manure extract had
+been added directly had by far larger and better shoots and the roots
+were incomparably superior to those grown in any other culture, being
+larger, thicker, better branched, clear, bright and translucent, and
+very turgid, very like the roots obtained in cultures to which carbon
+black or precipitated ferric oxide had been added.</p>
+
+<p>The results of this experiment, which has been repeated a number
+of times, using manure extracts of various origins, leave no doubt
+that it is the organic components of the manure which produce the
+characteristic effects, for the ash culture contained all and even more
+of the mineral constituents “available” in the original extract, and
+the nitrate culture excluded any explanation based on the nitrogenous
+content of the manure. This conclusion was supported by the results of
+another experiment.</p>
+
+<p>To a manure extract was added alcohol, which precipitated most of the
+organic dissolved substances but very little of the inorganic ones.
+The precipitated organic matter was filtered off, dried carefully in a
+water oven to eliminate the alcohol, and then taken up in sufficient
+water to equal the original volume of manure extract. The nitrate
+<span class="pagenum" id="Page_86">[Pg 86]</span>
+containing the major part of the salts was boiled vigorously to
+eliminate the alcohol and water was then added to restore the original
+concentration. A third solution was prepared by bringing together the
+organic and inorganic substances which had previously been separated as
+above described. The three solutions were used as water cultures for
+wheat seedlings, a solution of the original manure extract being taken
+for a check culture. The original manure extract and the reconstructed
+manure extract gave plants of about equal development. The culture
+containing the organic dissolved substances only, gave plants of
+nearly, but not quite, equal development to those grown in the check
+culture. But the plants grown in the solution containing the dissolved
+minerals only, while fine plants and making what would ordinarily be
+considered a good development, were decidedly smaller as regards their
+aerial parts, and the roots were in no wise comparable to the roots
+of the plants grown in the cultures containing the dissolved organic
+substances.</p>
+
+<p>This last experiment has been repeated, with dissolved substances
+prepared from another manure extract, but in this case the organic
+and inorganic substances were separated by dialysis. This suggested
+yet another experiment, in which it was sought to hasten the process
+of dialysis, by introducing electrodes into the manure extract, each
+electrode being surrounded by some porous membrane, either of parchment
+paper, or unglazed porcelain. Not only were the mineral constituents
+of the manure extract readily separated in this way, passing into
+the electrode chambers, as did also to some slight extent organic
+compounds, but also about the outer walls of the electrode chambers
+there was marked segregation and deposition of organic materials. The
+organic substances deposited at the cathode were found to stimulate
+greatly the growth of wheat seedlings while those deposited at the
+anode were found to retard the growth of seedlings. It seems probable,
+therefore, that stable manure contains organic components which produce
+as great or greater effects upon growing plants as do the inorganic
+substances it contains: that on the whole these organic components
+<span class="pagenum" id="Page_87">[Pg 87]</span>
+induce increased plant growth, but some of them, by themselves alone,
+would retard plant growth.</p>
+
+<p>In a similar way green manures have been examined. If fresh clover,
+alfalfa, or cowpeas, be macerated and an aqueous extract thus prepared,
+it will in general be quite toxic to plants such as wheat; and if this
+extract be allowed to stand and ferment or sour the resulting solution
+will be totally unfit for the growth of seedling plants. But if the
+clover, alfalfa, or cowpea vines be allowed to wilt thoroughly before
+being macerated and extracted, or if they be macerated and incorporated
+with soil and allowed to remain thus for ten days or a fortnight
+before being extracted; then, the resulting solution will be quite
+stimulating to such plants as wheat, corn or the grasses, when added
+either to water or soil cultures. It would seem, therefore, that the
+mineral constituents of the legumes commonly employed as green manures
+are less important than the organic, in affecting the growth of crops
+subsequently planted, and the inhibitory or toxic action of fresh green
+manure seems to be recognized in the common practice of waiting some
+days after turning under a green manure crop before seeding to a new crop.</p>
+
+<p>The wilting of a green manure involves a darkening and some blackening
+of the mass, with apparently some absorption of oxygen. This fact
+has suggested a trial of other organic substances which show a
+decided ability to absorb oxygen. Among such substances, pyrogallol
+stands preëminent. It has been shown that when pyrogallol, or better
+pyrogallol and lime, is added to certain soils, naturally low in
+productive power, and allowed to stand for a few days, these soils are
+readily brought into good condition and support good crops of wheat,
+rye, or grasses. Pyrogallol in water cultures is rather toxic to wheat
+plants, even in quite dilute solutions. But if the aqueous solution
+of pyrogallol be allowed to stand exposed to the air, and better if
+the solution be made slightly alkaline as by the addition of lime,
+oxygen is absorbed, and a dark brown or blackened solution is soon
+formed, which is stimulating to wheat seedlings. Many experiments have
+<span class="pagenum" id="Page_88">[Pg 88]</span>
+indicated it to be a general rule that soluble organic substances which
+are toxic to plant growth yield oxidation products which are harmless
+or positively beneficial.</p>
+
+<p>The suggestion has been made that the well-known infertility of
+subsoils, when freshly turned up, is caused by the presence of
+alkaloids of the purine or codeine type, due to the activities of
+anaerobic bacteria. Water cultures and pot cultures show that while
+these substances do have a marked effect on plant growth, it is,
+frequently, quite beneficial; strychnine for example, in certain
+concentrations, produces a very decided stimulation in the growth of
+wheat seedlings. It is clear that some other explanation will have to
+be sought for the lack of fertility of subsoils.</p>
+
+<p>A number of the substances which may be expected for one reason
+or another to be present in soils, have been investigated as to
+their effect on plants. In this connection may be cited the work of
+Livingston&#x2060;<a id="FNanchor_103_103" href="#Footnote_103_103" class="fnanchor">[103]</a>
+and of Dachnowski,&#x2060;<a id="FNanchor_104_104" href="#Footnote_104_104" class="fnanchor">[104]</a>
+who have studied the effect on vegetation of the organic substances
+dissolved in bog waters. In the following table are given the results
+obtained by growing wheat seedlings in solutions containing some one
+of a number of substances which might be expected to occur in a soil
+or to be derivatives of such substances. It will be observed that in
+the case of these dissolved organic substances, as has been repeatedly
+established with the inorganic ones, in concentrations sufficiently
+dilute not to be toxic, they generally show the opposite effect and
+appear to be stimulating.
+<span class="pagenum" id="Page_89">[Pg 89]</span></p>
+
+<p class="f120 smcap"><b>
+Table I.—Effect of Various Organic Compounds<br> upon the Growth
+of Wheat Plants, with Especial<br> Reference to Their Toxic
+Properties</b>&#x2060;<a id="FNanchor_105_105" href="#Footnote_105_105" class="fnanchor">[105]</a></p>
+
+<ul class="index">
+<li class="isub3">LEGEND:</li>
+<li class="isub5"><b>A</b> = Duration of experiment</li>
+<li class="isub5"><b>B</b> = Lowest concentration causing death</li>
+<li class="isub5"><b>C</b> = Lowest concentration causing injury</li>
+<li class="isub5"><b>D</b> = Concentration causing greatest stimulation</li>
+</ul>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc bb">Compound</th>
+ <th class="tdc bl">A</th>
+ <th class="tdc bl">B</th>
+ <th class="tdc bl">C</th>
+ <th class="tdc bl">D</th>
+ <th class="tdc bl">Remarks</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdc bl">days</td>
+ <td class="tdc bl">p.p.m.</td>
+ <td class="tdc bl">p.p.m.</td>
+ <td class="tdc bl">p.p.m.</td>
+ <td class="tdc bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>a</i> Aspartic acid</td>
+ <td class="tdr_wsp bl" rowspan="2">10</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">100</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdl_wsp bl">Normal growth in concentration</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b>HOOC.CH₂.CH(NH₂).COOH</b></td>
+ <td class="tdl_wsp bl">below 100 p.p.m.</td>
+ </tr><tr>
+ <td class="tdl"><i>b</i> Asparagine</td>
+ <td class="tdr_wsp bl" rowspan="2">9</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdl_wsp bl" rowspan="2">No injury below 1,000 p.p.m.</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b>NH₂.OC.CH₂.CH(NH₂).COOH</b></td>
+ </tr><tr>
+ <td class="tdl"><i>c</i> Glycocoll,</td>
+ <td class="tdr_wsp bl" rowspan="2">9</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdl_wsp bl">Tops of all plants good. Roots slightly</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b>CH₂(NH₂).COOH</b></td>
+ <td class="tdl_wsp bl">injured at higher concentrations</td>
+ </tr><tr>
+ <td class="tdl"><i>d</i> Alanine,</td>
+ <td class="tdr_wsp bl" rowspan="2">10</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">25</td>
+ <td class="tdl_wsp bl" rowspan="2">Only roots were injured at 500 p.p.m.</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b>CH₃.CH(NH₂).COOH</b></td>
+ </tr><tr>
+ <td class="tdl"><i>e</i> Leucine</td>
+ <td class="tdr_wsp bl" rowspan="2">9</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdl_wsp bl" rowspan="2">No injurious action</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b>CH₃.(CH₂)₃.CH(NH₂).COOH</b></td>
+ </tr><tr>
+ <td class="tdl"><i>f</i> &nbsp;Tyrosine,</td>
+ <td class="tdr_wsp bl">11</td>
+ <td class="tdr_wsp bl">....</td>
+ <td class="tdr_wsp bl">10</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b>&emsp;OH<br>&emsp;/<br>C₆ H₄<br>&emsp;\<br>&emsp;CH₂.CH(NH₂).COOH</b></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>g</i>&nbsp; Choline,</td>
+ <td class="tdr_wsp bl">10</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">500</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdl_wsp bl">Roots affected more than tops</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b><span class="ws4">CH₂CH₂OH</span><br><span class="ws4">/</span><br>
+ &nbsp; (CH₃)₃N<br><span class="ws4">\</span><br><span class="ws4">OH</span></b></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl"><span class="pagenum" id="Page_90">[Pg 90]</span></td>
+ </tr><tr>
+ <td class="tdl"><i>h</i>&nbsp; Neurine,</td>
+ <td class="tdr_wsp bl">9</td>
+ <td class="tdr_wsp bl">250</td>
+ <td class="tdr_wsp bl">25</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl"><b><span class="ws4">CH:CH₂</span><br><span class="ws4">/</span><br>
+ &nbsp; (CH₃)₃N<br><span class="ws4">\</span><br><span class="ws4">OH</span></b></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1">Neurine (neutralized)</td>
+ <td class="tdr_wsp bl">8</td>
+ <td class="tdr_wsp bl">250</td>
+ <td class="tdr_wsp bl">25</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>i</i>&nbsp; Betaine,</td>
+ <td class="tdr_wsp bl">9</td>
+ <td class="tdr_wsp bl">...</td>
+ <td class="tdr_wsp bl">...</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">No injury</td>
+ </tr><tr class="bb">
+ <td class="tdl"><img src="images/betaine.jpg" alt="" width="160" height="55" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>j</i>&nbsp; Alloxan,</td>
+ <td class="tdr_wsp bl">10</td>
+ <td class="tdr_wsp bl">1,000</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl"><img src="images/alloxan.jpg" alt="" width="150" height="54" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>k</i>&nbsp; Guanine,</td>
+ <td class="tdr_wsp bl">12</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">Insoluble above 40 p.p.m.</td>
+ </tr><tr class="bb">
+ <td class="tdl"><img src="images/guanine.jpg" alt="" width="200" height="50" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_top bl">&nbsp; No harmful effects</td>
+ </tr><tr>
+ <td class="tdl"><i>l</i>&nbsp; Xanthine</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">No injurious action.</td>
+ </tr><tr class="bb">
+ <td class="tdl"><img src="images/xanthine.jpg" alt="" width="200" height="59" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>m</i>&nbsp; Guanadine,</td>
+ <td class="tdr_wsp bl">9</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1"><b><span class="ws3">&nbsp; NH₂</span><br><span class="ws3">/</span><br>HN : C<br>
+ <span class="ws3">\</span><br><span class="ws3">&nbsp; NH₂</span></b></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl"><i>n</i>&nbsp; Skatol,</td>
+ <td class="tdr_wsp bl">9</td>
+ <td class="tdr_wsp bl">200</td>
+ <td class="tdr_wsp bl">50</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">Roots injured more than tops</td>
+ </tr><tr class="bb">
+ <td class="tdl"><img src="images/skatol.jpg" alt="" width="150" height="53" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl"><span class="pagenum" id="Page_91">[Pg 91]</span></td>
+ </tr><tr>
+ <td class="tdl"><i>o</i>&nbsp; Pyridine,</td>
+ <td class="tdr_wsp bl" rowspan="2">9</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdr_wsp bl" rowspan="2">50</td>
+ <td class="tdr_wsp bl" rowspan="2">....</td>
+ <td class="tdl_wsp bl">In solutions of 50 p.p.m. and less</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1 fs_110"><b>C₅H₅N</b></td>
+ <td class="tdl_wsp bl">the root growth was normal.</td>
+ </tr><tr>
+ <td class="tdl_ws1">Picoline,</td>
+ <td class="tdr_wsp bl" rowspan="2">7</td>
+ <td class="tdr_wsp bl" rowspan="2">1,000</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">100</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1 fs_110"><b>C₅H₄N.CH₃</b></td>
+ </tr><tr>
+ <td class="tdl_ws1">Piperidine</td>
+ <td class="tdr_wsp bl">7</td>
+ <td class="tdr_wsp bl">250</td>
+ <td class="tdr_wsp bl">25</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;&emsp;<img src="images/piperidine.jpg" alt="" width="100" height="109" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl">&emsp;Piperidine (neutralized)</td>
+ <td class="tdr_wsp bl">7</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">25</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl">&emsp;Quinolin,</td>
+ <td class="tdr_wsp bl">6</td>
+ <td class="tdr_wsp bl">500</td>
+ <td class="tdr_wsp bl">5</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;&emsp;<img src="images/quinolin.jpg" alt="" width="100" height="127" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl"><i>p</i>&nbsp; Ricin</td>
+ <td class="tdr_wsp bl">10</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">40</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">Insoluble above 50 p.p.m.</td>
+ </tr><tr class="bb">
+ <td class="tdl"><i>q</i>&nbsp; Mucin</td>
+ <td class="tdr_wsp bl">10</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdc bl"><span class="pagenum" id="Page_92">[Pg 92]</span></td>
+ <td class="tdl_wsp bl">Not tested in concentrations<br>higher than 100 p.p.m.</td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>r</i>&nbsp; Pyrocatechin,</td>
+ <td class="tdr_wsp bl" rowspan="2">12</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">25</td>
+ <td class="tdr_wsp bl" rowspan="2">1</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl fs_110"><b>C₆H₄(OH)₂(1,2)</b></td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>s</i>&nbsp; Arbutin,</td>
+ <td class="tdr_wsp bl" rowspan="2">12</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">25</td>
+ <td class="tdr_wsp bl" rowspan="2">1</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl fs_110"><b>C₁₂H₁₆O₇</b></td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>t</i>&nbsp; Phloroglucin,</td>
+ <td class="tdr_wsp bl" rowspan="2">13</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">25</td>
+ <td class="tdr_wsp bl" rowspan="2">1</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl fs_110"><b>C₆H₃(OH)₃(1,3,5)</b></td>
+ </tr><tr>
+ <td class="tdl"><i>u</i>&nbsp; Vanillin,</td>
+ <td class="tdr_wsp bl">9</td>
+ <td class="tdr_wsp bl">500</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1"><b><span class="ws2">CHO</span><br><span class="ws2">/</span><br>C₆H₃ — O.CH₃<br>
+ <span class="ws2">\</span><br><span class="ws2">OH</span></b></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl_ws1">Vanillic acid,</td>
+ <td class="tdr_wsp bl">7</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">25</td>
+ <td class="tdr_wsp bl">5</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1"><b><span class="ws2">COOH</span><br><span class="ws2">/</span><br>
+ C₆H₃—O.CH₃<br><span class="ws2">\</span><br><span class="ws2">OH</span></b></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>v</i>&nbsp; Quinic acid,</td>
+ <td class="tdr_wsp bl" rowspan="2">10</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">100</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl fs_110"><b>C₆H₇(OH)₄.COOH</b></td>
+ </tr><tr>
+ <td class="tdl"><i>w</i>&nbsp; Quinone,</td>
+ <td class="tdr_wsp bl">9</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;&emsp;<img src="images/quinone.jpg" alt="" width="100" height="67" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>x</i>&nbsp; Cinnamic acid,</td>
+ <td class="tdr_wsp bl" rowspan="2">8</td>
+ <td class="tdr_wsp bl" rowspan="2">100</td>
+ <td class="tdr_wsp bl" rowspan="2">25</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl fs_110"><b>C₆H₅CH : CH.COOH</b></td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1">Sodium cinnamate</td>
+ <td class="tdr_wsp bl">12</td>
+ <td class="tdr_wsp bl">...</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">Roots were stimulated<br>in lower concentrations</td>
+ </tr><tr>
+ <td class="tdl"><i>y</i>&nbsp; Cumarin,</td>
+ <td class="tdr_wsp bl">8</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;&emsp;<img src="images/cumarin.jpg" alt="" width="150" height="77" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl"><span class="pagenum" id="Page_93">[Pg 93]</span></td>
+ </tr><tr>
+ <td class="tdl"><i>z</i>&nbsp; Daphnetin,</td>
+ <td class="tdr_wsp bl">12</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">50</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">Insoluble above 50 p.p.m.</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;&emsp;<img src="images/daphnetin.jpg" alt="" width="150" height="60" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_top bl">&nbsp; Roots somewhat injured</td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>aa</i>&nbsp; Esculin,</td>
+ <td class="tdr_wsp bl" rowspan="2">13</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">1</td>
+ <td class="tdr_wsp bl" rowspan="2">&nbsp;</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1 fs_110"><b>C₁₅H₁₆O₉</b></td>
+ </tr><tr>
+ <td class="tdl"><i>bb</i>&nbsp; Piperonal (heliotropine)—</td>
+ <td class="tdr_wsp bl">7</td>
+ <td class="tdr_wsp bl">100</td>
+ <td class="tdr_wsp bl">1</td>
+ <td class="tdr_wsp bl">...</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;&emsp;<img src="images/piperonal.jpg" alt="" width="150" height="77" ></td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdr_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>cc</i>&nbsp; Borneol,</td>
+ <td class="tdr_wsp bl" rowspan="2">10</td>
+ <td class="tdr_wsp bl" rowspan="2">100</td>
+ <td class="tdr_wsp bl" rowspan="2">1</td>
+ <td class="tdr_wsp bl" rowspan="2">...</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1 fs_110"><b>C₁₀H₁₇(OH)</b></td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>dd</i>&nbsp; Camphor,</td>
+ <td class="tdr_wsp bl" rowspan="2">8</td>
+ <td class="tdr_wsp bl" rowspan="2">300</td>
+ <td class="tdr_wsp bl" rowspan="2">5</td>
+ <td class="tdr_wsp bl" rowspan="2">...</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1 fs_110"><b>C₁₀H₁₆O</b></td>
+ </tr><tr>
+ <td class="tdl fs_110"><i>ee</i>&nbsp; Turpentine,</td>
+ <td class="tdr_wsp bl" rowspan="2">8</td>
+ <td class="tdr_wsp bl" rowspan="2">500</td>
+ <td class="tdr_wsp bl" rowspan="2">10</td>
+ <td class="tdr_wsp bl" rowspan="2">...</td>
+ <td class="tdl_wsp bl" rowspan="2">&nbsp;</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1 fs_110"><b>C₁₀H₁₆</b></td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_94">[Pg 94]</span></p>
+
+<p><i>a.</i> Aspartic acid has been found in young sugar-cane and in
+seedlings of the bean and pumpkin.</p>
+
+<p><i>b.</i> Asparagine was first found in asparagus; but has since been
+shown to be relatively abundant in many species.</p>
+
+<p><i>c.</i> Glycocoll is one of the simpler and more common degradation
+products of proteins.</p>
+
+<p><i>d.</i> Alanine is a common degradation product of proteins and is
+related chemically to phenylalanine, and to tyrosine, which has been
+found in many plants.</p>
+
+<p><i>e.</i> Leucine, an amino-acid of a paraffine series and a
+decomposition product of proteids, has been found in certain mushrooms,
+vetches, lupine, gourds, potatoes, corn, etc.</p>
+
+<p><i>f.</i> Tyrosine is an important decomposition product of proteids,
+is widely distributed and found in many plants and fungi.</p>
+
+<p><i>g.</i> Choline is a derivative of certain lecithins and is found in
+many seeds and growing plants.</p>
+
+<p><i>h.</i> Neurine is a substance closely related to choline, and
+probably formed from it.</p>
+
+<p><i>i.</i> Betaine is closely related to both choline and neurine, and
+is found in many seeds and plants.</p>
+
+<p><i>j.</i> Alloxan is closely related chemically to convicine, which
+latter is found in beets and certain beans.</p>
+
+<p><i>k.</i> Guanine is a widely distributed nitrogenous body, and has
+been found in the seeds of vetch, alfalfa, clover, gourds, barley,
+sugar-beets and sugar-cane.</p>
+
+<p><i>l.</i> Xanthine, a substance closely related to guanine, has been
+found in a number of plants.</p>
+
+<p><i>m.</i> Guanidine, a substance chemically related to guanine, has
+been found in a number of plants of different species.</p>
+
+<p><i>n.</i> Skatol is a derivative of proteids and is a common product of
+the activities of some varieties of bacteria.</p>
+
+<p><i>o.</i> Pyridine has been shown to exist in soils, as such probably,
+by Shorey, who obtained it from certain soils in Hawaii.</p>
+
+<p><i>p.</i> Ricin is found in the castor-oil plant.</p>
+
+<p><i>q.</i> Mucin has been found in yams.</p>
+
+<p><i>r.</i> Pyrocatechin has been found in the bark of various trees, the
+berries of the Virginia creeper, the sap of sugar-beets and in several
+varieties of willows.</p>
+
+<p><i>s.</i> Arbutin has been found in many plants, especially in some of
+the grasses.</p>
+
+<p><i>t.</i> Phloroglucin is easily derived from a number of plant
+constituents.</p>
+
+<p><i>u.</i> Vanillin forms readily from a glucoside, which is very widely
+distributed in many plants, and by some authorities is supposed to be a
+product of the decomposition of wood tissues.
+<span class="pagenum" id="Page_95">[Pg 95]</span></p>
+
+<p><i>v.</i> Quinic acid, which is found with quinine in the cinchona
+bark, also occurs in beet leaves, certain hays, cranberry leaves, and
+occasionally in other plants.</p>
+
+<p><i>w.</i> Quinone has been shown to result from the action of a certain
+fungus, <i>Streptothrix chromogena</i>, common in soils.</p>
+
+<p><i>x.</i> Cinnamic acid is found in certain barks, and forms esters
+which have been found in the leaves of various plants.</p>
+
+<p><i>y.</i> Cumarin has been found in a large number of plants, including
+the grasses, beets, sweet clover, etc.</p>
+
+<p><i>z.</i> Daphnetin occurs in some species of <i>Daphne</i> and is
+closely related to cumarin.</p>
+
+<p><i>aa.</i> Esculin, as well as the corresponding esculetin, has been
+found occasionally in a number of plants.</p>
+
+<p><i>bb.</i> Heliotropine, or piperonal, has the odor of heliotrope and
+is found in flowers.</p>
+
+<p><i>cc.</i> Borneol occurs in needles of different varieties of pine,
+fir, spruce and hemlock, golden rod and thyme.</p>
+
+<p><i>dd.</i> Camphor is closely related chemically to borneol and
+is secreted by a number of plants; it is found in the wood of
+<i>Cinnamomum</i>, cinnamon root, in the leaves of sassafras,
+spikenard, rosemary, rosewood, etc.</p>
+
+<p><i>ee.</i> Turpentine is a constituent of many plants and coniferous
+trees.</p>
+
+<p>Finally, a number of organic substances has been isolated from soils.
+Their composition, and in several cases their constitutions have been
+determined. The effects of these on plants, when they are present
+in the cultural media have been studied. Thus, Shorey&#x2060;<a id="FNanchor_106_106" href="#Footnote_106_106" class="fnanchor">[106]</a>
+was able to isolate picoline carboxylic acid (C₇H₇NO₂) from certain
+soils in Hawaii, and this same substance has since been found in
+several soils of the United States. In aqueous solutions it is quite
+toxic to wheat seedlings. Since then a number of other definite organic
+compounds have been isolated from soils belonging to at least eight
+different classes of organic substances, including:&#x2060;<a id="FNanchor_107_107" href="#Footnote_107_107" class="fnanchor">[107]</a></p>
+
+<table class="spb1">
+ <tbody><tr>
+ <td class="tdl">Hentriacontane,</td>
+ <td class="tdl_ws1 fs_110">C₃₁H₆₄.</td>
+ </tr><tr>
+ <td class="tdl">Monohydroxystearic acid,</td>
+ <td class="tdl_ws1 fs_110">CH₃(CH₂)₆CHOH(CH₂)₉COOH.</td>
+ </tr><tr>
+ <td class="tdl">Dihydroxystearic acid,
+ <span class="pagenum" id="Page_96">[Pg 96]</span></td>
+ <td class="tdl_ws1 fs_110">CH₂(CH₂)₇CHOH.CHOH.(CH₂)₇ COOH.</td>
+ </tr><tr>
+ <td class="tdl">Agroceric acid,</td>
+ <td class="tdl_ws1 fs_110">C₂₁H₄₂O₃.</td>
+ </tr><tr>
+ <td class="tdl">Paraffinic acid,</td>
+ <td class="tdl_ws1 fs_110">C₂₄H₄₈O₂.</td>
+ </tr><tr>
+ <td class="tdl">Lignoceric acid,</td>
+ <td class="tdl_ws1 fs_110">C₂₄H₄₈O₂.</td>
+ </tr><tr>
+ <td class="tdl">Phytosterol,</td>
+ <td class="tdl_ws1 fs_110">C₂₆H₄₄O.H₂O.</td>
+ </tr><tr>
+ <td class="tdl">Pentosan,</td>
+ <td class="tdl_ws1 fs_110">C₅H₈O₄.</td>
+ </tr><tr>
+ <td class="tdl">Agrosterol,</td>
+ <td class="tdl_ws1 fs_110">C₂₆H₄₄O.H₂0.</td>
+ </tr><tr>
+ <td class="tdl">Picoline carboxylic acid,</td>
+ <td class="tdl_ws1 fs_110">C₇H₇O₂N.</td>
+ </tr><tr>
+ <td class="tdl">Histidine,</td>
+ <td class="tdl_ws1 fs_110">C₆H₉O₂N₃.</td>
+ </tr><tr>
+ <td class="tdl">Arginine,</td>
+ <td class="tdl_ws1 fs_110">C₆H₁₄O₂,N₄.</td>
+ </tr><tr>
+ <td class="tdl">Cytosine,</td>
+ <td class="tdl_ws1 fs_110">C₄H₅ON₃.H₂O.</td>
+ </tr><tr>
+ <td class="tdl">Xanthine,</td>
+ <td class="tdl_ws1 fs_110">C₅H₄O₂N₄.</td>
+ </tr><tr>
+ <td class="tdl">Hypoxanthine,</td>
+ <td class="tdl_ws1 fs_110">C₅H₄ON₄.</td>
+ </tr><tr>
+ <td class="tdl" colspan="2">Glycerides, resin acids, etc.</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>Some of these, picoline carboxylic acid, dihydroxystearic acid and
+the pentosan just cited, are toxic to growing plants; others are not.
+The origin and mode of production of these substances in the soil
+is, generally speaking, uncertain and obscure, and is yet one of the
+important fundamental problems confronting the soil chemist.</p>
+
+<p>It is important to note that the organic substances thus far isolated
+from soils are of widely varying types, and with very different
+chemical characteristics. As pointed out above, almost any type of
+organic substance is likely to be found in soils, and the effects
+of any of them on growing plants can hardly be predicted from <i>a
+priori</i> considerations.</p>
+
+<p>It has been found that as a general rule the continued growth of
+one crop in any soil results in a low crop production. Pot cultures
+have given even more pronounced results in the same direction. The
+explanation long accepted is that the soil has, as a result of
+continued cropping, become deficient in some one or more of the
+“available” mineral nutrients. Pot experiments, where the garnered crop
+was returned to the soil and still a diminished yield was obtained,
+throw doubt on this explanation. Still further doubt results from
+water-cultures which, by growing a crop in them, become “poor” for
+<span class="pagenum" id="Page_97">[Pg 97]</span>
+subsequent crops, although there is maintained in them an ample supply
+of mineral plant nutrients, and they are easily renovated by good
+absorbers. These facts find a more satisfactory explanation as being
+due to the production in the nutrient medium of deleterious organic
+substances originating in the growing plant itself. This idea seems
+to have been advanced first by De Candolle, in 1832,&#x2060;<a id="FNanchor_108_108" href="#Footnote_108_108" class="fnanchor">[108]</a>
+to account for the beneficial results obtained by employing a rotation
+of crops. It appears to have been held by Liebig at one time, although
+he subsequently abandoned it in favor of the view that the benefits
+of a crop rotation are due to the several crops requiring different
+proportions of mineral nutrients, and that the disturbance of the
+balance in the soil produced by one crop is not unfavorable to the
+growth of some other crop. Although lacking direct experimental
+confirmation, this latter view of Liebig’s has long prevailed among
+agricultural investigators, partly by reason of his authority, partly
+by reason of the dominance of the plant-food theory of fertilizers,
+and partly by reason of the fact that the ideas of De Candolle as
+originally advanced included certain errors soon detected. The trend of
+recent investigations has been distinctly in favor of a modified form
+of the view of De Candolle. It has been recognized that other factors
+enter into crop rotations, such as the elimination of associated weeds,
+various kinds of animal, insect and plant parasites, preparation of
+the soil by a deep-rooted crop for a shallow-rooted following crop,
+etc. It has come to be recognized that there are natural associations
+of plants, and natural rotations of vegetation certainly determined
+by other than plant food factors. Thus, in the eastern United States,
+wheat is followed by ragweed naturally, while across the fence
+cocklebur and wild sunflower come in after the corn, the difference
+in vegetation being as sharply marked after the removal of the crops
+as when they still occupied the land. Analyses of the ragweed, for
+instance, although it is a shallower rooted crop than wheat, show that
+<span class="pagenum" id="Page_98">[Pg 98]</span>
+it takes from the soil as much of the mineral nutrients as does the
+preceding&#x2060;<a id="FNanchor_109_109" href="#Footnote_109_109" class="fnanchor">[109]</a>
+wheat crop. The investigation of Lawes and Gilbert&#x2060;<a id="FNanchor_110_110" href="#Footnote_110_110" class="fnanchor">[110]</a>
+on fairy rings showed that the continual widening of the rings can not be
+satisfactorily explained by the comparison of the mineral constituents
+in the soil within and without the rings. Work at Woburn&#x2060;<a id="FNanchor_111_111" href="#Footnote_111_111" class="fnanchor">[111]</a>
+on the effect of grass on apple trees finds no other plausible explanation
+than that the growing grass produces in the soil organic substances
+detrimental to young apple trees. A number of similar cases have been
+recorded.</p>
+
+<p><span class="pagenum" id="Page_99">[Pg 99]</span></p>
+
+<p>Finally, although less work has been done in this direction with higher
+plants than with other organisms, it is now recognized as a general law
+of all living organisms that they function less readily as the products
+of their activities accumulate.&#x2060;<a id="FNanchor_112_112" href="#Footnote_112_112" class="fnanchor">[112]</a>
+These products may, however, be
+inimical, neutral or even stimulating to other organisms.</p>
+
+<p><span class="pagenum" id="Page_100">[Pg 100]</span>
+This problem has been investigated critically by direct
+experimentation, growing wheat, and other seedlings in water and agar
+cultures.&#x2060;<a id="FNanchor_113_113" href="#Footnote_113_113" class="fnanchor">[113]</a>
+It has been shown that wheat renders the culture media
+unsuitable for subsequent wheat crops, though it can be reclaimed or
+renovated by treatment with such absorbents as carbon black, or by
+other methods.&#x2060;<a id="FNanchor_114_114" href="#Footnote_114_114" class="fnanchor">[114]</a>
+Wheat did about as well when grown in a medium which
+had previously supported a growth of cowpeas as when planted in a fresh
+medium; poorer results were obtained after oats; no crop produced such
+poor results in the succeeding wheat crop as did wheat itself.</p>
+
+<p>It is yet a matter of dispute as to whether the substances thus added
+to nutrient media are truly excretory products of the plant, sloughed
+off or otherwise eliminated from the surface of the roots, or further
+elaborated by bacterial or other agencies before becoming effective.
+These are important problems for the plant physiologist and the soil
+chemist alike. It is beyond dispute, however, by reason of a large and
+increasing weight of evidence, much of it direct experiment, that, as
+a result of the growing of plants, soils and the soil water do contain
+organic substances; harmful to the plant or organism eliminating them;
+harmful, innocuous, or even stimulating to other plants or organisms.</p>
+
+<p>For the elimination from the soil of toxic or inhibitory organic
+substances, whether excreted by roots or otherwise produced, several
+methods are more or less effective. When, as is sometimes the case,
+the substance is volatile, it may be removed by heating, distilling
+with steam, or passing a current of air through the soil or cultural
+medium. These methods, while effective in the laboratory and possibly
+applicable to greenhouse conditions, are naturally inapplicable to
+field conditions. In this last case the obvious procedure is to
+increase as much as possible the absorptive powers of the soil; to
+secure the best possible drainage; and with these, the best possible
+aeration of the soil.
+<span class="pagenum" id="Page_101">[Pg 101]</span></p>
+
+<p>It has been found that, in general, a cultural medium which has
+been rendered unfit for the continued growth of a crop, is readily
+renovated by treatment with oxidizing agents, and is sometimes rendered
+even better than ever by such treatment, which would suggest that
+the oxidation products from plant effluvia may be even beneficial
+to the plant. To this end the growing plant seems itself to be an
+active agent, apparently attempting automatically to protect itself
+against the products of its own activities. It has been pointed out by
+Molisch&#x2060;<a id="FNanchor_115_115" href="#Footnote_115_115" class="fnanchor">[115]</a>
+that root secretions have an oxidizing power, apparently of
+an enzymotic character. Some doubt of the validity of Molisch’s work
+has been raised by Czapek, Pfeffer, and others; nevertheless it is now
+accepted that while intercellular autoxidation or reduction processes
+may take place in living roots, the higher plants, such as our common
+crop plants, also show a more or less well-developed extracellular
+oxidizing power in the neighborhood of the root tips and root hairs.&#x2060;<a id="FNanchor_116_116" href="#Footnote_116_116" class="fnanchor">[116]</a>
+That this oxidizing power displayed by growing roots is enzymotic is
+indicated by the fact that artificial culture media frequently display
+it also after plants have been grown in them for a short while.&#x2060;<a id="FNanchor_117_117" href="#Footnote_117_117" class="fnanchor">[117]</a></p>
+
+<p>It has been shown that the oxidizing action of growing roots is
+<span class="pagenum" id="Page_102">[Pg 102]</span>
+generally promoted by having the cultural medium slightly alkaline
+or neutral rather than acid. It is also promoted by the addition
+of various mineral salts, notably by nitrates, phosphates, or
+lime salts. Potassium salts promote the oxidation but slightly,
+and in some experiments have even produced a slight decrease. The
+corresponding sodium and ammonium salts are more favorable than those
+of potassium.&#x2060;<a id="FNanchor_118_118" href="#Footnote_118_118" class="fnanchor">[118]</a>
+It appears altogether probable, therefore, that the
+mineral salts in commercial fertilizers may have some importance in
+this connection.</p>
+
+<p>Whatever may be the role of mineral fertilizers towards organic
+substances toxic to growing plants, it is certain that they have
+an importance and one that is probably specific, as indicated by
+some recent investigations.&#x2060;<a id="FNanchor_119_119" href="#Footnote_119_119" class="fnanchor">[119]</a>
+Culture solutions containing the constituents potassium, nitric acid
+and phosphoric acid were prepared in such manner that they covered the
+range of all possible ratios of these constituents in intervals of
+ten per cent. in each. Into one set of these solutions was introduced
+dihydroxystearic acid, into another set cumarin, and into a third
+set, vanillin, and into a fourth set, quinone. The growth of wheat
+seedlings in these several sets showed indubitably that these several
+organic substances which are all deterrent to the growth of wheat,
+were modified in their influence by the presence of the mineral salts;
+but that nitrates were more efficient than the other minerals in the
+case of the solutions containing dihydroxystearic acid or vanillin;
+phosphates were most efficient in the case of the solutions containing
+cumarin, and potassium most efficient in solutions containing quinone.
+As the organic substances used in these experiments, either in
+themselves or as typifying classes of compounds, may be anticipated
+in soils under natural conditions, it is again apparent that mineral
+fertilizers have a function in addition to the traditional one of
+increasing the supply of mineral nutrients.</p>
+
+<p>The fact that the oxidizing power of roots is more marked when grown
+in aqueous extracts of soils in good tilth than in extracts made from
+<span class="pagenum" id="Page_103">[Pg 103]</span>
+soils in poor tilth, shows that cultural methods are no less important
+in field practice than are fertilizers in promoting this important
+activity of plants. There is little reason to doubt that oxidizing
+agencies other than plant roots (bacterial for instance) are more or
+less active in every arable soil, and numerous investigations, among
+which Russell’s researches&#x2060;<a id="FNanchor_120_120" href="#Footnote_120_120" class="fnanchor">[120]</a>
+are conspicuous, leave little doubt that oxidation processes are
+promoted by good tilth. It is apparent, therefore, that by the
+activities of the plant itself as well as other agencies, the general
+tendency in soils is the destruction of or rendering innocuous
+harmful plant effluvia or other organic substances, and to this end
+are effective each of the three methods of soil control generally
+practiced, namely, tillage, crop rotation and fertilizers.</p>
+
+<p>Among the organic components of the soil none have greater importance
+and interest than those containing nitrogen or as they are frequently
+called the nitrogen carriers. Conspicuous among these are the nitrates.
+While it is now generally conceded that ammonia and other nitrogen
+compounds can be taken up by higher plants and elaborated by them under
+special conditions, it nevertheless remains true that plants draw their
+needed supplies of nitrogen from the soil solution, mainly in the
+form of nitrates. The problems presented by these nitrogen carriers
+are mainly bacterial&#x2060;<a id="FNanchor_121_121" href="#Footnote_121_121" class="fnanchor">[121]</a>
+and physiological, but certain features are of direct importance to
+the soil chemist and to a study of the soil solution. It is now known
+generally that there are many kinds of nitrifying and denitrifying
+bacteria in soils, and that probably every arable soil contains several
+species, or varieties at least of both kinds. With good tilth and
+<span class="pagenum" id="Page_104">[Pg 104]</span>
+consequent aerobic conditions, nitrifying processes prevail, and with
+poor tilth or in subsoils, anaerobic conditions and denitrifying
+processes prevail. Warmth, moisture, the reaction of the soil, and
+perhaps other factors markedly affect the activity of the organisms
+of the soil solution. Another important factor is that the absorptive
+powers of the higher plants are markedly affected by sunlight, so
+that, especially on bright and clear days, there is generally a higher
+concentration of nitrates in the soil solution in the morning than in
+the evening. This fact would seem to affect seriously the value of
+some recent and extensive investigations where it has been sought to
+classify soils by their content of water-dissolved nitrates. Nitric
+acid is more readily leached from soils than are most other acid
+radicals. Consequently nitrates, like other organic components of the
+soil solution, and unlike inorganic components, tend to vary greatly in
+concentration.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_105">[Pg 105]</span></p>
+<h2 class="nobreak">Chapter XII.<br><span class="h_subtitle">FERTILIZERS.</span></h2>
+</div>
+
+<p>It is generally recognized that the great practical problem confronting
+the soil chemist is the proper use of soil amendments or fertilizers.
+The farmers of the United States now spend annually for fertilizers
+upwards of $100,000,000. It is estimated by various authorities that
+a large fraction, perhaps as much as three-fourths, of the material
+represented by this expenditure is misapplied for lack of intelligent
+direction. Yet all of this enormous mass of fertilizers can be used
+to advantage. Great as it is, it is relatively small beside the total
+which will, and must, be used in a not distant future, with the growth
+and development of intensive methods of cultivation consequent upon
+the rapid settling of the country, the practical disappearance of new
+lands and the increase in money value of the old lands. The commercial
+importance of the problem, therefore, makes it desirable that special
+emphasis should be given to fertilizers from the point of view
+developed in the preceding chapters. It should be recalled that the use
+of fertilizers constitutes one of the three great general methods of
+soil control, and further that while tillage methods, crop rotations,
+and fertilizer applications can be used to supplement one another, no
+one of these methods can be expected to take satisfactorily the place
+of another.</p>
+
+<p>Crop production is dependent upon a large number of factors. Upon the
+rainfall, both as to the amount and distribution; upon the sunlight, as
+to amount and distribution; upon the chemical and physical properties
+of the soil; soil bacteria and other biologic agents; enzymes in the
+soil; biological factors in the plant, and probably many other things.
+Opinions do and will continue to differ as to what these factors are,
+but at least every one agrees that they are many.</p>
+
+<p>Attempting to formulate these factors develops fundamental
+difficulties, since it is not positively known how far the variables
+are dependent or independent, and we have no idea as to the nature of
+<span class="pagenum" id="Page_106">[Pg 106]</span>
+the function or functions. The weight of existing evidence favors the
+view that all the factors are dependent variables, although numerous
+attempts have been made from time to time to show that some one factor,
+such as the rainfall for instance, or the mean annual temperature, or
+available plant-food, is <i>practically</i> an independent factor.
+Although it should be rather easy to determine experimentally
+the nature of the function, if any of these various factors were
+independent, this has never been done, and this fact is itself a strong
+argument that all the factors in crop production are dependent on one
+another.</p>
+
+<p>When there is introduced into the equation a factor for any one of
+the methods of soil control, <i>i. e.</i>, tillage, crop rotation,
+or fertilizers, it becomes even more apparent that the function is
+determined by dependent variables, for the new factor always more or
+less affects several if not all of those already cited. For instance,
+fertilizers certainly affect the chemical properties of the soil, its
+physical properties, the soil bacteria, perhaps the plant-food supply,
+the oxidation of plant effluvia and other factors. It is obvious,
+therefore, that a satisfactory theory of fertilizer action can not be a
+simple one but must of necessity be complex; and the same statement is
+no less true as regards tillage and crop rotation.</p>
+
+<p>The recognition of the fact that the action of fertilizers is a complex
+function depending upon many factors and groups of factors which vary
+among themselves and with each individual soil, carries with it the
+conviction that an exact or quantitative fertilizer practice, while
+theoretically possible, is probably unattainable since methods for the
+solution of such complex functions are generally wanting. It is not
+surprising, therefore, that the empirical experience of the past has
+failed to develop a quantitative practice. However disappointing this
+may seem at first sight, the prospect is not altogether hopeless, for
+this point of view indicates a systematic scheme for experimentally
+determining a qualitative, but nevertheless rational, fertilizer
+practice. The dominance of the plant-food theory of fertilizers in
+the past, shutting off, as it has, a rational attack of the problem,
+is causing the annual waste of millions of dollars in misapplied
+fertilizers, and it is of scarcely less economic than scientific
+<span class="pagenum" id="Page_107">[Pg 107]</span>
+importance to investigate and extend our knowledge of the effect of
+soil amendments upon the many factors in crop production. With a
+knowledge of the effect of fertilizers upon the physical, chemical
+and biological factors in crop production, and of the nature of the
+interdependence of these factors, will come the ability to manage
+intelligently the individual field for the particular crop. This
+knowledge can only come by attacking the problem from the dynamic
+viewpoint, and so far as the soil factors are concerned, they can
+apparently be studied best as they affect the properties of the soil
+solution.</p>
+
+<p>While it seems certain that some fertilizer effects are directly upon
+the soil and secondarily upon the plants, it cannot be doubted that in
+others, the phenomena are more directly concerned with the absorption
+by and the metabolism within the plant and until these plant processes
+are better understood, nothing approaching a satisfactory practice can
+be anticipated. Why and how plants exercise the selective powers they
+appear to possess are fundamental questions yet to be answered. The
+important effects sometimes produced by adding to the nutrient medium
+such substances as manganese salts which are not necessary to the
+growth of the plant, can no more be neglected than the study of the
+phosphorus needs. The presence in the soil universally of substances
+other than the recognized mineral nutrients,&#x2060;<a id="FNanchor_122_122" href="#Footnote_122_122" class="fnanchor">[122]</a>
+may very well have a significance for plant production hitherto
+unsuspected, for the fact that an organism can continue to function
+in the absence of a substance is no argument, much less proof, that
+it would not function better with that substance present. Recent
+investigations, showing that animal organisms are sometimes more
+resistant to certain toxins and diseases under starvation conditions or
+when ingesting substances unnecessary to normal development, suggest
+the possibility at least of similar phenomena with plants. It is at any
+rate clear that the practical problem of the best production of plants
+from soils is not merely one of providing a relatively large supply of
+potassium, phosphorus and nitrogen.
+<span class="pagenum" id="Page_108">[Pg 108]</span></p>
+
+<p>In this connection it is well to consider what constitutes a commercial
+fertilizer. It must be a substance the addition of which either
+directly or indirectly affects the properties of the soil or the
+growing plant; it must be obtainable in large quantities and from a
+source or sources of supply not readily exhausted; and it must be
+cheap. Of the many substances filling the first condition, all those
+which fulfill also the other conditions are used as fertilizers, with
+the exception of common salt and human excrement. In spite of the fact
+that it does not contain a conventional plant-food, sodium chloride
+appears to produce results quite similar to those produced by the usual
+fertilizer salts. Its use has been followed generally by an increased
+yield of crop, but occasionally by a decreased one, and it appears not
+improbable that further investigation would show sodium chloride to
+have a considerable value as a fertilizer. Human excrement or night
+soil, and the sewage and garbage refuse of our large cities are not
+commercial fertilizers, although having undoubtedly a high agricultural
+value. Objection has been urged to them that they are “filthy” and
+liable to contain dangerous pathogenic organisms. Both objections could
+be met. It seems a more rational explanation that the agricultural
+methods of this country have not yet become sufficiently intensive to
+necessitate the conservation of such materials or to justify their
+commercial exploitation.</p>
+
+<p>New products will come into use from time to time, as in the case of
+calcium cyanamid and basic calcium nitrate. But it is worthy of note
+that these substances have become available not so much because of
+their agricultural value, but incidentally to the efforts of inventors
+and manufacturers to produce cheap nitric acid for the preparation of
+<span class="pagenum" id="Page_109">[Pg 109]</span>
+high explosives.&#x2060;<a id="FNanchor_123_123" href="#Footnote_123_123" class="fnanchor">[123]</a>
+There seems no reason to doubt that an ample supply of desirable
+substances will always be available for fertilizer purposes. The
+immediate practical problem for the future is not the seeking of new
+fertilizers but the rational use of those at hand.</p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum" id="Page_110">[Pg 110]</span></p>
+ <h2 class="nobreak">Chapter XIII.<span class="h_subtitle">ALKALI.</span></h2>
+</div>
+
+<p>In the preceding chapters there have been considered the phenomena
+which obtain under humid conditions. Under exceptional conditions of
+prolonged drought there occurs an accumulation of soluble mineral
+substances at or near the surface of the soil. This phenomenon is
+pronounced in arid and semi-arid regions,&#x2060;<a id="FNanchor_124_124" href="#Footnote_124_124" class="fnanchor">[124]</a>
+and the accumulations of soluble salts occurring in such regions is
+known in the United States as “alkali,” in India as “reh,” in Africa as
+“brak,” and in other countries by various local designations. The study
+of the extreme conditions producing alkali has added materially to the
+present knowledge of the processes taking place in soil of humid areas.
+Moreover, alkali-infested areas are themselves becoming of so much
+importance with the growing needs for further new lands, that it seems
+wise to give here an outline of the chemical principles involved in
+their soil solutions.&#x2060;<a id="FNanchor_125_125" href="#Footnote_125_125" class="fnanchor">[125]</a></p>
+
+<p>Alkali is sometimes a single salt, but usually a mixture of some
+two or more of the chlorides, sulphates, carbonates, bicarbonates,
+and occasionally the nitrates, phosphates and borates, of sodium,
+magnesium, potassium, and calcium, and occasionally strontium and
+lithium. In the United States, when the carbonate of sodium is present
+to an appreciable extent, the salt mixture is known as <i>black
+alkali,</i> in contradistinction to <i>white alkali</i>, which latter
+does not contain sodium carbonate.&#x2060;<a id="FNanchor_126_126" href="#Footnote_126_126" class="fnanchor">[126]</a>
+<span class="pagenum" id="Page_111">[Pg 111]</span>
+Generally, but not always, soils containing alkali also contain
+accumulations of the less soluble salts, calcium carbonate, or calcium
+sulphate, or a mixture of the two. These substances, sometimes
+cementing the less soluble mineral components of the soil, sometimes
+almost pure, are found in layers more or less continuous, and from
+a fraction of an inch to several feet in thickness, in a position
+approximately parallel to and at a moderate depth below the surface of
+the soil. In such cases these layers form a “hard-pan” and frequently
+the treatment of this type of hard-pan is the most difficult and vexing
+problem in the management of alkali-bearing soils.</p>
+
+<p>The origin of alkali is often uncertain. In some cases the geological
+evidences in the area make it certain that the alkali came from the
+desiccation of former bodies of sea water which had become isolated
+from the ocean. In other cases the alkali appears to come from the
+desiccation of lakes which are the depositories of the drainage of a
+surrounding area, and which have no outlet to the sea. In still other
+cases it has been supposed that the alkali is derived from wind-borne
+sea-spray. Various explanations of a more or less special character
+with regard to particular localities or circumstances are to be found
+in the literature.&#x2060;<a id="FNanchor_127_127" href="#Footnote_127_127" class="fnanchor">[127]</a></p>
+
+<p>The chemical principles involved in the desiccation of a body of
+sea water are now pretty well understood, owing mainly to the
+investigations of van’t Hoff, Meyerhoffer, and their coworkers.&#x2060;<a id="FNanchor_128_128" href="#Footnote_128_128" class="fnanchor">[128]</a>
+The salts in sea water and those constituting “white alkali” are mainly the
+<span class="pagenum" id="Page_112">[Pg 112]</span>
+chlorides and sulphates of sodium, potassium and magnesium. Calcium
+is also present, appearing in deep deposits as anhydrite, and at the
+surface as gypsum.</p>
+
+<p>From the results of this work it is possible to predict the order
+in which the different salts or minerals will separate from the
+evaporating solution. At ordinary temperature (25° C) the first
+salt to be deposited from the dilute solution is <i>gypsum</i>
+(CaSO₄.2H₂O) followed by <i>halite</i> or <i>sodium chloride</i> (NaCl)
+in quantity. Sodium chloride continues to separate at all higher
+concentrations. Next will be deposited <i>kainite</i> (MgSO₄KCl.3H₂O).
+At the concentration then reached, the stable sulphate of calcium is
+<i>anhydrite</i> (CaSO₄), which continues to separate from solution as
+desiccation proceeds. Consequently, if the gypsum previously deposited
+is yet in contact with the solution, it tends to be transformed to
+anhydrite and at all higher concentrations the deposition of anhydrite
+may be expected. As evaporation proceeds a point is reached where
+<i>kainite</i> and <i>kieserite</i> (MgSO₄.H₂O) separate. Further
+evaporation brings a concentration at which <i>kieserite</i> and
+<i>carnallite</i> (MgCl₂.KCl.6H₂O) are precipitated, and as the
+process proceeds, finally the point is reached where <i>kieserite</i>,
+<i>carnallite</i> and <i>bischofite</i> (MgCl₂.6H₂O) all three
+separate with sodium chloride. The final products separating at a
+higher temperature, 83° C., are the same four solids, sodium chloride,
+kieserite, carnallite and bischofite.&#x2060;<a id="FNanchor_129_129" href="#Footnote_129_129" class="fnanchor">[129]</a>
+The alternate layers of anhydrite and sodium chloride noticeable in
+some desiccated sea beds is probably the result of alterations in
+<span class="pagenum" id="Page_113">[Pg 113]</span>
+temperature, anhydrite being less soluble, and sodium chloride somewhat
+more soluble in hot than in cold water. During warm weather there would
+be a greater tendency for anhydrite to separate and in colder weather
+for sodium chloride to be precipitated. Anhydrite at the surface would
+gradually absorb water vapor from the atmosphere and be transformed to
+gypsum.&#x2060;<a id="FNanchor_130_130" href="#Footnote_130_130" class="fnanchor">[130]</a></p>
+
+<p>Besides the principal salts just described, there may separate
+at one concentration or another other various double salts
+including <i>langbeinite</i> (2MgSO₄.K₂SO₄), <i>polyhalite</i>
+(K₂SO₄.MgSO₄.2CaSO₄.2H₂O), <i>glauberite</i> (CaSO₄.Na₂SO₄),
+<i>syngenite</i> (CaSO₄.K₂SO₄.H₂O), <i>potassium pentasulphate</i>
+(K₂SO₄.5CaSO₄.H₂O), <i>krugite</i> (4CaSO₄.K₂SO₄.MgSO₄.2H₂O), and
+possibly others. These are all stable over very restricted ranges of
+concentration, however, and if formed, probably seldom persist, but
+pass over to more stable salts as the desiccation proceeds, and have
+little more than a passing theoretical interest.</p>
+
+<p>The addition of carbonates to the system introduces some further
+modifications.&#x2060;<a id="FNanchor_131_131" href="#Footnote_131_131" class="fnanchor">[131]</a>
+In this case lime carbonate is the first salt to
+be precipitated, followed probably by the same order of deposition
+as outlined above. As the mother liquor becomes more concentrated,
+it apparently loses its alkaline character, for the addition of
+an alcoholic solution of phenolphthalein does not produce the
+characteristic red color. That the solution does actually contain
+dissolved carbonates is shown by the appearance of the red color on
+diluting a portion of the mother liquor with distilled water. An
+interesting example in nature is furnished by the Great Salt Lake,
+Utah. A test of the water of this lake in 1899 gave no alkaline
+<span class="pagenum" id="Page_114">[Pg 114]</span>
+reaction with phenolphthalein, but the reaction appeared promptly when
+distilled water was added, and further examination showed the water to
+contain about 0.012 per cent. sodium carbonate.&#x2060;<a id="FNanchor_132_132" href="#Footnote_132_132" class="fnanchor">[132]</a>
+Slosson has reported similar cases in Wyoming.&#x2060;<a id="FNanchor_133_133" href="#Footnote_133_133" class="fnanchor">[133]</a></p>
+
+<p>One “black alkali” system has been studied with some approach towards
+completeness.&#x2060;<a id="FNanchor_134_134" href="#Footnote_134_134" class="fnanchor">[134]</a>
+In this case magnesium and potassium salts are not
+present, the system being composed of water, carbon dioxide, chlorides,
+sulphates, sodium and calcium salts, with the condition imposed, that
+the bases are present in amounts more than equivalent to the sulphuric
+and hydrochloric acids. On desiccation at 25° C calcium carbonate first
+appears followed by gypsum and then sodium sulphate decahydrate. Next
+appears a double salt (2CaSO₄.3Na₂SO₄) followed by anhydrous sodium
+sulphate, the Glauber’s salt which formerly crystallized being no
+longer stable. Sodium chloride then precipitates and the concentration
+finally reaches a point where gypsum is no longer stable, and the
+final group of salts in contact with the evaporating solution under
+conditions of stable equilibrium consists of calcium carbonate, the
+double sulphate of soda and lime, anhydrous sodium sulphate and sodium chloride.</p>
+
+<p>The desiccation of a lake which serves as the final repository of a
+regional drainage involves essentially the principles just discussed.&#x2060;<a id="FNanchor_135_135" href="#Footnote_135_135" class="fnanchor">[135]</a>
+<span class="pagenum" id="Page_115">[Pg 115]</span>
+The constituents involved are the same. A serious problem involved
+in the consideration of this source of “alkali” is the high ratio of
+chlorine to the other constituents, in view of its very low ratio in
+the rocks from which it comes. The explanation undoubtedly involves the
+fact that the carbonates and sulphates are constantly being removed as
+calcium salts from a body of water which is more or less continuously
+receiving the drainage of any considerable watershed, and is at the
+same time subject to a relatively high rate of evaporation. The
+chlorine forming only very soluble salts under such conditions would
+be segregated and concentrated in the residual mother liquor. Most
+difficult is it to account for the relatively high ratio of sodium to
+potassium in alkali from such an origin. Some light is thrown on the
+subject by the progressive changes in concentration of a lake water
+which receives a regional drainage under arid conditions. To this end
+are given the following results of analyses of the waters of Utah Lake,
+made at different times&#x2060;<a id="FNanchor_136_136" href="#Footnote_136_136" class="fnanchor">[136]</a>
+over an interval of twenty years, and showing that there is a
+segregation of chlorine and sodium taking place, although in this case
+the lake has an outlet in the Jordan River.</p>
+
+<p class="f120"><b><span class="smcap">Analyses of the Water of Utah Lake.<br>
+Results in Parts per Million</span></b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc">&nbsp;</th>
+ <th class="tdc bl">&nbsp;Clarke&nbsp;<br>1883</th>
+ <th class="tdc bl">&nbsp;Cameron&nbsp;<br>1899</th>
+ <th class="tdc bl">&nbsp;Brown&nbsp;<br>1903</th>
+ <th class="tdc bl">Seidell<br>1904&#x2060;<a id="FNanchor_137_137" href="#Footnote_137_137" class="fnanchor">[137]</a></th>
+ <th class="tdc bl">Brown<br>1904&#x2060;<a id="FNanchor_138_138" href="#Footnote_138_138" class="fnanchor">[138]</a></th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">Ca</td>
+ <td class="tdr_wsp bl">55.8</td>
+ <td class="tdr_wsp bl">67.6</td>
+ <td class="tdr_wsp bl">80</td>
+ <td class="tdr_wsp bl">67.7</td>
+ <td class="tdr_wsp bl">67</td>
+ </tr><tr>
+ <td class="tdl">Sr</td>
+ <td class="tdc bl">—</td>
+ <td class="tdr_wsp bl">1.7</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ </tr><tr>
+ <td class="tdl">Mg</td>
+ <td class="tdr_wsp bl">18.6</td>
+ <td class="tdr_wsp bl">13.8</td>
+ <td class="tdr_wsp bl">92</td>
+ <td class="tdr_wsp bl">73.5</td>
+ <td class="tdr_wsp bl">86</td>
+ </tr><tr class="bt">
+ <td class="tdl">Na</td>
+ <td class="tdr_wsp bl">17.7</td>
+ <td class="tdr_wsp bl">233.7</td>
+ <td class="tdr_wsp bl">247</td>
+ <td class="tdr_wsp bl">207.2</td>
+ <td class="tdr_wsp bl">230</td>
+ </tr><tr class="bb">
+ <td class="tdl">K</td>
+ <td class="tdc bl">?</td>
+ <td class="tdc bl">?</td>
+ <td class="tdr_wsp bl">30</td>
+ <td class="tdr_wsp bl">25.8</td>
+ <td class="tdr_wsp bl">22</td>
+ </tr><tr>
+ <td class="tdl">Li</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdr_wsp bl">0.7</td>
+ <td class="tdr_wsp bl">—</td>
+ </tr><tr>
+ <td class="tdl">SO₄</td>
+ <td class="tdr_wsp bl">130.6</td>
+ <td class="tdr_wsp bl">236.7</td>
+ <td class="tdr_wsp bl">365</td>
+ <td class="tdr_wsp bl">332.9</td>
+ <td class="tdr_wsp bl">378</td>
+ </tr><tr>
+ <td class="tdl">Cl</td>
+ <td class="tdr_wsp bl">12.4</td>
+ <td class="tdr_wsp bl">316.5</td>
+ <td class="tdr_wsp bl">336</td>
+ <td class="tdr_wsp bl">288.5</td>
+ <td class="tdr_wsp bl">337</td>
+ </tr><tr>
+ <td class="tdl">HCO₃</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdr_wsp bl">266</td>
+ <td class="tdr_wsp bl">205.5</td>
+ <td class="tdr_wsp bl">194</td>
+ </tr><tr>
+ <td class="tdl">CO₃</td>
+ <td class="tdr_wsp bl">60.9</td>
+ <td class="tdr_wsp bl">23.7</td>
+ <td class="tdc bl">—</td>
+ <td class="tdr_wsp bl">24.0</td>
+ <td class="tdr_wsp bl">11</td>
+ </tr><tr class="bb">
+ <td class="tdl">SiO₂</td>
+ <td class="tdr_wsp bl">10.0</td>
+ <td class="tdc bl">—</td>
+ <td class="tdc bl">—</td>
+ <td class="tdr_wsp bl">22.6</td>
+ <td class="tdr_wsp bl">28</td>
+ </tr><tr class="bb">
+ <td class="tdl_ws1">Total&emsp;&nbsp;</td>
+ <td class="tdr_wsp bl">306.0</td>
+ <td class="tdr_wsp bl">892.0</td>
+ <td class="tdr_wsp bl">1416</td>
+ <td class="tdr_wsp bl">1250.1</td>
+ <td class="tdr_wsp bl">1353</td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_116">[Pg 116]</span>
+The third general origin of alkali supposes that wind-borne sea-spray
+carries into the air salts which are left in very fine particles on the
+evaporation of the water, or are deposited on the ordinary atmospheric
+dust and carried over the land; and that this dust is precipitated here
+and there as may be determined by the various meteorological conditions
+which it encounters. All the land surface is supposed to be receiving
+more or less of it from time to time, but in arid regions the rainfall
+and drainage is not sufficient to return to the sea as much as is
+received therefrom.&#x2060;<a id="FNanchor_139_139" href="#Footnote_139_139" class="fnanchor">[139]</a></p>
+
+<p>It is very probable that wind-borne salts from the sea are being
+carried over and to some extent being deposited on all the land
+surfaces of the earth. To what extent this process is taking place, and
+whether it is sufficient to account for the alkali of any particular
+region, available data fail to answer satisfactorily. Probably it is
+always associated with one of the origins of alkali already discussed
+and is in itself generally of secondary importance.</p>
+
+<p>An argument frequently advanced against the validity of the hypothesis
+that wind-borne sea-spray is the origin of alkali is that the relative
+proportions of the several constituents in “alkali” are seldom if
+ever those obtaining in sea water. This argument does not take into
+consideration, however, that the several salts in the spray probably
+separate into crystals of widely different size and specific gravities,
+and there may well be taking place a selective or sorting action by
+the wind. More important, undoubtedly, is the selective action taking
+place in the soil itself; it can only be an accidental coincidence
+that the constituents of alkali in any particular occurrence should
+have the same quantitative relations as in the material from which it
+originated, no matter what may have been the nature of its origin.</p>
+
+<p>In the field, alkali is found in a bewildering array of forms and
+types. Quite different combinations of constituents may be found in the
+<span class="pagenum" id="Page_117">[Pg 117]</span>
+same field within a few rods or even a few feet, and each case appears
+to have a distinct origin, to be in fact a law unto itself. Each
+alkali deposit represents generally the resultant from a mixture of
+salt which has been dissolved and reprecipitated a number of times,
+and which while dissolved has been seeping through the soil under
+gravitational forces, or has been moving through the soil as film
+water under capillary stresses. In either event the salt mixture has
+been subject to the power for selective absorption peculiar to the
+particular soil mass through which it has been moving. Re-solution
+is seldom an instantaneous process, and different rates of solution
+necessarily involve some separation of salts. Finally the alkali
+deposit is usually so mixed with other soil material that there cannot
+be recognized the characteristic solid phases (such, for instance,
+as the double sulphates of calcium and another base) which serve
+as guides in laboratory studies and in certain salt mines. Even if
+the characteristic salts are deposited in surface soils, it is very
+doubtful, owing to their hygroscopicity, if any but gypsum, halite and
+Glauber’s salt can persist for any length of time. The alternations
+of temperature from night to day characteristic of arid regions, with
+precipitation of dews, might easily be expected to make noticeable
+and rapid changes in the characteristics of any given alkali or salt
+mixture.</p>
+
+<p>It is not surprising, therefore, that attempts to account for the
+genesis and present appearance of an alkali deposit by comparison
+with artificial depositions of salt mixtures, as worked out in the
+laboratory, have generally been disappointing. On the other hand,
+laboratory studies have been quite fruitful in elucidating the
+phenomena taking place on the leaching of alkali from a soil, or
+so-called “alkali reclamation.”</p>
+
+<p>Whatever the origin of the alkali, its segregation at or near the
+surface of the soil is everywhere much the same; that is, there is a
+translocation and segregation of soluble salts in the below-surface
+seepage waters, determined mainly by the topographic features, but
+partly by the texture and structural properties of the soil and
+subsoil, with a subsequent rise as capillary water consequent upon
+evaporation at the surface. Precipitation of the solutes may take place
+<span class="pagenum" id="Page_118">[Pg 118]</span>
+at the surface; more commonly it takes place a few inches below, owing
+to the fact that under conditions of rapid evaporation, there is
+ordinarily a discontinuance in the capillary columns or the film water
+at a point below the surface of the soil, the water diffusing thence
+into the above-surface atmosphere as the vapor phase.</p>
+
+<p>The composition of alkali is varied. In the vast majority of cases, the
+world over, the predominating compound is sodium chloride. When calcium
+carbonate is a conspicuous component of the soil, as a hard-pan or
+otherwise, sodium carbonate or black alkali is also generally present,
+or apt to appear when the land is irrigated. When calcium sulphate or
+gypsum is likewise present, there is less probability of appreciable
+amounts of black alkali, and where gypsum predominates or the calcium
+carbonate is present in relatively inappreciable amounts, black alkali
+is generally absent, and sodium sulphate is an important constituent
+of the alkali. Relative rates of diffusion, selective absorption, and
+sometimes other factors are prominent, however, and the character of
+the alkali in different spots within a few yards of one another may
+differ greatly. One of the most interesting manifestations of alkali is
+the occasional occurrence of a predominating amount of calcium chloride
+which, as a result of its unusually high hygroscopicity, renders the
+soil damper, and therefore darker in color than the surrounding soil,
+and frequently causes even experts to suspect the presence of black
+alkali. Its true nature can, of course, be determined by a simple
+chemical examination.</p>
+
+<p>The effect of alkali on the physical properties of the soil is often
+very marked, aside from the cementing action or hard-pan formation by
+the carbonate or sulphate of lime. Black alkali, by dissolving and
+segregating the organic matter at the surface, removes from the lower
+soil layers the “humus” compounds which are of enormous importance
+to the maintenance of a soil structure favorable to plant growth.
+Moreover, black alkali is one of the best of deflocculating agents,
+and consequently soils where it is a noticeable component, frequently
+puddle with great readiness and are reclaimed with the utmost
+difficulty. Most of the other constituents of alkali, however, are
+<span class="pagenum" id="Page_119">[Pg 119]</span>
+flocculating or “crumbing” agencies, and if not present in too large
+amounts tend to increase the readiness with which the soil can be
+brought into good tilth. In this latter case, by separating in the
+solid phase, or in forming a viscous soil solution, near the saturation
+point, they sometimes produce a condition in the soil simulating
+puddling, and where it occurs below the surface, called an alkali
+hard-pan.</p>
+
+<p>The management of soils infested with alkali is possible in accordance
+with a few well established principles. Substantial progress has been
+made in selecting and breeding plants and strains of plants adapted
+to such soils. Extreme cases are the use of the so-called Australian
+salt-bushes as forage crops, and the growing of date-palms which
+through generations of breeding in the oases of the Sahara can thrive
+in lands so salty as to destroy most of the halophilous plants. More
+interesting is the unwitting development of the farmers of Utah of
+strains of wheat and alfalfa which easily withstand three or four
+times as high a salt content in the soil as do corresponding crops
+in other alkali regions, such as New Mexico and Arizona.&#x2060;<a id="FNanchor_140_140" href="#Footnote_140_140" class="fnanchor">[140]</a>
+Black alkali, or one in which sodium carbonate is a prominent
+constituent, is especially destructive to vegetation, not alone on
+account of a toxic action on plants, but because in any considerable
+concentration it has a corrosive action on the plant tissue. Not only
+on this account but also because of its unfortunate effects on the
+physical properties of the soil, black alkali has received unusual
+attention from soil investigators. Hilgard&#x2060;<a id="FNanchor_141_141" href="#Footnote_141_141" class="fnanchor">[141]</a>
+has repeatedly urged the use of gypsum as an “antidote” to black
+<span class="pagenum" id="Page_120">[Pg 120]</span>
+drainage and aeration a reaction takes place in accordance with the
+alkali, assuming that under conditions of good following equation,</p>
+
+<p class="f120">Na₂CO₃ + CaSO₄ = CaCO₃ + Na₂SO₄.</p>
+
+<p>Furthermore, it has been shown that calcium salts and especially
+calcium sulphate exercise a marked ameliorating effect on the action of
+other salts upon growing vegetation.&#x2060;<a id="FNanchor_142_142" href="#Footnote_142_142" class="fnanchor">[142]</a>
+On the other hand, the reaction indicated by the equation just given
+does not run to an end with complete precipitation of the carbonate,
+and the total amount of alkali is increased in the soil by the addition
+of the gypsum. Unfortunately, Hilgard’s suggestion has not yet acquired
+the sanction of satisfactory field demonstration, although it would
+seem to merit more consideration than has been given it. Inasmuch as
+lime is generally a prominent constituent of soils containing black
+alkali, it is possible that the maintenance of good drainage and
+aeration in the soil is itself the best corrective of black alkali.</p>
+
+<p>The best use of alkali soils involves irrigation, and it is in the
+application of irrigation waters that management of alkali soils finds
+its most highly developed and most important expression. With light
+sandy soils it has sometimes been found practicable to add sufficient
+water to carry the alkali down into the soil to such a depth that the
+crop is well advanced toward maturity before the alkali again rises in
+sufficient amounts to prove seriously detrimental to the more advanced
+crops which are generally far more “alkali resistant” than the young
+seedlings or the germinating seeds. In some cases this procedure can
+be practiced for a number of years without greatly increasing the
+seriousness of the alkali conditions, and it may be justified, for a
+time at least, by economic considerations. Ultimately, however, and
+more quickly with heavy than with light soils, increasing amounts
+of alkali must be brought into the surface soil, and this method of
+irrigating should not be considered as anything more than a temporary
+<span class="pagenum" id="Page_121">[Pg 121]</span>
+expedient. The only procedure which should be seriously considered as
+a permanent system on an alkali soil, no matter what the texture, is
+the installation of underground drains, for which purpose, so far,
+cylindrical tile drains commend themselves as giving the best results.
+With a well established system of tile drains, the alkali and all
+excess of soluble salts can be removed from the soil above the drains;
+and alkali rising from the soil below can, at least very largely, be
+prevented from rising to the upper soil layers. The reclamation of an
+alkali tract by underdrainage is not, however, a necessarily quick
+operation. Generally it must be a matter of several years persistent
+and careful effort, but once attained should readily be maintained. The
+reclamation of an alkali tract by flooding and underdrainage involves
+the reverse process to the crystallization of salt from a brine. If
+the water in percolating through the soil were long enough in contact
+with the salts present to become a saturated solution in equilibrium
+with them, then the composition of the resulting solution or drainage
+water would depend upon the particular solid phases or salts which are
+present in the soil, but not on the amounts of these salts; and the
+relative proportions of the mineral constituents in the drainage water
+should remain constant until some one of the solid phases in the soil
+permanently disappears.</p>
+
+<p>In practice, however, the water passes through the soil at different
+rates from time to time, the flow from the tiles being copious after a
+flooding but gradually diminishing as time goes on. One or both of two
+processes can therefore take place. The water may dissolve some of the
+salts without at any time or place becoming saturated. As the different
+salts have different rates of solution as well as different absolute
+solubilities, it would be expected that not only the concentration of
+the drainage water, but the composition of the dissolved salts would
+change from time to time. On the other hand, a part of the water may be
+imagined to percolate slowly through the finer openings, thus forming
+a saturated solution with respect to the alkali salts which solution,
+however, will be diluted on entrance to the drains by a part of the
+water going through the larger soil openings and dissolving but little
+<span class="pagenum" id="Page_122">[Pg 122]</span>
+salt in its passage. In this case, it would be anticipated that the
+concentration of the drainage water would increase as the amount of
+flow diminished but the composition of the dissolved salts would remain
+practically constant until some one or more of the alkali salts was
+completely removed. There are, unfortunately, but few experimental
+data by which these can be tested. In the accompanying table are given
+the results of an investigation on the reclamation of an alkali tract
+near Salt Lake City, Utah, where observations on the composition of
+the drainage water were made at frequent intervals for more than three
+years.&#x2060;<a id="FNanchor_143_143" href="#Footnote_143_143" class="fnanchor">[143]</a></p>
+
+<p>At first sight these results might appear to show that the composition
+of the salts was remaining reasonably constant. This conclusion
+must be received with caution, however. Variations do occur in the
+constituents which are present in smaller amount, but the variations
+are not systematic and may plausibly be explained by dilution of
+saturated solution by unsaturated solution on entering the drains.
+Confining attention therefore to the constituents occurring in larger
+proportions, namely, sodium chloride, sodium sulphate and sodium
+bicarbonate (including the normal carbonate) it should be remembered
+that the percentage of sodium in these three salts does not vary much,
+and the “constancy” may be more apparent than real. Indeed a close
+inspection of the results indicates that while the sodium is remaining
+practically unchanged, there is some decrease in the chlorine and a
+corresponding increase in the sulph-ion. From this it would follow that
+the sodium chloride was being washed out of the soil more rapidly,
+proportionately, than sodium sulphate; and it would also appear that
+the solution entering the drains was not in final equilibrium with the
+salts in the soil.
+<span class="pagenum" id="Page_123">[Pg 123]</span></p>
+
+<p class="f120"><b><span class="smcap">Composition of the Salts in the Drainage Water<br>
+from the Swan Tract, Utah</span></b></p>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc" colspan="2">Date</th>
+ <th class="tdc bl">Ca<br>&nbsp;per cent.&nbsp;</th>
+ <th class="tdc bl">Mg<br>&nbsp;per cent.&nbsp;</th>
+ <th class="tdc bl">Na<br>&nbsp;per cent.&nbsp;</th>
+ <th class="tdc bl">K<br>&nbsp;per cent.&nbsp;</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl_top" rowspan="3">1902—</td>
+ <td class="tdl">September</td>
+ <td class="tdc bl">0.38</td>
+ <td class="tdc bl">0.50</td>
+ <td class="tdc bl">33.74</td>
+ <td class="tdc bl">2.04</td>
+ </tr><tr>
+ <td class="tdl">October</td>
+ <td class="tdc bl">0.23</td>
+ <td class="tdc bl">0.78</td>
+ <td class="tdc bl">34.73</td>
+ <td class="tdc bl">1.49</td>
+ </tr><tr>
+ <td class="tdl">November</td>
+ <td class="tdc bl">0.19</td>
+ <td class="tdc bl">0.74</td>
+ <td class="tdc bl">34.42</td>
+ <td class="tdc bl">1.40</td>
+ </tr><tr class="bt">
+ <td class="tdl_top" rowspan="6">1903—</td>
+ <td class="tdl">May</td>
+ <td class="tdc bl">0.38</td>
+ <td class="tdc bl">0.61</td>
+ <td class="tdc bl">34.48</td>
+ <td class="tdc bl">0.84</td>
+ </tr><tr>
+ <td class="tdl">June</td>
+ <td class="tdc bl">0.45</td>
+ <td class="tdc bl">0.85</td>
+ <td class="tdc bl">34.18</td>
+ <td class="tdc bl">1.09</td>
+ </tr><tr>
+ <td class="tdl">July</td>
+ <td class="tdc bl">0.50</td>
+ <td class="tdc bl">0.80</td>
+ <td class="tdc bl">34.06</td>
+ <td class="tdc bl">1.25</td>
+ </tr><tr>
+ <td class="tdl">August</td>
+ <td class="tdc bl">0.35</td>
+ <td class="tdc bl">0.90</td>
+ <td class="tdc bl">34.40</td>
+ <td class="tdc bl">1.12</td>
+ </tr><tr>
+ <td class="tdl">September</td>
+ <td class="tdc bl">0.49</td>
+ <td class="tdc bl">0.72</td>
+ <td class="tdc bl">34.54</td>
+ <td class="tdc bl">1.24</td>
+ </tr><tr>
+ <td class="tdl">October</td>
+ <td class="tdc bl">0.47</td>
+ <td class="tdc bl">1.02</td>
+ <td class="tdc bl">33.43</td>
+ <td class="tdc bl">1.52</td>
+ </tr><tr class="bt">
+ <td class="tdl_top" rowspan="10">1904—</td>
+ <td class="tdl">January</td>
+ <td class="tdc bl">0.15</td>
+ <td class="tdc bl">0.75</td>
+ <td class="tdc bl">33.93</td>
+ <td class="tdc bl">1.26</td>
+ </tr><tr>
+ <td class="tdl">February</td>
+ <td class="tdc bl">0.34</td>
+ <td class="tdc bl">0.78</td>
+ <td class="tdc bl">34.59</td>
+ <td class="tdc bl">0.70</td>
+ </tr><tr>
+ <td class="tdl">March</td>
+ <td class="tdc bl">0.29</td>
+ <td class="tdc bl">0.77</td>
+ <td class="tdc bl">34.57</td>
+ <td class="tdc bl">1.28</td>
+ </tr><tr>
+ <td class="tdl">April</td>
+ <td class="tdc bl">0.29</td>
+ <td class="tdc bl">0.70</td>
+ <td class="tdc bl">34.28</td>
+ <td class="tdc bl">1.37</td>
+ </tr><tr>
+ <td class="tdl">May</td>
+ <td class="tdc bl">0.71</td>
+ <td class="tdc bl">0.74</td>
+ <td class="tdc bl">26.92</td>
+ <td class="tdc bl">4.01</td>
+ </tr><tr>
+ <td class="tdl">June</td>
+ <td class="tdc bl">0.37</td>
+ <td class="tdc bl">0.70</td>
+ <td class="tdc bl">32.60</td>
+ <td class="tdc bl">3.55</td>
+ </tr><tr>
+ <td class="tdl">August</td>
+ <td class="tdc bl">0.37</td>
+ <td class="tdc bl">0.86</td>
+ <td class="tdc bl">33.85</td>
+ <td class="tdc bl">2.13</td>
+ </tr><tr>
+ <td class="tdl">September</td>
+ <td class="tdc bl">0.42</td>
+ <td class="tdc bl">0.79</td>
+ <td class="tdc bl">34.10</td>
+ <td class="tdc bl">1.35</td>
+ </tr><tr>
+ <td class="tdl">October</td>
+ <td class="tdc bl">1.04</td>
+ <td class="tdc bl">0.60</td>
+ <td class="tdc bl">33.01</td>
+ <td class="tdc bl">1.86</td>
+ </tr><tr>
+ <td class="tdl">December</td>
+ <td class="tdc bl">1.25</td>
+ <td class="tdc bl">0.70</td>
+ <td class="tdc bl">32.62</td>
+ <td class="tdc bl">1.69</td>
+ </tr><tr class="bt">
+ <td class="tdl_top" rowspan="8">1905—</td>
+ <td class="tdl">February</td>
+ <td class="tdc bl">0.32</td>
+ <td class="tdc bl">0.67</td>
+ <td class="tdc bl">33.59</td>
+ <td class="tdc bl">0.99</td>
+ </tr><tr>
+ <td class="tdl">March</td>
+ <td class="tdc bl">0.31</td>
+ <td class="tdc bl">0.66</td>
+ <td class="tdc bl">33.46</td>
+ <td class="tdc bl">1.30</td>
+ </tr><tr>
+ <td class="tdl">April</td>
+ <td class="tdc bl">0.35</td>
+ <td class="tdc bl">0.65</td>
+ <td class="tdc bl">34.20</td>
+ <td class="tdc bl">1.01</td>
+ </tr><tr>
+ <td class="tdl">May</td>
+ <td class="tdc bl">0.45</td>
+ <td class="tdc bl">0.86</td>
+ <td class="tdc bl">33.43</td>
+ <td class="tdc bl">1.20</td>
+ </tr><tr>
+ <td class="tdl">June</td>
+ <td class="tdc bl">0.40</td>
+ <td class="tdc bl">0.94</td>
+ <td class="tdc bl">34.05</td>
+ <td class="tdc bl">1.32</td>
+ </tr><tr>
+ <td class="tdl">July</td>
+ <td class="tdc bl">0.32</td>
+ <td class="tdc bl">0.69</td>
+ <td class="tdc bl">33.67</td>
+ <td class="tdc bl">1.30</td>
+ </tr><tr>
+ <td class="tdl">August</td>
+ <td class="tdc bl">0.35</td>
+ <td class="tdc bl">1.04</td>
+ <td class="tdc bl">33.12</td>
+ <td class="tdc bl">1.58</td>
+ </tr><tr>
+ <td class="tdl">September &nbsp;</td>
+ <td class="tdc bl">0.42</td>
+ <td class="tdc bl">0.82</td>
+ <td class="tdc bl">33.39</td>
+ <td class="tdc bl">1.26</td>
+ </tr><tr class="bb">
+ <td class="tdl">1906—</td>
+ <td class="tdl">January</td>
+ <td class="tdc bl">0.55</td>
+ <td class="tdc bl">0.84</td>
+ <td class="tdc bl">33.12</td>
+ <td class="tdc bl">1.11</td>
+ </tr>
+ </tbody>
+</table>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc" colspan="2">Date</th>
+ <th class="tdc bl">SO₄<br>&nbsp;per cent.&nbsp;</th>
+ <th class="tdc bl">Cl<br>&nbsp;per cent.&nbsp;</th>
+ <th class="tdc bl">HCO₃<br>&nbsp;per cent.&nbsp;</th>
+ <th class="tdc bl">CO₃<br>&nbsp;per cent.&nbsp;</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl_top" rowspan="3">1902—</td>
+ <td class="tdl">September</td>
+ <td class="tdc bl">18.62</td>
+ <td class="tdc bl">37.76</td>
+ <td class="tdc bl">6.49</td>
+ <td class="tdc bl">0.48</td>
+ </tr><tr>
+ <td class="tdl">October</td>
+ <td class="tdc bl">19.14</td>
+ <td class="tdc bl">39.52</td>
+ <td class="tdc bl">5.06</td>
+ <td class="tdc bl">0.29</td>
+ </tr><tr>
+ <td class="tdl">November</td>
+ <td class="tdc bl">18.61</td>
+ <td class="tdc bl">40.46</td>
+ <td class="tdc bl">3.95</td>
+ <td class="tdc bl">0.23</td>
+ </tr><tr class="bt">
+ <td class="tdl_top" rowspan="6">1903—</td>
+ <td class="tdl">May</td>
+ <td class="tdc bl">29.90</td>
+ <td class="tdc bl">38.19</td>
+ <td class="tdc bl">4.30</td>
+ <td class="tdc bl">0.25</td>
+ </tr><tr>
+ <td class="tdl">June</td>
+ <td class="tdc bl">17.52</td>
+ <td class="tdc bl">41.00</td>
+ <td class="tdc bl">4.23</td>
+ <td class="tdc bl">0.42</td>
+ </tr><tr>
+ <td class="tdl">July</td>
+ <td class="tdc bl">18.24</td>
+ <td class="tdc bl">40.24</td>
+ <td class="tdc bl">4.67</td>
+ <td class="tdc bl">0.30</td>
+ </tr><tr>
+ <td class="tdl">August</td>
+ <td class="tdc bl">17.15</td>
+ <td class="tdc bl">42.37</td>
+ <td class="tdc bl">3.48</td>
+ <td class="tdc bl">0.16</td>
+ </tr><tr>
+ <td class="tdl">September</td>
+ <td class="tdc bl">17.31</td>
+ <td class="tdc bl">42.02</td>
+ <td class="tdc bl">3.36</td>
+ <td class="tdc bl">0.33</td>
+ </tr><tr>
+ <td class="tdl">October</td>
+ <td class="tdc bl">16.08</td>
+ <td class="tdc bl">43.28</td>
+ <td class="tdc bl">3.33</td>
+ <td class="tdc bl">0.30</td>
+ </tr><tr class="bt">
+ <td class="tdl_top" rowspan="10">1904—</td>
+ <td class="tdl">January</td>
+ <td class="tdc bl">20.08</td>
+ <td class="tdc bl">36.64</td>
+ <td class="tdc bl">6.94</td>
+ <td class="tdc bl">0.25</td>
+ </tr><tr>
+ <td class="tdl">February</td>
+ <td class="tdc bl">18.95</td>
+ <td class="tdc bl">40.15</td>
+ <td class="tdc bl">4.49</td>
+ <td class="tdc bl">——</td>
+ </tr><tr>
+ <td class="tdl">March</td>
+ <td class="tdc bl">16.31</td>
+ <td class="tdc bl">42.28</td>
+ <td class="tdc bl">3.81</td>
+ <td class="tdc bl">0.19</td>
+ </tr><tr>
+ <td class="tdl">April</td>
+ <td class="tdc bl">20.93</td>
+ <td class="tdc bl">38.04</td>
+ <td class="tdc bl">3.33</td>
+ <td class="tdc bl">1.06</td>
+ </tr><tr>
+ <td class="tdl">May</td>
+ <td class="tdc bl">21.26</td>
+ <td class="tdc bl">40.93</td>
+ <td class="tdc bl">4.05</td>
+ <td class="tdc bl">1.38</td>
+ </tr><tr>
+ <td class="tdl">June</td>
+ <td class="tdc bl">19.94</td>
+ <td class="tdc bl">37.42</td>
+ <td class="tdc bl">4.05</td>
+ <td class="tdc bl">1.37</td>
+ </tr><tr>
+ <td class="tdl">August</td>
+ <td class="tdc bl">17.12</td>
+ <td class="tdc bl">41.31</td>
+ <td class="tdc bl">3.20</td>
+ <td class="tdc bl">1.16</td>
+ </tr><tr>
+ <td class="tdl">September</td>
+ <td class="tdc bl">19.01</td>
+ <td class="tdc bl">39.85</td>
+ <td class="tdc bl">4.11</td>
+ <td class="tdc bl">0.37</td>
+ </tr><tr>
+ <td class="tdl">October</td>
+ <td class="tdc bl">21.42</td>
+ <td class="tdc bl">36.63</td>
+ <td class="tdc bl">4.68</td>
+ <td class="tdc bl">0.76</td>
+ </tr><tr>
+ <td class="tdl">December</td>
+ <td class="tdc bl">19.89</td>
+ <td class="tdc bl">37.44</td>
+ <td class="tdc bl">6.18</td>
+ <td class="tdc bl">0.22</td>
+ </tr><tr class="bt">
+ <td class="tdl_top" rowspan="8">1905—</td>
+ <td class="tdl">February</td>
+ <td class="tdc bl">22.30</td>
+ <td class="tdc bl">33.32</td>
+ <td class="tdc bl">8.45</td>
+ <td class="tdc bl">0.36</td>
+ </tr><tr>
+ <td class="tdl">March</td>
+ <td class="tdc bl">21.60</td>
+ <td class="tdc bl">33.86</td>
+ <td class="tdc bl">8.46</td>
+ <td class="tdc bl">0.35</td>
+ </tr><tr>
+ <td class="tdl">April</td>
+ <td class="tdc bl">20.03</td>
+ <td class="tdc bl">36.99</td>
+ <td class="tdc bl">6.22</td>
+ <td class="tdc bl">0.55</td>
+ </tr><tr>
+ <td class="tdl">May</td>
+ <td class="tdc bl">20.59</td>
+ <td class="tdc bl">36.04</td>
+ <td class="tdc bl">6.96</td>
+ <td class="tdc bl">0.47</td>
+ </tr><tr>
+ <td class="tdl">June</td>
+ <td class="tdc bl">20.89</td>
+ <td class="tdc bl">35.85</td>
+ <td class="tdc bl">5.71</td>
+ <td class="tdc bl">0.84</td>
+ </tr><tr>
+ <td class="tdl">July</td>
+ <td class="tdc bl">21.17</td>
+ <td class="tdc bl">34.94</td>
+ <td class="tdc bl">7.23</td>
+ <td class="tdc bl">0.68</td>
+ </tr><tr>
+ <td class="tdl">August</td>
+ <td class="tdc bl">21.58</td>
+ <td class="tdc bl">35.92</td>
+ <td class="tdc bl">5.72</td>
+ <td class="tdc bl">0.99</td>
+ </tr><tr>
+ <td class="tdl">September</td>
+ <td class="tdc bl">21.18</td>
+ <td class="tdc bl">34.85</td>
+ <td class="tdc bl">7.41</td>
+ <td class="tdc bl">0.67</td>
+ </tr><tr class="bb">
+ <td class="tdl">1906—</td>
+ <td class="tdl">January</td>
+ <td class="tdc bl">21.10</td>
+ <td class="tdc bl">34.35</td>
+ <td class="tdc bl">8.57</td>
+ <td class="tdc bl">0.36</td>
+ </tr>
+ </tbody>
+</table>
+
+<p><span class="pagenum" id="Page_124">[Pg 124]</span>
+How long drainage must continue before there is a radical change in the
+composition of the seepage water cannot be predicted, and unfortunately
+data regarding this point are not available. It is certain that in
+time some one or more of the salts in the soil would be removed and
+the nature of the drainage water would be changed. Alterations in the
+composition of the drainage water furnish the readiest as well as the
+best guides as to the changes and the nature of the changes taking
+place in the soil during the process of reclamation. As a practical
+matter it should be borne in mind that the persistence of the several
+salts of the alkali mixture does not mean necessarily that they are
+evenly distributed in the soil; while yet determining the composition
+of the water entering the drain, they may have disappeared from the
+upper soil layers which then may hold a solution of quite different
+character, suited to the support of crops. In the case just cited the
+soil contained, before drainage operations were commenced, upwards of
+2.7 per cent. of readily soluble salts and would not support any growth
+other than salt-bushes and similar halophilous plants. Four years later
+the soil contained less than 0.3 per cent. soluble salts and yielded
+a very satisfactory crop of alfalfa. In such cases, however, the land
+cannot be considered as finally reclaimed until a material change in
+the composition of the drainage water shows that there has been a
+complete removal of some of the solid salts from that portion of the
+soil feeding the drains.</p>
+
+<p>The rate at which alkali can be leached from a soil is dependent in a
+large measure upon the absorptive properties of the soil, and to some
+extent upon the nature of the salts composing the alkali. The leaching
+is more rapid from sandy than from clay soils, and white alkali is
+leached more readily than is black. In general, however, the same laws
+hold here as in any leaching of a solute from an absorbent, and it has
+been shown that even in the case of black alkali, the rate of removal
+under a constant leaching follows the law</p>
+
+<table class="spb1 fs_120">
+ <tbody><tr>
+ <td class="tdl bb">&nbsp;<i>dx</i>&nbsp;</td>
+ <td class="tdl_wsp" rowspan="2">= K (A - <i>x</i>).&#x2060;<a id="FNanchor_144_144" href="#Footnote_144_144" class="fnanchor">[144]</a></td>
+ </tr><tr>
+ <td class="tdl"><i>dt</i></td>
+ </tr>
+ </tbody>
+</table>
+
+<p>In practice, the water does not percolate through the soil under a
+constant “head,” but the flow is intermittent, so that the value of the
+above formula is mainly academic. On the other hand, if the drainage
+between floodings is thorough, this procedure should be more efficient
+than any other for causing a rapid removal of the alkali salts, if, as
+is generally the case, a limited quantity of water is available.
+<span class="pagenum" id="Page_125">[Pg 125]</span></p>
+
+<p>Finally, it remains to be pointed out that the use of excessive amounts
+of water on alkali tracts is quite as unfortunate in its effects as the
+use of too little. If water be added to an undrained soil or in excess
+of the capacity of the drains to remove it, incalculable harm may be
+done by enormously increasing in the surface soil the amount of salts
+brought up from the lower layers as the capillary stream rises to the
+surface in consequence of evaporation there. Should the wetting of the
+soil proceed so far as to establish good capillary connection with the
+permanent ground water, the harm may be sufficient to offset in a few
+weeks or months expensive reclamation efforts of years. The harm to the
+tract where the water is added may be far less than the harm done to
+other areas. A large proportion of existing alkali deposits or “spots”
+results from the evaporation of seepage waters coming sometimes from
+considerable distances. The over-wetting of a soil means the production
+of seepage waters which are to appear at the surface somewhere
+else, generally at a lower level, and frequently means the more or
+less complete ruin of the soils of the lower level. The experience
+of India, Africa and our own arid states in the increase of alkali
+spots following the introduction of irrigation, added to our present
+theoretical knowledge, should make the planning of an irrigation
+project without adequate drainage provisions, a stupidity, and its
+accomplishment a public crime. Quite as important is the development
+of a public opinion that the individual cultivator who deliberately or
+carelessly uses excessive amounts of water on his tract is a serious
+enemy to the body politic, and should be treated as such.
+<span class="pagenum"><a id="Page_126"></a>[Pg 126]</span></p>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+<p><span class="pagenum"><a id="Page_127"></a>[Pg 127]</span></p>
+ <h2 class="nobreak">INDEX.</h2>
+</div>
+
+<ul class="index">
+<li class="isub2">Absorbents, Influence on soil extracts, <a href="#Page_38">38</a></li>
+<li class="isub2">Absorption by soils, <a href="#Page_9">9</a>, <a href="#Page_59">59</a>, <a href="#Page_65">65</a></li>
+<li class="isub3">formula, <a href="#Page_62">62</a></li>
+<li class="isub3">of dyes, <a href="#Page_60">60</a>, <a href="#Page_61">61</a></li>
+<li class="isub3">rate, <a href="#Page_63">63</a></li>
+<li class="isub3">selective, <a href="#Page_61">61</a></li>
+<li class="isub2">Acid digestion of soils, <a href="#Page_11">11</a>, <a href="#Page_12">12</a></li>
+<li class="isub2">Adsorption, <a href="#Page_9">9</a>, <a href="#Page_60">60</a></li>
+<li class="isub2">Alkali, <a href="#Page_110">110</a>, <a href="#Page_118">118</a></li>
+<li class="isub3">Effect on soils, <a href="#Page_118">118</a></li>
+<li class="isub3">Order of deposition, <a href="#Page_112">112</a></li>
+<li class="isub3">Reclamation, <a href="#Page_117">117</a>, <a href="#Page_121">121</a></li>
+<li class="isub3">Source, <a href="#Page_111">111</a>, <a href="#Page_117">117</a></li>
+<li class="isub2">Antagonism between salts, <a href="#Page_120">120</a></li>
+<li class="isub2">Apophyllite, Crystallization from water, <a href="#Page_35">35</a></li>
+<li class="isub2">Apple trees, Effect of grass on, <a href="#Page_98">98</a></li>
+<li class="isub2">Appleyard, James R. <i>See</i> Walker, James, and Appleyard, James R.</li>
+<li class="isub2">Ash analyses, <a href="#Page_11">11</a>, <a href="#Page_13">13</a></li>
+<li class="isub2">Association of Official Agricultural Chemists’ analyses, quoted, <a href="#Page_12">12</a></li>
+<li class="isub3">cited, <a href="#Page_12">12</a></li>
+<li class="isub3">“official method”, <a href="#Page_10">10</a>, <a href="#Page_12">12</a></li>
+<li class="isub2">“Available” and “non-available” plant-food elements, <a href="#Page_8">8</a></li>
+<li class="isub2">Averitt, S. D. <i>See</i> Peter, Alfred M., and Averitt, S. D.</li>
+
+<li class="isub2 ifrst">Bacteria in soils, <a href="#Page_103">103</a></li>
+<li class="isub2">Bailey, Liberty H., cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Balance between supply and removal of mineral plant nutrients, <a href="#Page_75">75</a></li>
+<li class="isub2">Barium in soils, <a href="#Page_107">107</a></li>
+<li class="isub2">Bardt, A. <i>See</i> Doroshevskii, A. and Bardt, A.</li>
+<li class="isub2">Becquerel, Antoine C., cited, <a href="#Page_67">67</a></li>
+<li class="isub3">quoted, <a href="#Page_68">68</a></li>
+<li class="isub2">Bell, James M., and Cameron, Frank K., cited, <a href="#Page_28">28</a></li>
+<li class="isub2">Bell, James M. <i>See also</i> Cameron, Frank K., and Bell, J. M.;</li>
+<li class="isub5">Cameron, Frank K., Bell, J. M., and Robinson, W. O.</li>
+<li class="isub2">Benedick, Carl, cited, <a href="#Page_55">55</a></li>
+<li class="isub2">Birner, H., and Lucanus, B., cited, <a href="#Page_70">70</a></li>
+<li class="isub2">Bischof, Gustav, cited, <a href="#Page_113">113</a></li>
+<li class="isub2">Black alkali, <a href="#Page_110">110</a>, <a href="#Page_114">114</a>,
+ <a href="#Page_119">119</a>, <a href="#Page_124">124</a></li>
+<li class="isub2">Blanck, Edward, cited, <a href="#Page_63">63</a></li>
+<li class="isub2">Breazeale, James F., acknowledgments, <a href="#Page_80">80</a></li>
+<li class="isub3">cited, <a href="#Page_71">71</a></li>
+<li class="isub3"><i>See also</i> Cameron, Frank K., and Breazeale, J. F.;</li>
+<li class="isub5">LeClerc, J. A. and Breazeale, J. F.
+ <span class="pagenum" id="Page_128">[Pg 128]</span></li>
+<li class="isub2">Briggs, Lyman J., cited, <a href="#Page_55">55</a></li>
+<li class="isub3">and Lapham, Macy H., cited, <a href="#Page_41">41</a></li>
+<li class="isub3">and McLane, John W., cited, <a href="#Page_26">26</a></li>
+<li class="isub3">Martin, F. O., and Pearce, J. R., cited, <a href="#Page_31">31</a></li>
+<li class="isub2">Brooks, William P., cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Brown, Bailey E., cited, <a href="#Page_46">46</a></li>
+<li class="isub3">quoted, <a href="#Page_46">46</a>, <a href="#Page_115">115</a></li>
+<li class="isub2">Bryan, H. <i>See</i> Davis, R. O. E., and Bryan, H.</li>
+<li class="isub2">Buckingham, Edgar, cited, <a href="#Page_30">30</a></li>
+<li class="isub2">Burney, W. B., quoted, <a href="#Page_98">98</a></li>
+
+<li class="isub2 ifrst">Cameron, Frank K., cited, <a href="#Page_110">110</a>, <a href="#Page_114">114</a>, <a href="#Page_115">115</a></li>
+<li class="isub3"><i>See also</i> Bell, James M., and Cameron, Frank K.; Kearney, Thomas H.</li>
+<li class="isub5">and Cameron, Frank K.; Whitney, Milton, and Cameron, Frank K.</li>
+<li class="isub5">and Bell, James M., cited, <a href="#Page_31">31</a>, <a href="#Page_38">38</a>,
+ <a href="#Page_50">50</a>, <a href="#Page_113">113</a>, <a href="#Page_122">122</a></li>
+<li class="isub5">and Breazeale, James F., cited, <a href="#Page_62">62</a></li>
+<li class="isub5">and Gallagher, Francis E., cited, <a href="#Page_24">24</a></li>
+<li class="isub5">and Patten, Harrison E., cited, <a href="#Page_63">63</a>, <a href="#Page_124">124</a></li>
+<li class="isub5">and Robinson, William O., cited, <a href="#Page_27">27</a>, <a href="#Page_53">53</a></li>
+<li class="isub5">Bell, James M., and Robinson, William O., cited, <a href="#Page_114">114</a></li>
+<li class="isub2">Calcium nitrate, basic, <a href="#Page_108">108</a></li>
+<li class="isub2">Carbon dioxide in the soil, <a href="#Page_53">53</a></li>
+<li class="isub2">Charpentier, Jean G. F., cited, <a href="#Page_113">113</a></li>
+<li class="isub2">Chemical analysis of soils. <i>See</i> Soil analysis—Chemical.</li>
+<li class="isub2">Chesneau, G., cited, <a href="#Page_68">68</a></li>
+<li class="isub2">Christie, W. A. K. <i>See</i> Holland, Sir Thomas H., and Christie, W. A. K.</li>
+<li class="isub2">Clarke, Frank Wigglesworth, cited, <a href="#Page_76">76</a>, <a href="#Page_115">115</a></li>
+<li class="isub2">Coffey, George N., quoted, <a href="#Page_23">23</a></li>
+<li class="isub2">Concentration of mineral constituents, <a href="#Page_39">39</a></li>
+<li class="isub2">Concentration, Plant growth and, <a href="#Page_70">70</a></li>
+<li class="isub2">Cracking of soil, <a href="#Page_22">22</a></li>
+<li class="isub2">Creep, <a href="#Page_19">19</a></li>
+<li class="isub2">Creighton, Henry J. M. <i>See</i> Findlay, Alexander, and Creighton, Henry J. M.</li>
+<li class="isub2">Critical moisture content, <a href="#Page_24">24</a></li>
+<li class="isub2">Crop control methods, <a href="#Page_7">7</a>, <a href="#Page_105">105</a></li>
+<li class="isub3">plants defined, <a href="#Page_1">1</a></li>
+<li class="isub3">producing power and aqueous extract, <a href="#Page_81">81</a></li>
+<li class="isub3">rotation, Natural, <a href="#Page_97">97</a></li>
+<li class="isub7">Objects of, <a href="#Page_4">4</a></li>
+<li class="isub3">yields increasing, <a href="#Page_16">16</a></li>
+<li class="isub2">Crumb structure of soils, <a href="#Page_25">25</a></li>
+<li class="isub2">Crumbing, <a href="#Page_27">27</a>, <a href="#Page_119">119</a>
+ <span class="pagenum" id="Page_129">[Pg 129]</span></li>
+<li class="isub2">Cushman, Allerton S., cited, <a href="#Page_36">36</a></li>
+<li class="isub2">“Cut-off”, <a href="#Page_22">22</a>, <a href="#Page_75">75</a></li>
+<li class="isub2">Cyanamid, <a href="#Page_108">108</a></li>
+<li class="isub2">Czapek, Friedrich, Experiments on root etchings, <a href="#Page_9">9</a></li>
+<li class="isub3">Criticism of Molisch, <a href="#Page_101">101</a></li>
+
+<li class="isub2 ifrst">Dachnowski, Alfred, cited, <a href="#Page_88">88</a></li>
+<li class="isub2">Darbishire, Francis V., and Russell, Edward J., cited, <a href="#Page_103">103</a></li>
+<li class="isub2">Darwin, Horace, cited, <a href="#Page_22">22</a></li>
+<li class="isub2">Davis, R. O. E., quoted, <a href="#Page_63">63</a></li>
+<li class="isub3">and Bryan, H., cited, <a href="#Page_55">55</a></li>
+<li class="isub2">De Candolle, Augustin P., cited, <a href="#Page_97">97</a></li>
+<li class="isub2">Degradation of rocks, <a href="#Page_1">1</a></li>
+<li class="isub2">De Roode, Rudolph J. J., quoted, <a href="#Page_98">98</a></li>
+<li class="isub2">Diaspore, <a href="#Page_34">34</a></li>
+<li class="isub2">Dittrich, Max., cited, <a href="#Page_13">13</a></li>
+<li class="isub2">Doroshevskii, A., and Bardt, A., cited, <a href="#Page_35">35</a></li>
+<li class="isub2">Dorsey, Clarence W., cited, <a href="#Page_110">110</a>, <a href="#Page_122">122</a></li>
+<li class="isub2">Drainage waters, Composition, <a href="#Page_124">124</a></li>
+<li class="isub2">Drought limits defined, <a href="#Page_29">29</a></li>
+<li class="isub2">Dunnington, Francis P., cited, <a href="#Page_98">98</a></li>
+<li class="isub2">Dust, <a href="#Page_20">20</a></li>
+<li class="isub2">Dyer, Bernard, cited, <a href="#Page_40">40</a></li>
+<li class="isub3">method of soil analysis, <a href="#Page_10">10</a></li>
+<li class="isub3">quoted, <a href="#Page_6">6</a></li>
+<li class="isub2">Dynamic nature of soil phenomena, <a href="#Page_18">18</a></li>
+
+<li class="isub2 ifrst">Earthworms, <a href="#Page_22">22</a></li>
+<li class="isub2">European soils, analyses, <a href="#Page_16">16</a></li>
+<li class="isub2">Erosion, <a href="#Page_20">20</a></li>
+<li class="isub2">Etchings, Root, <a href="#Page_9">9</a></li>
+<li class="isub2">Ewart, A. J., cited, <a href="#Page_18">18</a>, <a href="#Page_72">72</a>,
+ <a href="#Page_73">73</a></li>
+<li class="isub2">Excreta, Toxic, <a href="#Page_99">99</a>, <a href="#Page_100">100</a>,
+ <a href="#Page_103">103</a></li>
+
+<li class="isub2 ifrst">“Factors”, <a href="#Page_11">11</a></li>
+<li class="isub2">Failyer, George H., cited, <a href="#Page_107">107</a></li>
+<li class="isub3"><i>See also</i> Schreiner, Oswald, and Failyer, George H. Smith,</li>
+<li class="isub5">Joseph G., and Wade, H. R., cited, <a href="#Page_32">32</a></li>
+<li class="isub2">Fairy rings, <a href="#Page_98">98</a></li>
+<li class="isub2">Feldspars, <a href="#Page_35">35</a>, <a href="#Page_38">38</a>, <a href="#Page_55">55</a></li>
+<li class="isub2">Fertilizers, <a href="#Page_4">4</a>, <a href="#Page_83">83</a>, <a href="#Page_105">105</a></li>
+<li class="isub2">Film water, <a href="#Page_24">24</a></li>
+<li class="isub3">tenacity, Experiments, <a href="#Page_25">25</a></li>
+<li class="isub2">Findlay, Alexander, and Creighton, Henry J. M., cited, <a href="#Page_53">53</a></li>
+<li class="isub2">Fine a soil, to, <a href="#Page_4">4</a></li>
+<li class="isub2">Fischer, Emil, and Schmidmer, Edward, cited, <a href="#Page_61">61</a></li>
+<li class="isub2">“Fly-off”, <a href="#Page_22">22</a>, <a href="#Page_75">75</a>
+ <span class="pagenum" id="Page_130">[Pg 130]</span></li>
+<li class="isub2">Frear, William, cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Free, Edward Elway, cited, <a href="#Page_20">20</a></li>
+<li class="isub2">Friedel, Charles and Sarasin, Edmond, cited, <a href="#Page_34">34</a></li>
+
+<li class="isub2 ifrst">Gallagher, Francis Edward. <i>See</i> Cameron, Frank K. and Gallagher, Francis E.</li>
+<li class="isub2">Gannett, Henry, cited, <a href="#Page_76">76</a></li>
+<li class="isub2">Gaudechon, H. <i>See</i> Muntz, A., and Gaudechon, H.</li>
+<li class="isub2">Geikie, <i>Sir</i> Archibald, cited, <a href="#Page_75">75</a></li>
+<li class="isub2">Gels, <a href="#Page_36">36</a></li>
+<li class="isub2">Gilbert, Joseph H., cited, <a href="#Page_98">98</a></li>
+<li class="isub2">Gonnard, F., cited, <a href="#Page_35">35</a></li>
+<li class="isub2">“Good” and “poor” soils compared, <a href="#Page_80">80</a></li>
+<li class="isub2">Graham, Thomas, cited, <a href="#Page_67">67</a></li>
+<li class="isub2">Granulate a soil, to, <a href="#Page_4">4</a></li>
+<li class="isub2">Grass, Effect on apple trees, <a href="#Page_98">98</a></li>
+<li class="isub2">Gravitational water, <a href="#Page_23">23</a></li>
+<li class="isub2">Great Salt Lake, Reaction of water, <a href="#Page_113">113</a></li>
+<li class="isub2">Green manure, Effect on soil extracts, <a href="#Page_87">87</a></li>
+<li class="isub2">Gypsum on alkali soils, <a href="#Page_119">119</a></li>
+
+<li class="isub2 ifrst">Hardpan, <a href="#Page_111">111</a></li>
+<li class="isub2">Harter, Leonard L. <i>See</i> Kearney, Thomas H., and Harter, L. L.</li>
+<li class="isub2">Hartwell, Burt L., Wheeler, H. J., and Pember, F. R., cited, <a href="#Page_74">74</a></li>
+<li class="isub2">Haselhoff, Emil. <i>See</i> König, Joseph, and Haselhoff, E.</li>
+<li class="isub2">Haworth, Erasmus, cited, <a href="#Page_113">113</a></li>
+<li class="isub2">Heileman, William H., quoted, <a href="#Page_65">65</a></li>
+<li class="isub2">Heterogeneity of soils, <a href="#Page_1">1</a>, <a href="#Page_21">21</a>, <a href="#Page_32">32</a>, <a href="#Page_79">79</a></li>
+<li class="isub2">Hilgard, Eugene W., cited, <a href="#Page_5">5</a>, <a href="#Page_6">6</a>, <a href="#Page_38">38</a>, <a href="#Page_40">40</a>, <a href="#Page_119">119</a></li>
+<li class="isub3">Method of soil analysis, <a href="#Page_10">10</a></li>
+<li class="isub2">Hillebrand, William F., cited, <a href="#Page_13">13</a></li>
+<li class="isub2">Hills, Joseph L., cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Holland, Sir Thomas H., and Christie, W. A. K., cited, <a href="#Page_116">116</a></li>
+<li class="isub2">Hulett, George A., cited, <a href="#Page_68">68</a></li>
+<li class="isub2">Humic acids, <a href="#Page_55">55</a></li>
+<li class="isub2">Humus, <a href="#Page_61">61</a></li>
+<li class="isub2">Hutchinson, Henry B. <i>See</i> Russell, Edward J., and Hutchinson, Henry B.</li>
+<li class="isub2">Hydrolysis, <a href="#Page_33">33</a></li>
+
+<li class="isub2 ifrst">Imbibition, <a href="#Page_59">59</a></li>
+<li class="isub2">Irrigation, <a href="#Page_120">120</a></li>
+
+<li class="isub2 ifrst">Johnson, Samuel W., cited, <a href="#Page_40">40</a>, <a href="#Page_77">77</a></li>
+<li class="isub3">quoted, <a href="#Page_2">2</a></li>
+
+<li class="isub2 ifrst">Kahlenberg, Louis, and Lincoln, Azariah T., cited, <a href="#Page_35">35</a></li>
+<li class="isub2">Kaolinite, <a href="#Page_34">34</a></li>
+<li class="isub2">Kearney, Thomas H., and Cameron, Frank K., cited, <a href="#Page_119">119</a></li>
+<li class="isub3">and Harter, Leonard L., cited, <a href="#Page_119">119</a>
+ <span class="pagenum" id="Page_131">[Pg 131]</span></li>
+<li class="isub2">Kentucky agricultural experiment station,</li>
+<li class="isub5">Method of soil analysis, <a href="#Page_10">10</a></li>
+<li class="isub2">King, Franklin H., cited, <a href="#Page_75">75</a>, <a href="#Page_76">76</a>, <a href="#Page_77">77</a></li>
+<li class="isub3">quoted, <a href="#Page_46">46</a>, <a href="#Page_76">76</a></li>
+<li class="isub2">Knight, Wilbur C., and Slosson, Edwin E., cited, <a href="#Page_114">114</a></li>
+<li class="isub2">König, Joseph, and Haselhoff, E., cited, <a href="#Page_8">8</a></li>
+<li class="isub2">Kossovich, Petr. S., Experiments on root etchings, <a href="#Page_9">9</a></li>
+
+<li class="isub2 ifrst">Lagergren, Sten, cited, <a href="#Page_26">26</a></li>
+<li class="isub2">Lake desiccation, <a href="#Page_114">114</a></li>
+<li class="isub2">Lapham, Macy H. <i>See</i> Briggs, Lyman J., and Lapham, Macy H.</li>
+<li class="isub2">Lawes, John B., and Gilbert, Joseph H. <i>See</i> Gilbert, Joseph H.</li>
+<li class="isub2">Leather, J. Walter, cited, <a href="#Page_23">23</a></li>
+<li class="isub2">Le Clerc, J. Arthur, and Breazeale, James F., cited, <a href="#Page_14">14</a></li>
+<li class="isub2">Lemberg, Johann T., cited, <a href="#Page_35">35</a></li>
+<li class="isub2">Liebig, Justus, cited, <a href="#Page_8">8</a>, <a href="#Page_97">97</a></li>
+<li class="isub2">Liebrich, A., cited, <a href="#Page_34">34</a></li>
+<li class="isub2">Liebreich, quoted, <a href="#Page_68">68</a></li>
+<li class="isub2">Lieving, quoted, <a href="#Page_68">68</a></li>
+<li class="isub2">Lincoln, Azariah T. <i>See</i> Kahlenberg, Louis, and Lincoln, Azariah T.</li>
+<li class="isub2">Lipman, Jacob G., cited, <a href="#Page_72">72</a>, <a href="#Page_103">103</a></li>
+<li class="isub3"><i>See also</i> Voorhees, Edward B., and Lipman, Jacob G.</li>
+<li class="isub2">Lipman, C. B., cited, <a href="#Page_120">120</a></li>
+<li class="isub2">Litmus, Absorption of, <a href="#Page_66">66</a></li>
+<li class="isub3">as indicator, <a href="#Page_66">66</a></li>
+<li class="isub2">Livingston, Burton E., cited, <a href="#Page_85">85</a>, <a href="#Page_88">88</a>, <a href="#Page_97">97</a></li>
+<li class="isub2">Loughridge, Robert H., cited, <a href="#Page_28">28</a>, <a href="#Page_119">119</a></li>
+<li class="isub2">Lucanus, B. <i>See</i> Birner, H., and Lucanus, B.</li>
+
+<li class="isub2 ifrst">McGee, W. J., quoted, <a href="#Page_22">22</a>, <a href="#Page_76">76</a></li>
+<li class="isub2">McLane, John W. <i>See</i> Briggs, Lyman J., and McLane, John W.</li>
+<li class="isub2">Manure, Stable, Effect on soil extracts, <a href="#Page_84">84</a></li>
+<li class="isub2">Martin, F. Oskar. <i>See</i> Briggs, Lyman J., Martin, F. O., and Pearce, J. R.</li>
+<li class="isub2">Maxwell, Walter, Method of soil analysis, <a href="#Page_10">10</a></li>
+<li class="isub2">Mechanical analysis, <a href="#Page_31">31</a></li>
+<li class="isub2">Merrill, George P., cited, <a href="#Page_9">9</a></li>
+<li class="isub2">Meyerhoffer, Wilhelm, cited, <a href="#Page_111">111</a></li>
+<li class="isub2">Meyer, Victor, cited, <a href="#Page_67">67</a></li>
+<li class="isub2">Minchin, George M., cited, <a href="#Page_26">26</a></li>
+<li class="isub2">Mineral constituents of soil solution, <a href="#Page_31">31</a>, <a href="#Page_37">37</a></li>
+<li class="isub2">Mineral plant nutrients, balance between supply and removal, <a href="#Page_75">75</a></li>
+<li class="isub2">Mississippi River, Soil-carrying power, <a href="#Page_21">21</a></li>
+<li class="isub2">Mixing of soils, <a href="#Page_33">33</a></li>
+<li class="isub2">Moisture content, <a href="#Page_24">24</a></li>
+<li class="isub2">Moisture movement into soil, <a href="#Page_28">28</a></li>
+<li class="isub2">Molisch, Hans, cited, <a href="#Page_101">101</a></li>
+<li class="isub2">Mooers, Charles A., cited, <a href="#Page_10">10</a>
+ <span class="pagenum" id="Page_132">[Pg 132]</span></li>
+<li class="isub2">Motion in soils, <a href="#Page_19">19</a></li>
+<li class="isub2">Movement of soils, <a href="#Page_20">20</a></li>
+<li class="isub2">Muntz, A., and Gaudechon, H., cited, <a href="#Page_30">30</a></li>
+<li class="isub3">quoted, <a href="#Page_24">24</a></li>
+<li class="isub2">Murray, <i>Sir</i> John, cited, <a href="#Page_75">75</a></li>
+
+<li class="isub2 ifrst">Newell, Frederick H., cited, <a href="#Page_75">75</a></li>
+<li class="isub2">Night-soil, <a href="#Page_108">108</a></li>
+<li class="isub2">Nitrates in agriculture, <a href="#Page_108">108</a></li>
+<li class="isub3">in soil solution, <a href="#Page_103">103</a></li>
+<li class="isub2">Nitrogen carriers, <a href="#Page_103">103</a></li>
+
+<li class="isub2 ifrst">“Official method” of soil analysis, <a href="#Page_10">10</a></li>
+<li class="isub2">Optimum moisture content, <a href="#Page_24">24</a></li>
+<li class="isub2">Organic compounds, Effect on plants, <a href="#Page_82">82</a></li>
+<li class="isub2">Organic constituents of soil solution, <a href="#Page_54">54</a>, <a href="#Page_79">79</a></li>
+<li class="isub2">Orthoclase, Alteration of, <a href="#Page_33">33</a></li>
+<li class="isub2">Ostwald, Wo., cited, <a href="#Page_28">28</a></li>
+<li class="isub2">Oxidizing power of roots, <a href="#Page_101">101</a></li>
+<li class="isub2">Oxygen in the soil, <a href="#Page_53">53</a></li>
+<li class="isub2">Oxystearic acid, Toxic to plants, <a href="#Page_96">96</a></li>
+
+<li class="isub2 ifrst">Patten, Harrison E., cited, <a href="#Page_24">24</a>, <a href="#Page_25">25</a>, <a href="#Page_60">60</a></li>
+<li class="isub3"><i>See</i> Cameron, Frank K., and Patten, Harrison E.</li>
+<li class="isub5">and Waggaman, William H., cited, <a href="#Page_9">9</a>, <a href="#Page_59">59</a></li>
+<li class="isub3">and Gallagher, F. E., cited, <a href="#Page_59">59</a></li>
+<li class="isub2">Pearce, Julia R. <i>See</i> Briggs, Lyman J., Martin, F. O., and Pearce, J. R.</li>
+<li class="isub2">Pember, F. R. <i>See</i> Hartwell, Burt L., Wheeler, H. J., and Pember, F. R.</li>
+<li class="isub2">Penfield, Samuel L., cited, <a href="#Page_13">13</a></li>
+<li class="isub2">Percolation experiments, <a href="#Page_47">47</a></li>
+<li class="isub2">Peter, Alfred, cited, <a href="#Page_54">54</a></li>
+<li class="isub3">and Averitt, S. D., cited, <a href="#Page_10">10</a></li>
+<li class="isub2">Pfeffer, Wilhelm F. P., cited, <a href="#Page_18">18</a>, <a href="#Page_72">72</a>,
+ <a href="#Page_73">73</a>, <a href="#Page_101">101</a></li>
+<li class="isub2">Phlogiston theory, <a href="#Page_17">17</a></li>
+<li class="isub2">Phosphates, <a href="#Page_50">50</a></li>
+<li class="isub2">Picoline carboxylic acid, toxic to plants, <a href="#Page_96">96</a></li>
+<li class="isub2">Plant-food theory, <a href="#Page_16">16</a></li>
+<li class="isub2">Plant growth and concentration, <a href="#Page_70">70</a></li>
+<li class="isub2">Plant nutrients, Supply and removal, <a href="#Page_75">75</a></li>
+<li class="isub2">Plot experiments, <a href="#Page_14">14</a></li>
+<li class="isub2">“Poor” and “good” soils compared, <a href="#Page_80">80</a></li>
+<li class="isub2">Pot experiments, <a href="#Page_14">14</a></li>
+<li class="isub2">Puddling, <a href="#Page_25">25</a></li>
+<li class="isub2">Pyrogallol, <a href="#Page_87">87</a></li>
+<li class="isub2">Pyrophyllite, <a href="#Page_34">34</a></li>
+
+<li class="isub2 ifrst">Ragweed, <a href="#Page_97">97</a>, <a href="#Page_98">98</a></li>
+<li class="isub2">Rainfall, <a href="#Page_22">22</a>, <a href="#Page_75">75</a>
+ <span class="pagenum" id="Page_133">[Pg 133]</span></li>
+<li class="isub2">Rajputana, Salt deposits, <a href="#Page_116">116</a></li>
+<li class="isub2">Rayleigh, Lord, cited, <a href="#Page_26">26</a></li>
+<li class="isub2">Reed, Howard S. <i>See</i> Schreiner, Oswald, and Reed, Howard S.;</li>
+<li class="isub5">Schreiner, Oswald, Reed, Howard S., and Skinner, J. J.</li>
+<li class="isub2">Removal of plant nutrients, Supply and, <a href="#Page_75">75</a></li>
+<li class="isub2">Reversible reactions, <a href="#Page_34">34</a></li>
+<li class="isub2">Ries, Heinrich, quoted, <a href="#Page_112">112</a></li>
+<li class="isub2">River waters, Concentration of, <a href="#Page_76">76</a></li>
+<li class="isub2">Robinson, William O. <i>See</i> Cameron, Frank K., and Robinson, William O.;</li>
+<li class="isub5">Cameron, Frank K., Bell, James M., and Robinson, W. O.</li>
+<li class="isub2">Rodewald, H., cited, <a href="#Page_24">24</a></li>
+<li class="isub2">Römer, Hermann. <i>See</i> Wilfarth, Hermann, Römer, Hermann, and Wimmer, G.</li>
+<li class="isub2">Root etchings, <a href="#Page_9">9</a></li>
+<li class="isub2">Root growth mechanism, <a href="#Page_19">19</a></li>
+<li class="isub2">Roots of growing plants, <a href="#Page_18">18</a></li>
+<li class="isub2">Rotation of crops, <a href="#Page_97">97</a></li>
+<li class="isub2">Rothmund, V., cited, <a href="#Page_68">68</a></li>
+<li class="isub2">“Run-off”, <a href="#Page_22">22</a>, <a href="#Page_75">75</a></li>
+<li class="isub2">Russell, Edward J., cited, <a href="#Page_103">103</a></li>
+<li class="isub3"><i>See also</i> Darbishire, Francis V., and Russell, Edward J.</li>
+<li class="isub5">and Hutchinson, Henry B, cited, <a href="#Page_72">72</a></li>
+
+<li class="isub2 ifrst">Sachs, Julius, Experiments on root etchings, <a href="#Page_9">9</a></li>
+<li class="isub2">Salt as fertilizer, Common, <a href="#Page_108">108</a></li>
+<li class="isub2">Sarasin, Edmond. <i>See</i> Friedel, Charles, and Sarasin, Edmond, <a href="#Page_34">34</a></li>
+<li class="isub2">Schmidmer, Edward. <i>See</i>, Fischer, Emil, and Schmidmer, Edward.</li>
+<li class="isub2">Schreiner, Oswald, quoted, <a href="#Page_102">102</a></li>
+<li class="isub6">and Failyer, George H., cited, <a href="#Page_41">41</a>, <a href="#Page_47">47</a></li>
+<li class="isub6">and Reed, Howard S., cited, <a href="#Page_100">100</a>, <a href="#Page_101">101</a></li>
+<li class="isub6">and Shorey, Edmund C., cited, <a href="#Page_95">95</a></li>
+<li class="isub6">and Sullivan, M. X., cited, <a href="#Page_100">100</a></li>
+<li class="isub6">Reed, Howard S., and Skinner. J. J., quoted, <a href="#Page_89">89</a></li>
+<li class="isub2">Sea water, Desiccation of, <a href="#Page_111">111</a></li>
+<li class="isub2">Seedlings, Growth of, <a href="#Page_74">74</a>, <a href="#Page_80">80</a>, <a href="#Page_82">82</a>,
+ <a href="#Page_84">84</a>, <a href="#Page_86">86</a>, <a href="#Page_88">88</a>,
+ <a href="#Page_100">100</a>, <a href="#Page_102">102</a></li>
+<li class="isub2">Seedlings, Toxic action of acids and salts, <a href="#Page_62">62</a></li>
+<li class="isub2">Seidell, Atherton, quoted, <a href="#Page_115">115</a></li>
+<li class="isub2">Shaler, Nathaniel S., cited, <a href="#Page_20">20</a></li>
+<li class="isub2">Shorey, Edmund C., cited, <a href="#Page_95">95</a></li>
+<li class="isub3"><i>See also</i> Schreiner, Oswald, and Shorey, E. C.</li>
+<li class="isub2">Shrinking of soils, <a href="#Page_22">22</a></li>
+<li class="isub2">Skinner, J. J., quoted, <a href="#Page_99">99</a>, <a href="#Page_102">102</a>
+ <span class="pagenum" id="Page_134">[Pg 134]</span></li>
+<li class="isub2">Skinner, J. J. <i>See also</i> Schreiner, Oswald, Reed, Howard S., and Skinner, J. J.</li>
+<li class="isub2">Slosson, Edwin E. <i>See</i> Knight, Wilbur C., and Slosson, Edwin E.</li>
+<li class="isub2">Smith, Joseph G., quoted, <a href="#Page_98">98</a></li>
+<li class="isub3"><i>See also</i> Failyer, George H., Smith, Joseph G., and Wade, H. R.</li>
+<li class="isub2">Sodium chloride as fertilizer, <a href="#Page_108">108</a></li>
+<li class="isub2">Soil, the, <a href="#Page_1">1</a></li>
+<li class="isub2">Soil amendments, <a href="#Page_105">105</a></li>
+<li class="isub3">analysis, Chemical, <a href="#Page_8">8</a>, <a href="#Page_22">22</a></li>
+<li class="isub5">Methods, <a href="#Page_10">10</a></li>
+<li class="isub3">atmosphere, <a href="#Page_23">23</a></li>
+<li class="isub3">bacteria, <a href="#Page_23">23</a>, <a href="#Page_103">103</a></li>
+<li class="isub3">control, <a href="#Page_4">4</a></li>
+<li class="isub5">methods, <a href="#Page_4">4</a></li>
+<li class="isub3">erosion, <a href="#Page_20">20</a></li>
+<li class="isub3">fatigue, <a href="#Page_100">100</a></li>
+<li class="isub3">heaving, <a href="#Page_22">22</a></li>
+<li class="isub3">individuality, <a href="#Page_2">2</a></li>
+<li class="isub3">management, <a href="#Page_2">2</a>, <a href="#Page_3">3</a>, <a href="#Page_4">4</a></li>
+<li class="isub3">minerals, Chief, <a href="#Page_32">32</a></li>
+<li class="isub3">moisture defined, <a href="#Page_1">1</a></li>
+<li class="isub3">not a static system, <a href="#Page_18">18</a></li>
+<li class="isub3">phenomena, Dynamic nature of, <a href="#Page_18">18</a></li>
+<li class="isub3">shrinking, <a href="#Page_22">22</a></li>
+<li class="isub3">solution defined, <a href="#Page_1">1</a></li>
+<li class="isub5">Analyses, <a href="#Page_39">39</a></li>
+<li class="isub5">Importance of, <a href="#Page_2">2</a></li>
+<li class="isub5">Organic constituent of, <a href="#Page_79">79</a></li>
+<li class="isub3">Survey Field Book, cited, <a href="#Page_3">3</a></li>
+<li class="isub3">translocation by water, <a href="#Page_20">20</a></li>
+<li class="isub5">wind, <a href="#Page_21">21</a></li>
+<li class="isub2">Soils, Composition of, <a href="#Page_1">1</a></li>
+<li class="isub3">Mineral constituents of, <a href="#Page_32">32</a></li>
+<li class="isub3">Moisture content, <a href="#Page_24">24</a></li>
+<li class="isub3">Water extracts of, <a href="#Page_39">39</a></li>
+<li class="isub2">Solid solution defined, <a href="#Page_59">59</a></li>
+<li class="isub2">Solubility of minerals, <a href="#Page_52">52</a>, <a href="#Page_55">55</a></li>
+<li class="isub2">Spring, Walthère, cited, <a href="#Page_67">67</a></li>
+<li class="isub2">Structure, <a href="#Page_27">27</a></li>
+<li class="isub2">Subsoils, Infertility of, <a href="#Page_88">88</a>
+ <span class="pagenum" id="Page_135">[Pg 135]</span></li>
+<li class="isub2">Sullivan, Michael X., cited, <a href="#Page_102">102</a></li>
+<li class="isub3">quoted, <a href="#Page_68">68</a></li>
+<li class="isub3"><i>See also</i> Schreiner, Oswald, and Sullivan, M. X.</li>
+<li class="isub2">Supply and removal of plant nutrients, <a href="#Page_75">75</a></li>
+<li class="isub2">Surface effects, <a href="#Page_67">67</a></li>
+<li class="isub2">Surface tension, <a href="#Page_27">27</a></li>
+<li class="isub2">Swan tract, Utah, <a href="#Page_123">123</a></li>
+<li class="isub2">Swingle, Walter T., cited, <a href="#Page_119">119</a></li>
+
+<li class="isub2 ifrst">Taylor, Frederick W., cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Tennessee agricultural experiment station,</li>
+<li class="isub5">Methods of soil analysis, <a href="#Page_10">10</a></li>
+<li class="isub2">Thorne, Charles E., cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Tillage methods, <a href="#Page_4">4</a></li>
+<li class="isub3">Objects of, <a href="#Page_4">4</a></li>
+<li class="isub2">Tollens, Bernhard C. G., cited, <a href="#Page_14">14</a></li>
+<li class="isub2">Toxic excreta of roots, <a href="#Page_99">99</a>, <a href="#Page_100">100</a>, <a href="#Page_103">103</a></li>
+
+<li class="isub2 ifrst">Udden, Johan August, quoted, <a href="#Page_21">21</a></li>
+<li class="isub2">U. S. Dept. of Agriculture, Bureau of Soils.</li>
+<li class="isub5"><i>See</i> Soil Survey Field Book.</li>
+<li class="isub2">U. S. Geological Survey, cited, <a href="#Page_13">13</a></li>
+<li class="isub2">Underdrainage, <a href="#Page_121">121</a></li>
+<li class="isub2">Utah Lake water analyses, <a href="#Page_115">115</a></li>
+
+<li class="isub2 ifrst">Van Hise, Charles R., cited, <a href="#Page_35">35</a>, <a href="#Page_36">36</a></li>
+<li class="isub2">van’t Hoff, Jakob H., cited, <a href="#Page_67">67</a>, <a href="#Page_111">111</a></li>
+<li class="isub2">Voorhees, Edward B., and Lipman, Jacob G., cited, <a href="#Page_72">72</a>, <a href="#Page_103">103</a></li>
+
+<li class="isub2 ifrst">Wade, Harold R. <i>See</i> Failyer, George H., Smith, Joseph G., and Wade, H. R.</li>
+<li class="isub2">Waggaman, William H. <i>See</i> Patten, Harrison E., and Waggaman, William H.</li>
+<li class="isub2">Walker, James, and Appleyard, James R., cited, <a href="#Page_60">60</a></li>
+<li class="isub2">Washington, Henry S., cited, <a href="#Page_13">13</a></li>
+<li class="isub2">Water, Movement into soils, <a href="#Page_28">28</a></li>
+<li class="isub3">vapor, Movement in soils, <a href="#Page_29">29</a></li>
+<li class="isub2">Way, John T., cited, <a href="#Page_9">9</a></li>
+<li class="isub2">Weeds, Analyses of, <a href="#Page_98">98</a></li>
+<li class="isub2">Weinschenk, E., cited, <a href="#Page_35">35</a></li>
+<li class="isub2">Wheeler, Homer J., cited, <a href="#Page_74">74</a></li>
+<li class="isub2">Wheeler, Homer J. <i>See also</i> Hartwell, Burt L., Wheeler, H. J., and Pember, F. R.</li>
+<li class="isub2">White alkali, <a href="#Page_110">110</a>, <a href="#Page_111">111</a></li>
+<li class="isub2">Whitney, Milton, cited, <a href="#Page_16">16</a></li>
+<li class="isub3">and Cameron, Frank K., cited, <a href="#Page_26">26</a>, <a href="#Page_42">42</a></li>
+<li class="isub2">Wilfarth, Hermann, Römer, Hermann, and Wimmer, G., cited, <a href="#Page_14">14</a>
+ <span class="pagenum" id="Page_136">[Pg 136]</span></li>
+<li class="isub2">Willard, Julius T., cited, <a href="#Page_5">5</a></li>
+<li class="isub2">Wimmer, G. <i>See</i> Wilfarth, Hermann, Römer, Hermann, and Wimmer, G.</li>
+<li class="isub2">Wind, <a href="#Page_20">20</a></li>
+<li class="isub3">Carrying power of, <a href="#Page_21">21</a></li>
+<li class="isub2">Wind-borne soil material, <a href="#Page_21">21</a>, <a href="#Page_33">33</a></li>
+<li class="isub2">Wöhler, Friedrich, cited, <a href="#Page_35">35</a></li>
+<li class="isub2">Wolff, Emil T. von, tables, cited, <a href="#Page_77">77</a></li>
+<li class="isub2">Woburn, Experiments at, <a href="#Page_98">98</a></li>
+
+<li class="isub2 ifrst">Young, Thomas, cited, <a href="#Page_26">26</a></li>
+
+<li class="isub2 ifrst">Zeolites, <a href="#Page_9">9</a>, <a href="#Page_34">34</a>, <a href="#Page_35">35</a></li>
+</ul>
+
+<hr class="chap x-ebookmaker-drop">
+<div class="chapter">
+ <p class="f200"><b>Scientific Books</b></p>
+</div>
+
+<p class="f150">Published by<br><b>THE CHEMICAL PUBLISHING COMPANY</b></p>
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+<p class="f120">EASTON, PA.</p>
+
+<table class="spb1">
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+ <td class="tdl" colspan="2"><span class="ws2"> Molecular Weights. (Translated by Jones).</span></td>
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+ </tbody>
+</table>
+
+<hr class="chap x-ebookmaker-drop">
+
+<div class="footnotes">
+<p class="f150"><b>Footnotes:</b></p>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_1_1" href="#FNanchor_1_1" class="label">[1]</a>
+By crop plants are meant the ordinary green plants employed in
+agriculture. As is well-known, the fungi as well as certain parasitic
+and saprophytic non-green seed plants obtain their nutriment in a very
+different way from ordinary green crop plants.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_2_2" href="#FNanchor_2_2" class="label">[2]</a>
+According to S. W. Johnson—Some points of agricultural
+science, Am. Jour. Sci. (2), <b>28</b>, 71-85 (1859)—“The soil
+(speaking in the widest sense) is then not only the ultimate
+exhaustless source of mineral (fixed) food, to vegetation, but it
+is the storehouse and conservatory of this food, protecting its own
+resources from waste and from too rapid use, and converting the highly
+soluble matters of animal exuviæ as well as of artificial refuse
+(manures) into permanent supplies.”</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_3_3" href="#FNanchor_3_3" class="label">[3]</a>
+For definitions, see Soil Survey Field Book, 1906, Bureau
+of Soils, U. S. Dept. of Agriculture, pp. 15-24. On the ground that
+experience has shown that genetic classifications are the ones which
+have generally persisted and proved the most useful, objection might be
+made to the classification just cited. But a careful inspection of the
+results of the Soil Survey by the U. S. Department of Agriculture will
+show that while not categorically stating the fact, to all intents and
+purposes it has employed a genetic classification. This is exemplified
+by the fact that its delineation of soil provinces corresponds quite
+closely with the recognized physiographic provinces of the United
+States. See map accompanying Soils of the United States, by Milton
+Whitney, Bull. No. <b>55</b> Bureau of Soils, U. S. Dept. Agriculture,
+1909.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_4_4" href="#FNanchor_4_4" class="label">[4]</a>
+Actually, to granulate the soil. “Fine” would seem to be a
+misnomer, but its agricultural significance is well understood, and it
+has the sanction of long usage in the literature.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_5_5" href="#FNanchor_5_5" class="label">[5]</a>
+In this connection see: The texture of the soil, by L.
+H. Bailey, Cornell University Agr. Expt. Sta., Bull. No. <b>119</b>
+(1896); Suggestions regarding the examination of lands, by E. W.
+Hilgard, University of California, College of Agriculture, Circ.
+No. <b>25</b>, (1906); Chemical analysis of soils, by William P.
+Brooks, Massachusetts Agr. Expt. Sta. Circ. No. <b>11</b>, (1907);
+Testing soils for fertilizer needs, by F. W. Taylor, New Hampshire
+Agr. Expt. Sta., Circ. No. <b>2</b>, (1908); The uses and limitations
+of soil analysis, by J. T. Willard, The Industrialist. Kansas State
+Agricultural College, <b>34</b>, 291, (1908); Soil analysis, by Wm.
+Frear, Pennsylvania Agr. Expt. Sta., Chem. Circ. No. <b>1</b>; How
+to determine the fertilizer requirements of Ohio soils, by Chas. E.
+Thorne, Ohio Agr. Expt. Sta., Circ. No. <b>79</b>, (1908); Concerning
+work which the station can and cannot undertake for residents of the
+state, by Joseph L. Hills, Vermont Agr. Expt. Sta., Circ. No. <b>3</b>,
+(1909).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_6_6" href="#FNanchor_6_6" class="label">[6]</a>
+Soils by E. W. Hilgard, 1906, p. 339, <i>et seq.</i></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_7_7" href="#FNanchor_7_7" class="label">[7]</a>
+It should, of course, be borne in mind that soil factors
+are not the only ones in crop production. Control by seed selection,
+breeding of standard types of plants, etc., may be, and probably is,
+more highly developed than control by soil factors. The same might
+possibly be claimed for moisture supply in irrigated areas; but on the
+other hand, such factors as the bacterial and lower life processes in
+the soil are generally under little or no control, and as a rule the
+amount and distribution of sunlight under none at all. A notable effort
+has been made in the last case with shade-grown tobacco (see Bulletins
+Nos. 20 and 39, Bureau of Soils, U. S. Dept. Agriculture) and a few
+cases are known where shade-crops are employed, but not in general
+agriculture.</p></div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_8_8" href="#FNanchor_8_8" class="label">[8]</a>
+See also, Die Aufnahme der Nährstoffe aus dem Boden durch die Pflanzen,
+von J. König und E. Haselhoff, Landw. Jahrb., 23, 1009, 1030,
+(1894).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_9_9" href="#FNanchor_9_9" class="label">[9]</a>
+Way was misled, as we now know, in considering the results of his
+absorption experiments with soils as merely metathetical reactions; see
+Absorption by soils, by Harrison E. Patten and William H. Waggaman,
+Bull. No. <b>52</b>, Bureau of Soils, U. S. Dept. Agriculture,
+1908.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_10_10" href="#FNanchor_10_10" class="label">[10]</a>
+The formation of zeolites in the soil has often been assumed, but has
+not yet been proven; see Rocks, rock-weathering and soils, by George P.
+Merrill, 1906, p. 363.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_11_11" href="#FNanchor_11_11" class="label">[11]</a>
+The classic experiments of Sachs, in producing etchings on marble
+slabs, and the etchings observed occasionally on rock surfaces are the
+proofs universally cited. The experiments of Czapek, who substituted
+slabs of aluminum phosphate and other substances for the marble, and
+those of Kossowitch, show that the action can be accounted for more
+satisfactorily and reasonably as due to dissolved carbon dioxide. In
+fact such etchings can be produced on marble slabs by laying platinum
+wires upon them and covering with moist soil, or cotton, or mats of
+filter-paper; see Bull. No. <b>22</b>, p. 14, and Bull. No. <b>30</b>,
+p. 41, Bureau of Soils, U. S. Dept. Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_12_12" href="#FNanchor_12_12" class="label">[12]</a>
+Soils, by A. M. Peter and S. D. Averitt, Bull. No. 126, p.
+66, (1906).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_13_13" href="#FNanchor_13_13" class="label">[13]</a>
+The soils of Tennessee, by Charles A. Mooers, Bull. No. 78,
+p. 49, (1906).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_14_14" href="#FNanchor_14_14" class="label">[14]</a>
+Proceedings of the Twelfth Annual Convention of the Association of
+Official Agricultural Chemists, Bull. No. 47, Division of Chemistry, U.
+S. Dept. Agriculture, p. 36, (1896).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_15_15" href="#FNanchor_15_15" class="label">[15]</a>
+See: On the interpretation of mineral analyses, by S. L. Penfield,
+Amer. Jour. Sci., (4), 10, 33, (1900); The analysis of silicate and
+carbonate rocks, by W. F. Hillebrand, Bull. No. 305. U. S. Geol.
+Surv., 1907; Manual of the chemical analysis of rocks, by H. S.
+Washington, 1904, p. 24; Über Genauigkeit von Gesteinanalysen, von M.
+Dittrich, Neues Jahrbuch für Mineralogie und Palaeontologie, 2, 69,
+(1903).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_16_16" href="#FNanchor_16_16" class="label">[16]</a>
+For a brief but comprehensive discussion of ash analyses see, The ash
+constituents of plants, etc., by B. Tollens, Expt. Sta. Rec., 13,
+207-220, 305-317, (1901-02).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_17_17" href="#FNanchor_17_17" class="label">[17]</a>
+Über die Nährstoffaufnahme der Pflanzen in verschiedenen Zeiten ihres
+Wachstums, von Wilfarth, Römer und Wimmer. Landw. Vers. Sta., 63, 1-70,
+(1905); Plant food removed from growing plants by rain or dew, by J. A.
+Le Clerc and J. F. Breazeale, Year Book, U. S. Dept. Agriculture, 1908,
+p. 389-402.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_18_18" href="#FNanchor_18_18" class="label">[18]</a>
+A study of crop yields and soil composition in relation to soil
+productivity, by Milton Whitney, Bull. No. 57, Bureau of Soils, U. S.
+Dept. Agriculture, 1909.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_19_19" href="#FNanchor_19_19" class="label">[19]</a>
+In order to penetrate the soil, a living root must be
+capable of exerting large pressures, and indeed, the magnitude of these
+pressures has been determined for some cases. See, for citations of the
+literature, Pfeffer, Plant Physiology, translated by Ewart, 1903, Vol.
+2, p. 124 <i>et seq.</i> But it can not be doubted that, in general,
+root movement is much facilitated and perhaps directed by movements
+among the soil particles. As the absorbing tip of the root removes film
+water from the adjacent soil grains, there is a necessary rearrangement
+of these grains with a shrinking away from the tip, which then moves
+forward by taking advantage of the movements among the soil grains.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_20_20" href="#FNanchor_20_20" class="label">[20]</a>
+Soil erosion is undoubtedly one of the greatest economic problems of
+the time, and yet there is scarcely any subject about which there are
+current so many popular misconceptions. In the rivers and to those
+who use the rivers the water-borne soil material is an unmitigated
+nuisance, save possibly to a few cultivators of low-lying lands who
+for one reason or another, may flood their fields for the sake of the
+silt deposited. To the upland farmer, however, erosion is not only a
+necessity of natural conditions which can not be avoided entirely, but
+under proper control it may be even a blessing. The scalded and gullied
+hillsides, a trial and unnecessary disgrace to the owner, are probably
+not the main sources of the material which finds its way to the river.
+On the contrary, what are regarded usually as well-tilled fields supply
+the greater part of the suspended material in the rivers. The problem
+of erosion on the farm is not merely to check gullying and scalding,
+and deepening of stream heads, but to so adjust both cropping system
+and cultural methods as to secure a reasonable translocation of surface
+soil material with a minimum contamination of the neighborhood streams.
+See, Man and the earth, by Nathaniel Southgate Shaler, 1905.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_21_21" href="#FNanchor_21_21" class="label">[21]</a>
+For a comprehensive discussion of wind as a translocating agent, see:
+The movement of soil material by the wind, by E. E. Free, Bureau of
+Soils, Bull. No. 68, U. S. Dept. Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_22_22" href="#FNanchor_22_22" class="label">[22]</a>
+Erosion, transportation and sedimentation performed by the
+atmosphere, by J. A. Udden, Jour. Geol., 2, 318-331 (1894).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_23_23" href="#FNanchor_23_23" class="label">[23]</a>
+On the small vertical movements of a stone laid on the
+surface of the ground, by Horace Darwin, Proceedings of the Royal
+Society of London, 68, 253-261, (1901). On the other hand, geological
+literature would probably furnish numerous references to the heaving
+out of boulders, probably as the result of successive freezings and
+thawings of the soil. The shape of the stone as well as the specific
+nature of the movements of the soil particles evidently has an
+important influence in determining whether the stone sinks into the
+soil or <i>vice versa</i>.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_24_24" href="#FNanchor_24_24" class="label">[24]</a>
+It is clear that as the soil is continually changing
+through physical agencies, the chemical analysis of it can not be
+expected to furnish evidence as to the mineral constituents removed by
+crops or by leaching.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_25_25" href="#FNanchor_25_25" class="label">[25]</a>
+This terminology has been suggested by Dr. W. J. McGee.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_26_26" href="#FNanchor_26_26" class="label">[26]</a>
+Leather, however, thinks the water returns from only a limited depth,
+some 5-7 feet; see, The loss of water from soil during dry weather,
+by J. Walter Leather, Memoirs of the Department of Agriculture,
+Agricultural Research Institute, Pusa, India, Chemical series, I,
+79-116, (1908). Dr. George N. Coffey has called the author’s attention
+to some observations in Western Kansas, where a prolonged drought had
+dried the soil to a considerable depth. A fairly heavy rain wetted the
+soil to less than two feet from the surface, and practically all of
+this moisture had returned to the surface and evaporated within a few
+days. Such special cases as these, however interesting in themselves,
+are even less so than the normal cases in humid areas, where a part
+of the water passes through the soil as seepage, the larger portion
+returning to the surface, sometimes through distances of many feet.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_27_27" href="#FNanchor_27_27" class="label">[27]</a>
+See, in this connection, Energy changes accompanying absorption, by
+Harrison E. Patten, Trans. Am. Electrochem. Soc., 11, 387-407, (1907);
+see also the recent valuable research, Les dégagements de chaleur
+qui se produisent an contact de la terre sèche et de l’eau, par A.
+Muntz et H. Gaudechon, Ann. sci. agron. (3), 4, II, 393-443, (1909),
+where it is shown that probably a part of the heat is due to chemical
+combination between the water and the other soil components. To quote,
+“Ces diverses observations nous conduisent à penser, sans nous en
+donner toutefois la preuve absolute, que la fixation de l’eau sur les
+éléments terreux très fins et sur les matériaux organisés, est tout
+au moins, en partie, attribuable à une combinaison chimique qui se
+manifeste non seulement par un fort dégagement de chaleur, mais aussi
+par la soustraction de l’eau à des substances aux-quelles elle semble
+chimiquement liée.”</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_28_28" href="#FNanchor_28_28" class="label">[28]</a>
+The moisture content and physical condition of soils, by
+Frank K. Cameron and Francis E. Gallagher, Bull. No. 50, Bureau of
+Soils, U. S. Dept. of Agriculture, 1908. See also Über physikalische
+Bodenuntersuchung, von H. Rodewald, Schriften Naturwiss. Vereins
+Schleswig-Holstein, 14, 397-399, (1909).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_29_29" href="#FNanchor_29_29" class="label">[29]</a>
+Heat transference in soils, by Harrison E. Patten, Bull.
+No. 59, Bureau of Soils, U. S. Dept. Agriculture, 1909.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_30_30" href="#FNanchor_30_30" class="label">[30]</a>
+The chemistry of the soil as related to crop production, by Milton
+Whitney and Frank K. Cameron, Bull. No. 22, Bureau of Soils, U. S.
+Dept. Agriculture, 1903, p. 54.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_31_31" href="#FNanchor_31_31" class="label">[31]</a>
+The moisture equivalent of soils, by Lyman J. Briggs and John W.
+McLane, Bull. No. 45, Bureau of Soils, U. S. Dept. Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_32_32" href="#FNanchor_32_32" class="label">[32]</a>
+Über die beim Benetzen fein verteilter Körper auftretende Wärmetönung,
+von Lagergren, Bihang till K. sv. Vet.-Akad., Handl., 24, Afd. II, No.
+5, (1898).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_33_33" href="#FNanchor_33_33" class="label">[33]</a>
+Hydrostatics and elementary hydrokinetics, George M.
+Minchin, p. 311, 1892.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_34_34" href="#FNanchor_34_34" class="label">[34]</a>
+On the theory of surface forces, by Lord Rayleigh, Phil.
+Mag. (5), 30, 285-298, 456-475, (1890).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_35_35" href="#FNanchor_35_35" class="label">[35]</a>
+Equally unsuccessful is the attempt to correlate flocculating agents
+with changes in the density of water. See, The condensation of water by
+electrolytes, by F. K. Cameron and W. O. Robinson, Jour. Phys. Chem.,
+14, 1-11, (1910).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_36_36" href="#FNanchor_36_36" class="label">[36]</a>
+See Bull. No. <b>30</b>, Bureau of Soils, U. S. Dept. Agriculture,
+p. 50 <i>et seq.</i>; also, The flow of liquids through capillary
+spaces, by J. M. Bell and F. K. Cameron, Jour. Phys. Chem., <b>10</b>,
+659, (1906); See also, Wo. Ostwald, 2 Supplementheft Zeitschrift
+Kolloidchemie, 1908, 20.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_37_37" href="#FNanchor_37_37" class="label">[37]</a>
+Computed from observations by Loughridge, Report Agr.
+Expt. Sta., University California, 1893-94, p. 93.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_38_38" href="#FNanchor_38_38" class="label">[38]</a>
+Sur la diffusion des engrais salins dans le terre, par
+Muntz et Gaudechon, Comptes rendus, <b>148</b>, 253-258, (1909).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_39_39" href="#FNanchor_39_39" class="label">[39]</a>
+See, Contribution to our knowledge of the aeration of soils, and
+Studies of the movement of soil moisture, by Edgar Buckingham, Bulls.
+Nos. <b>25</b>, 1904, and <b>33</b>, 1907, Bureau of Soils, U. S. Dept.
+of Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_40_40" href="#FNanchor_40_40" class="label">[40]</a>
+For a more detailed discussion and citations of the literature, see
+The mineral constituents of the soil solution, by Frank K. Cameron
+and James M. Bell, Bull. No. <b>30</b>, Bureau of Soils, U. S. Dept.
+Agriculture, 1905.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_41_41" href="#FNanchor_41_41" class="label">[41]</a>
+Centrifugal methods of mechanical soil analysis, by L. J. Briggs, F. O.
+Martin and J. R. Pearce, Bull. No. <b>24</b>, Bureau of Soils, U. S.
+Dept. Agriculture, 1904.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_42_42" href="#FNanchor_42_42" class="label">[42]</a>
+See, The mineral composition of soil particles, by G. H. Failyer, J.
+G. Smith and H. R. Wade, Bull. No. <b>54</b>, Bureau of Soils, U. S.
+Dept. Agriculture, 1909. Recent improvements in microscope methods
+make it possible to identify without serious trouble the mineral
+content of silts with a diameter as low as 0.005 mm., and many even
+of the clay particles have recently been determined with satisfactory
+accuracy.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_43_43" href="#FNanchor_43_43" class="label">[43]</a>
+See Bull. No. <b>30</b>, Bureau of Soils, U. S. Dept. Agriculture, 1905, p. 9.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_44_44" href="#FNanchor_44_44" class="label">[44]</a>
+See Ueber die Bildung von Bauxit und verwandte Mineralien,
+von A. Liebrich, Zeit. prakt. Geol., <b>1897</b>, 212-214.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_45_45" href="#FNanchor_45_45" class="label">[45]</a>
+Sur la reproduction par voie aqueuse du feldspath orthose,
+par Friedel et Sarasin, Comptes rendus, <b>92</b>, 1374, (1881).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_46_46" href="#FNanchor_46_46" class="label">[46]</a>
+Note sur une observation de Fournet, concernant la production des
+zéolites a froid, par F. Gonnard, Bull. Soc. min. France, <b>5</b>,
+267-269, (1882); Jahrb. Min., <b>1884</b>. I, Ref. 28.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_47_47" href="#FNanchor_47_47" class="label">[47]</a>
+Metathetical reactions with artificial zeolites, by A. Doroshevskii and
+A. Bardt, Jour. Russ. Phys. Chem. Soc., <b>42</b>, 435-42 (1910). Chem.
+Zentr., 1910, II, 68.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_48_48" href="#FNanchor_48_48" class="label">[48]</a>
+Beiträge zur Mineralsynthesis, von E. Weinschenk, Zeit. Kryst.,
+<b>17</b>, 489-504, (1890).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_49_49" href="#FNanchor_49_49" class="label">[49]</a>
+U. S. Geol. Surv. Monograph, <b>47</b>, A treatise on metamorphism,
+by Charles R. Van Hise, 1904, p. 333.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_50_50" href="#FNanchor_50_50" class="label">[50]</a>
+Jahresb. Fortschr. Chemie Liebig and Kopp, <b>1847-48</b>, 1262; note.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_51_51" href="#FNanchor_51_51" class="label">[51]</a>
+Ueber Silicatumwandlungen, von J. Lemberg, Zeit. deutsch. geol. Ges.,
+<b>28</b>, 519-621, (1876); Inaug. diss. Dorpat, <b>1877</b>; Bied.
+Centbl., <b>8</b>, 567-577, (1879).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_52_52" href="#FNanchor_52_52" class="label">[52]</a>
+Solutions of silicates of the alkalis, by L. Khlenberg and A. T. Lincoln,
+Jour. Phys. Chem., <b>2</b>, 77-90, (1898).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_53_53" href="#FNanchor_53_53" class="label">[53]</a>
+Van Hise, loc. cit., p. 693.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_54_54" href="#FNanchor_54_54" class="label">[54]</a>
+A gel is a jelly-like substance, apparently continuous, which
+forms either by the settling from suspension in a liquid of very
+fine particles which then become aggregated; or, is formed by the
+evaporation of a liquid containing fine particles in suspension until
+the quantity of liquid remaining is just sufficient to serve as a
+cementation medium holding the suspended particles together in a
+semi-rigid mass. For an experimental demonstration of the formation
+of such a gel, see, The effect of water on rock powders, by Allerton
+S. Cushman, Bull. No. <b>92</b>, Bureau of Chemistry, U. S. Dept.
+Agriculture, 1905.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_55_55" href="#FNanchor_55_55" class="label">[55]</a>
+In making such experiments in the laboratory or in lecture
+demonstrations, it is well to have the mass of water large in
+comparison with the mass of powdered mineral or rock; otherwise
+secondary adsorption effects may occur and obscure the results of the
+hydrolysis.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_56_56" href="#FNanchor_56_56" class="label">[56]</a>
+Feldspars certainly, and phosphorites possibly, are mineral components
+of the soil; and these substances when ground sufficiently fine have
+been added to soils with sometimes an increased production of crop.
+Other minerals, such as leucite, have given similar results. But also
+apparently pure quartz sand sometimes accomplishes the same results,
+as for example, in the experiments of Hilgard cited above. It has not
+been shown, however, that the addition of any of these substances
+produces an appreciable change in the concentration of the soil
+solution.</p></div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_57_57" href="#FNanchor_57_57" class="label">[57]</a>
+The action of water and aqueous solutions upon soil phosphates, by
+Frank K. Cameron and James M. Bell, Bull. No. <b>41</b>, Bureau of
+Soils, U. S. Dept. of Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_58_58" href="#FNanchor_58_58" class="label">[58]</a>
+In this connection it is interesting to note that recent investigations
+on the proportions of phosphoric acid, potassium and nitrates in
+cultural solutions best adapted to the growth of wheat, give the same
+ratio of phosphoric acid to potassium as the figures just cited show to
+exist normally in the soil solution.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_59_59" href="#FNanchor_59_59" class="label">[59]</a>
+For the literature of the earlier work on the composition of aqueous
+extracts of soils, see: How crops feed, by Samuel W. Johnson, 1890,
+p. 309 <i>et seq.</i>; see also. On the analytical determination of
+probably available “mineral” plant-food in soils, by Bernard Dyer,
+Jour. Chem. Soc. <b>65</b>, 115-167, (1894); and Soils, by E. W.
+Hilgard, 1906, p. 327 <i>et seq.</i></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_60_60" href="#FNanchor_60_60" class="label">[60]</a>
+Capillary studies and filtration of clays from soil solutions, by Lyman
+J. Briggs and Macy H. Lapham, Bull. No. <b>19</b>, Bureau of Soils.
+U. S. Dept. Agriculture, 1902; Colorimetric, turbidity and titration
+methods used in soil investigations, by Oswald Schreiner and George H.
+Failyer, Bull. No. <b>31</b>, Bureau of Soils, U. S. Dept. Agriculture, 1906.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_61_61" href="#FNanchor_61_61" class="label">[61]</a>
+The chemistry of the soil as related to crop production, by Milton
+Whitney and F. K. Cameron, Bull. No. <b>22</b>, Bureau of Soils, U. S.
+Dept. Agriculture, 1903.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_62_62" href="#FNanchor_62_62" class="label">[62]</a>
+King, however, claims that the concentration of the soil solution
+with respect to mineral plant nutrients, is higher in the soils of
+the northern states than in the soils of the South Atlantic states.
+See: Some results of investigations in soil management, by F. H. King,
+Yearbook, U. S. Dept. Agriculture, 1903, p. 159-174. Bailey E. Brown
+has obtained some preliminary results which suggest that there may
+be seasonal variations with respect to some of the dissolved mineral
+constituents. See, Annual Report of the Pennsylvania State Experiment
+Station, 1908-9, pp. 31 <i>et seq.</i></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_63_63" href="#FNanchor_63_63" class="label">[63]</a>
+The absorption of phosphates and potassium by soils, by Oswald
+Schreiner and George H. Failyer, Bull. No. <b>32</b>, Bureau of Soils,
+U. S. Dept. Agriculture, 1906.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_64_64" href="#FNanchor_64_64" class="label">[64]</a>
+For reference to the literature and detailed discussion see: The action
+of water and aqueous solutions upon soil phosphates, by F. K. Cameron
+and J. M. Bell, Bull. No. <b>41</b>, Bureau of Soils, U. S. Dept.
+Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_65_65" href="#FNanchor_65_65" class="label">[65]</a>
+For references to the literature see Bull. No. <b>30</b>, Bureau of
+Soils, U. S. Dept. of Agriculture; also, The action of carbon dioxide
+under pressure upon a few metal hydroxides at 0° C., by F. K. Cameron
+and W. O. Robinson, Jour. phys. chem., <b>12</b>, 561-573, (1908); The
+influence of colloids and fine suspensions on the solubility of gases
+in water, Part I. Solubility of carbon dioxide and nitrous oxide, by
+Alexander Findlay and Henry Jermain Maude Creighton, Trans. Chem. Soc.,
+<b>97</b>, 536-561, (1910).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_66_66" href="#FNanchor_66_66" class="label">[66]</a>
+See, for instance, the results obtained by Peter, Proceedings of the
+19th Annual Convention of the Association of American Agricultural
+Colleges and Experiment Stations, Bull. No. <b>164</b>, Office of
+Experiment Stations, U. S. Dept. Agriculture, 1906, p. 151 <i>et seq.</i></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_67_67" href="#FNanchor_67_67" class="label">[67]</a>
+See, for example, Umwandlung des Feldspars in Sericit (Kaliglimmer)
+von Carl Benedick, Bull. Geol. Inst. Upsala, <b>7</b>, 278-286, (1904).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_68_68" href="#FNanchor_68_68" class="label">[68]</a>
+See Electrical instruments for determining the moisture, temperature
+and soluble salt content of soils, by L. J. Briggs, Bull. No. 15, and
+the electric bridge for the determination of soluble salts in soils, by
+R. O. E. Davis and H. Bryan, Bull. No. <b>61</b>, Bureau of Soils, U.
+S. Dept. Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_69_69" href="#FNanchor_69_69" class="label">[69]</a>
+For detailed description of the apparatus and experimental data, see
+Bull. No. <b>30</b>, p. 27, <i>et seq.</i>, Bureau of Soils, U. S.
+Dept. Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_70_70" href="#FNanchor_70_70" class="label">[70]</a>
+For a detailed discussion and citations of the literature, see:
+Absorption of vapors and gases by soils, by H. E. Patten and F. E.
+Gallagher, Bull. No. <b>51</b>; and Absorption by soils, by H. E.
+Patten and W. H. Waggaman, Bull. No. <b>52</b>, Bureau of Soils, U. S.
+Dept. Agriculture, 1908.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_71_71" href="#FNanchor_71_71" class="label">[71]</a>
+That is, a homogeneous solid, which may be either crystalline or
+amorphous. Probably the readiest criterion for distinguishing between
+a definite compound and a solid solution, is that the former is stable
+in contact with a liquid solution of its constituents over a measurable
+range of concentrations, while the composition of the solid solution
+changes with every change in the concentration of the liquid solution
+in contact with it.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_72_72" href="#FNanchor_72_72" class="label">[72]</a>
+A clear and apparently indisputable case of adsorption has been noted
+by Patten (Some surface factors affecting distribution, Trans. Am.
+Electrochem. Soc., <b>10</b>, 67-74, (1906). On adding powdered quartz
+to an aqueous solution of gentian violet, there is a distribution of
+the dye between the water and the quartz. A microscopic examination of
+the latter showed that the dye was concentrated in thin layers upon the
+surface of the quartz grains, from which it could be washed with water,
+no change in the quartz grains being noticeable.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_73_73" href="#FNanchor_73_73" class="label">[73]</a>
+Absorption of dilute acids by silk, by James Walker and
+James R. Appleyard, Jour. Chem. Soc., <b>69</b>, 1334-1349, (1896).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_74_74" href="#FNanchor_74_74" class="label">[74]</a>
+For a number of interesting examples, see, Ueber das Aufsteigen von
+Salzlösungen in Filtrirpapier, von Emil Fischer und Edward Schmidmer,
+Liebig’s Annalen der Chemie, <b>272</b>, 156-169, (1893).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_75_75" href="#FNanchor_75_75" class="label">[75]</a>
+The prompt absorption of a base by soils is shown by the following
+experiment: To some freshly boiled distilled water add several drops
+of alcoholic phenolphthalein, and then just enough base to produce
+a decided red color. If the solution be now passed through a short
+column of soil, cotton, shredded filter-paper or similar absorbent, the
+percolate will be perfectly colorless. The red color will be restored,
+however, by adding a little of the base to the percolate.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_76_76" href="#FNanchor_76_76" class="label">[76]</a>
+See, The toxic action of acids and salts on seedlings, by F. K. Cameron
+and J. F. Breazeale, Jour. Phys. Chem., <b>8</b>, 1-13, (1904). It
+is quite conceivable, for instance, that if the drainage conditions
+were not exceptionally good under a heavy type of soil, it might be
+rendered temporarily unfit for clover or alfalfa by a heavy application
+of potassium salts or of sodium nitrate. The idea put forward by some
+authorities that too long continued or over fertilizing renders soils
+acid, may have better foundation than their theoretical reasoning would
+seem to warrant.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_77_77" href="#FNanchor_77_77" class="label">[77]</a>
+That mineral fertilizers have a decided influence on the granulation
+of soils and the properties dependent thereon, and that this is of
+practical importance, is gradually coming to be recognized; see, for
+instance, Ein Beitrag zur Kenntnis der Wirkung künstlicher Dünger auf
+die Durchlässigkeit des Bodens für Wasser, von Edwin Blanck, Landw.
+Jahrb., <b>38</b>, 863-869, (1909), and the literature there cited.
+Dr. R. O. E. Davis in a yet unpublished investigation has shown that
+the addition of soluble salts produces decided effects upon the
+soil-moisture relations which affect crop production. The critical
+moisture content is displaced, the penetrability, permeability,
+specific volume, vapor tension, etc., are affected in measurable
+degree, and it appears that the physical functions of mineral
+fertilizers are much greater in amount and importance than has been
+popularly assumed.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_78_78" href="#FNanchor_78_78" class="label">[78]</a>
+The distribution of solute between water and soil, by F. K. Cameron and
+H. E. Patten, Jour. Phys. Chem., <b>11</b>, 581-593, (1907).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_79_79" href="#FNanchor_79_79" class="label">[79]</a>
+See formula, <a href="#Page_28">page 28.</a></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_80_80" href="#FNanchor_80_80" class="label">[80]</a>
+See formula, <a href="#Page_47">page 47.</a></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_81_81" href="#FNanchor_81_81" class="label">[81]</a>
+An extreme case is worth citing in this connection. Mr. W. H. Heileman
+in studying the influence of various kinds of alkali upon plant growth,
+added from 3-4 per cent. of sodium carbonate to soils known to be
+otherwise free from alkali. Wheat seedlings grown in the soils so
+treated showed no ill effects from the added salt. When distilled water
+was percolated slowly through the soils, or shaken up with them, the
+resulting solution contained the merest traces of the alkali.</p>
+
+<p>The ordinary method of determining the lime requirement of a soil
+by adding lime water until the solution shows an alkaline reaction,
+is another obvious absorption phenomenon, and is not dependent, as
+popularly supposed, upon the presence of acids in the soil. Soils which
+by no possibility could contain any free acid, frequently absorb very
+large amounts of lime in this manner.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_82_82" href="#FNanchor_82_82" class="label">[82]</a>
+Usually, in the growing season, the soil solution has a much higher
+concentration with respect to nitrates in the morning than it has in
+the evening.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_83_83" href="#FNanchor_83_83" class="label">[83]</a>
+For references to the literature see, Bull. No. <b>30</b>, Bureau of
+Soils, U. S. Dept. Agriculture, p. 61 <i>et seq.</i></p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_84_84" href="#FNanchor_84_84" class="label">[84]</a>
+Note sur les réductions métalliques produites dans les espaces
+capillaires, par M. Becquerel, Comptes rendus, <b>82</b>, 354-356, (1876).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_85_85" href="#FNanchor_85_85" class="label">[85]</a>
+Effects of animal charcoal on solutions, by T. Graham,
+Quart. Jour. Sci., <span class="allsmcap">I</span>, 120-125, (1830).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_86_86" href="#FNanchor_86_86" class="label">[86]</a>
+Über eine Zunahme chemischer Energie an der freien Oberfläche flüssiger
+Körper, von W. Spring, Zeit. physik. Chem., <b>4</b>, 658-662, (1889).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_87_87" href="#FNanchor_87_87" class="label">[87]</a>
+See especially, Beziehungen zwischen Oberflächenspannung und
+Löslichkeit, von G. A. Hulett, Zeit. Phys. Chem., <b>37</b>, 385-406,
+(1901). Löslichkeit und Löslichkeits Beeinflussung, von V. Rothmund, p.
+109, (1907); Principles théoretiques des methodes d’analyse minerale,
+par G. Chesneau, p. 16-25, (1906).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_88_88" href="#FNanchor_88_88" class="label">[88]</a>
+Wasserculturversuche mit Hafer, von Dr. Birner und Dr.
+Lucanus, Landw. Vers.-Sta., <b>8</b>, 128-177, (1866).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_89_89" href="#FNanchor_89_89" class="label">[89]</a>
+Effect of the concentration of the nutrient solution upon wheat
+cultures, by J. F. Breazeale, Science, n. s., <b>22</b>, 146-149, (1905).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_90_90" href="#FNanchor_90_90" class="label">[90]</a>
+See: The fixation of atmospheric nitrogen by bacteria, by J. G. Lipman,
+Bull. No. <b>81</b>, Bureau of Chemistry, U. S. Dept. of Agriculture,
+1904; A review of investigations in soil bacteriology, by Edward
+B. Voorhees and Jacob G. Lipman, Bull. No. <b>194</b>, Office of
+Experiment Stations, U. S. Dept. of Agriculture, 1907; The physiology
+of plants, by W. Pfeffer, translated by A. J. Ewart, vol.
+<span class="allsmcap">I</span>, p. 388 <i>et seq.</i>, 1900; The effect
+of partial sterilization of soil on the production of plant food, by
+Edward John Russell and Henry Brougham Hutchinson, Jour. Agric. Sci.,
+<b>3</b>, 111-144, (1909).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_91_91" href="#FNanchor_91_91" class="label">[91]</a>
+For a more detailed discussion of this subject, and the
+functions of the several ash constituents in plant nutrition, see: The
+physiology of plants, by W. Pfeffer, translated by A. J. Ewart, vol.
+<span class="allsmcap">I</span>, p. 410, <i>et seq.</i>, 1900.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_92_92" href="#FNanchor_92_92" class="label">[92]</a>
+The effect of the addition of sodium to deficient amounts
+of potassium, upon the growth of plants in both water and sand culture,
+by B. L. Hartwell, H. J. Wheeler and F. R. Pember, Report Rhode Island
+Agricultural Experiment Station, 1906-7, p. 299-357.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_93_93" href="#FNanchor_93_93" class="label">[93]</a>
+On the total annual rainfall on the land of the globe, and the relation
+of rainfall to the annual discharge of rivers, by Sir John Murray,
+Scot. Geog. Mag., <b>3</b>, 65-77, (1887).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_94_94" href="#FNanchor_94_94" class="label">[94]</a>
+Textbook of Geology, by Sir Archibald Geikie, p. 484, (1903).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_95_95" href="#FNanchor_95_95" class="label">[95]</a>
+<i>In</i> Principles and conditions of the movements of ground water,
+by F. H. King, Ann. rept. U. S. Geol. Surv., <b>19</b>, II, 59-294, (1897-98).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_96_96" href="#FNanchor_96_96" class="label">[96]</a>
+Estimated from data in Bull. No. 330, U. S. Geological Survey, The data
+of geochemistry, by Frank Wigglesworth Clarke, 1908, p. 53-90.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_97_97" href="#FNanchor_97_97" class="label">[97]</a>
+The latest authoritative statement is that the average annual
+rainfall of the United States is 29.4 inches; see: Water Resources,
+by W. J. McGee, vol. 1, p. 39-49, and Distribution of rainfall, by
+Henry Gannett, vol. 2, p. 10-12, Report of the National conservation
+commission, Senate doc. No. 676, 60th Congress, 2d session, 1909.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_98_98" href="#FNanchor_98_98" class="label">[98]</a>
+King: loc. cit., p. 85.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_99_99" href="#FNanchor_99_99" class="label">[99]</a>
+Estimated from Wolff’s tables, How crops grow, by Samuel W. Johnson,
+1890, appendix.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_100_100" href="#FNanchor_100_100" class="label">[100]</a>
+See, for instance: Investigations in soil management, by F. H. King,
+Madison, Wis., 1904, p. 62 <i>et seq.</i> This tendency towards a
+higher content of absorbed soluble mineral matter in the surface soil
+has been amply confirmed by other experiments. It has been advanced
+as an argument against the assumption that the hydrolysis of the soil
+minerals is a reversible process. But as pointed out elsewhere in the
+text, many of the soil minerals can be made in the wet way at more or
+less elevated temperatures and the more rational explanation is simply
+that at ordinary temperatures the rate of formation is exceedingly slow.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_101_101" href="#FNanchor_101_101" class="label">[101]</a>
+The success of this and of many of the following experiments was
+due in large measure to the skill and patience of Mr. James E. Breazeale.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_102_102" href="#FNanchor_102_102" class="label">[102]</a>
+Further studies on the properties of unproductive soils,
+B. E. Livingston <i>et al.</i>, Bull. <b>36</b>, 1907, and <b>48</b>,
+1908, Bureau of Soils, U. S. Dept. Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_103_103" href="#FNanchor_103_103" class="label">[103]</a>
+Physiological Properties of Bog Water, by B. E. Livingston, Bot. gaz.,
+<b>39</b>, 348-355, (1905).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_104_104" href="#FNanchor_104_104" class="label">[104]</a>
+The toxic property of bog water and bog soil, by Alfred Dachnowski,
+Bot. gaz., <b>46</b>, 130-143, (1908).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_105_105" href="#FNanchor_105_105" class="label">[105]</a>
+Certain organic constituents of soils in relation to soil fertility, by
+Oswald Schreiner and Howard S. Reed, assisted by J. J. Skinner, Bull.
+No. <b>47</b>, Bureau of Soils, U. S. Dept. Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_106_106" href="#FNanchor_106_106" class="label">[106]</a>
+Organic nitrogen in Hawaiian soils, by E. C. Shorey, report of Hawaii
+Experiment Station, 1906, 37-59.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_107_107" href="#FNanchor_107_107" class="label">[107]</a>
+Chemical Nature of Soil Organic Matter, by Oswald Schreiner and Edmund
+C. Shorey, Bull. 74, Bureau of Soils, U. S. Department of Agriculture, 1910.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_108_108" href="#FNanchor_108_108" class="label">[108]</a>
+See in this connection, Further studies on the properties of
+unproductive soils, by B. E. Livingston, Bull. No. <b>36</b>, Bureau of
+soils, Dept. of Agric., 1907, p. 7-9.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_109_109" href="#FNanchor_109_109" class="label">[109]</a>
+Mr. J. G. Smith has made a comparison between the potash and phosphoric
+acid content of the wheat and following crop of ragweed grown on a farm
+in Fairfax Co., Va. His unpublished results, with some others found in
+the literature, are given in the following table:</p>
+
+<table class="spb1">
+ <thead><tr class="bt2 bb">
+ <th class="tdc">Material</th>
+ <th class="tdc bl">&nbsp;Potash&nbsp;<br>K₂O<br>%</th>
+ <th class="tdc bl">&nbsp;Phosphoric&nbsp;<br>acid, P₂O₅<br>%</th>
+ <th class="tdl_ws1 bl">Analyst</th>
+ </tr></thead>
+ <tbody><tr>
+ <td class="tdl">Wheat</td>
+ <td class="tdl_wsp bl">0.76</td>
+ <td class="tdc bl">0.52</td>
+ <td class="tdl_wsp bl">Smith</td>
+ </tr><tr>
+ <td class="tdl">Young ragweed</td>
+ <td class="tdl_wsp bl">1.78</td>
+ <td class="tdc bl">0.73</td>
+ <td class="tdl_wsp bl">Smith</td>
+ </tr><tr>
+ <td class="tdl">Ragweed in seed</td>
+ <td class="tdl_wsp bl">1.28</td>
+ <td class="tdc bl">0.35</td>
+ <td class="tdl_wsp bl">Smith</td>
+ </tr><tr>
+ <td class="tdl">Ragweed in seed and</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdc bl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ </tr><tr>
+ <td class="tdl_ws1">accompanying plants &nbsp;</td>
+ <td class="tdl_wsp bl">1.18</td>
+ <td class="tdc bl">0.39</td>
+ <td class="tdl_wsp bl">Smith</td>
+ </tr><tr>
+ <td class="tdl">Winter wheat in flower</td>
+ <td class="tdl_wsp bl">1.796</td>
+ <td class="tdc bl">0.51</td>
+ <td class="tdl_wsp bl">Wolff’s tables in Johnson’s</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdc bl">&nbsp;</td>
+ <td class="tdl_ws1 bl">“How Crops Grow,” p. 376.</td>
+ </tr><tr>
+ <td class="tdl">Ragweed</td>
+ <td class="tdl_wsp bl">1.79</td>
+ <td class="tdc bl">0.41</td>
+ <td class="tdl_wsp bl">DeRoode,in Bull. 19, W. Va.</td>
+ </tr><tr>
+ <td class="tdl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdc bl">&nbsp;</td>
+ <td class="tdl_ws1 bl">Agr. Exp. Sta., 1891</td>
+ </tr><tr>
+ <td class="tdl">Ragweed</td>
+ <td class="tdl_wsp bl">1.809</td>
+ <td class="tdc bl">0.54</td>
+ <td class="tdl_wsp bl">Burney, 2d. Ann. rept.</td>
+ </tr><tr class="bb">
+ <td class="tdl">&nbsp;</td>
+ <td class="tdl_wsp bl">&nbsp;</td>
+ <td class="tdc bl">&nbsp;</td>
+ <td class="tdl_ws1 bl">S. C. Stat., 1889, p. 146</td>
+ </tr>
+ </tbody>
+</table>
+
+<p>On the whole, ragweed seems to require and take from the soil about
+as much mineral matter as does wheat. It is stated by some of the
+dairy farmers near Washington, who cut the mixture of ragweed, other
+weeds and grass following wheat, for a hay crop, that the weight of
+the ragweed crop is generally heavier than that of the wheat crop.
+Therefore the ragweed actually removes more mineral matter from the
+field than does the wheat. These facts lend no support to the popular
+notion that wheat “exhausts” the soil of its “available” mineral plant
+nutrients. For analyses of a number of common American weeds, see
+Analyses of the ashes of certain weeds, by Francis P. Dunnington: Am.
+Chem. Jour., <b>2</b>, 24-27, (1880).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_110_110" href="#FNanchor_110_110" class="label">[110]</a>
+Note on the occurrence of “fairy rings,” by J. H. Gilbert:
+Jour. Linn. Soc, <b>15</b>, 17-24, (1875).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_111_111" href="#FNanchor_111_111" class="label">[111]</a>
+Second, third and fifth reports of the Woburn Experimental
+Fruit Farm, <b>1900</b>, <b>1903</b>, <b>1905</b>.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_112_112" href="#FNanchor_112_112" class="label">[112]</a>
+It may not be amiss to point out here that this general
+law holds for all dynamic phenomena. In chemistry, for instance, the
+general law is well recognized that the rate of reaction diminishes
+with increase in the active mass of the reaction products. It can
+be shown that the principle applies to plant growth. Young plants
+will withdraw potassium more rapidly than chlorine from solutions
+of potassium chloride; that is, the solution soon contains free
+hydrochloric acid. Conversely the plants cause a solution of sodium
+nitrate to become alkaline. Therefore, if the above principle holds,
+then the initial addition of small amounts of hydrochloric acid to
+a solution of potassium chloride should slow up the absorption of
+potassium by seedling wheat plants, or the addition of sodium hydroxide
+the absorption of nitrogen from a solution of sodium nitrate. Mr. J.
+J. Skinner has tested this idea with the following results, growing
+carefully selected wheat seedlings, for 3 days in solutions of pure
+potassium chloride, solutions of potassium chloride containing
+initially enough excess of hydrochloric acid to be of an N/₅,₀₀₀
+concentration with respect to the acid, solutions of sodium nitrate,
+and solutions of sodium nitrate containing initially an excess of
+sodium hydroxide.</p>
+
+<ul class="index">
+<li class="isub1">Solutions of KCl containing 80 p.p.m. K₂O.</li>
+<li class="isub3">1 K₂O absorbed 40.0 p.p.m.</li>
+<li class="isub3">2 K₂O absorbed 40.0 p.p.m.</li>
+<li class="isub3">3 K₂O absorbed 36.3 p.p.m.</li>
+<li class="isub1">Solutions of KCl (80 p.p.m. K₂O) and HCl (<sup>N</sup>/₅,₀₀₀).</li>
+<li class="isub3">4 K₂O absorbed 26.7 p.p.m.</li>
+<li class="isub3">5 K₂O absorbed 29.5 p.p.m.</li>
+<li class="isub3">6 K₂O absorbed 26.7 p.p.m.</li>
+<li class="isub1">Solutions of NaNO₃ containing 80 p.p.m. NH₃.</li>
+<li class="isub3">7 NH₃ absorbed 30.2 p.p.m.</li>
+<li class="isub3">S NH₃ absorbed 30.2 p.p.m.</li>
+<li class="isub3">9 NH₃ absorbed 32.5 p.p.m.</li>
+<li class="isub1">Solutions of NaNO₃ (80 p.p.m. NH₃) and NaOH (<sup>N</sup>/₅,₀₀₀).</li>
+<li class="isub3">10 NH₃ absorbed 27.8 p.p.m.</li>
+<li class="isub3">11 NH₃ absorbed 34.3 p.p.m.</li>
+<li class="isub3">12 NH₃ absorbed 27.8 p.p.m.</li>
+</ul>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_113_113" href="#FNanchor_113_113" class="label">[113]</a>
+Some factors in soil fertility, by Oswald Schreiner and Howard S.
+Reed, Bull. No. <b>40</b>, Bureau of Soils, U. S. Dept. Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_114_114" href="#FNanchor_114_114" class="label">[114]</a>
+Soil fatigue caused by organic compounds, by Oswald Schreiner and M. X.
+Sullivan: Jour. Biol. Chem., <b>6</b>, 39-50, (1909).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_115_115" href="#FNanchor_115_115" class="label">[115]</a>
+Über Wurzelausscheidungen und deren Einwirkung auf organische
+Substanzen, von Hans Molisch. Sitzungsber. Akad. Wiss. Wien, Math. nat.
+K1., <b>96</b>, 84-109 (1888).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_116_116" href="#FNanchor_116_116" class="label">[116]</a>
+The rôle of oxidation in soil fertility, by Oswald Schreiner and Howard
+S. Reed: Bull. No. <b>56</b>, Bureau of Soils, U. S. Dept. Agriculture, 1909.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_117_117" href="#FNanchor_117_117" class="label">[117]</a>
+From considerations as yet highly speculative, a different type of
+oxidation by roots might be anticipated. It is recognized that in the
+absorption of mineral nutrients by plants a certain amount of selection
+enters. For example, a plant with its roots in a solution of potassium
+chloride, absorbs more potassium than chlorine, relatively, and free
+hydrochloric acid is left in the solution. Obviously in the absorption,
+work is done, and a possible explanation is that water is decomposed
+at the absorbing surface of the root, with the liberation of oxygen.
+Theoretically, it ought not to be difficult to investigate this by a
+study of the energy changes during absorption, but growing plants do
+not lend themselves readily to such experimentation.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_118_118" href="#FNanchor_118_118" class="label">[118]</a>
+Action of fertilizing salts on plant enzymes, by M. X. Sullivan, Jour.
+biol. chem., <b>6</b>, (1909), proceed. XLIV.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_119_119" href="#FNanchor_119_119" class="label">[119]</a>
+Private communication by Dr. Oswald Schreiner and Mr. J. J. Skinner.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_120_120" href="#FNanchor_120_120" class="label">[120]</a>
+Oxidation in soils, and its connection with fertility, by Edward J.
+Russell: Jour. Agric. Sci., <span class="allsmcap">I</span>, 261-279,
+(1905); Pt. II. The influence of partial sterilization, by Francis V.
+Darbishire and Edward J. Russell, <b>2</b>, 305-326, (1907).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_121_121" href="#FNanchor_121_121" class="label">[121]</a>
+The fixation of atmospheric nitrogen by bacteria, by J. G. Lipman,
+Bull. <b>81</b>, Bureau of Chemistry, U. S. Dept. of Agriculture, 1904,
+p. 146-160; A review of investigations in soil bacteriology, by Edward
+B. Voorhees and Jacob G. Lipman, Bull, <b>194</b>, Office of Experiment
+Stations, U. S. Dept. of Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_122_122" href="#FNanchor_122_122" class="label">[122]</a>
+See, for instance, Barium in soils, by G. H. Failyer, Bull. No.
+<b>71</b>, Bureau of Soils, U. S. Dept. of Agriculture, 1910.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_123_123" href="#FNanchor_123_123" class="label">[123]</a>
+In this connection it may be of interest to call attention to the
+fact that the Twelfth Census shows less than a fifth of the sodium
+nitrate brought into the United States goes into the fertilizer trade.
+Moreover, the production of ammonium salts by the extensive coke and
+gas plants of the country has been practically <i>nil</i> not because
+of any inherent difficulties in making them or because the cost of
+production has been high, but because the market demands in this
+country have been too small.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_124_124" href="#FNanchor_124_124" class="label">[124]</a>
+Occasional occurrence of alkali in humid regions, by Frank K. Cameron,
+Bull. No. <b>17</b>, Bureau of Soils, U. S. Dept. Agriculture, 1901,
+p. 36-38. This phenomenon should not be confused with the surface
+deposition of various kinds of saline material from springs, which is
+fairly common in both humid and arid regions, the world over.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_125_125" href="#FNanchor_125_125" class="label">[125]</a>
+Alkali soils of the United States, by Clarence W. Dorsey, Bull. No.
+<b>35</b>, Bureau of Soils, U. S. Dept. Agriculture, 1906.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_126_126" href="#FNanchor_126_126" class="label">[126]</a>
+Black alkali is so called because the caustic solution containing
+sodium carbonate, in rising to the surface of the soil, dissolves
+and carries with it organic matter which is subsequently left on
+the surface in more or less blackish deposits, often ring-like in
+appearance. It is by no means uncommon, however, to find deposits of
+“black alkali” which are not black at all, and it is quite common to
+find “white alkali” so dark in color as to suggest the presence of
+sodium carbonate, although the latter be absent.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_127_127" href="#FNanchor_127_127" class="label">[127]</a>
+An interesting case is the Billings Area, Montana, where
+the alkali seems to be derived from the oxidation, solution and
+subsequent hydrolysis of the pyrites and marcasite of the neighboring
+Pierre shales. The sulphuric acid thus formed, leaching through shales
+and sandstones, takes up various bases and the predominating salts in
+the alkali of this area are the sulphates of sodium and magnesium.</p></div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_128_128" href="#FNanchor_128_128" class="label">[128]</a>
+Zur Bildung der ozeanischen Salzablagerungen, von J. H.
+van’t Hoff, Braunschweig, 1905-09. For a detailed discussion of these
+results with reference to alkali deposits see: Calcium sulphate in
+aqueous solutions, by Frank K. Cameron and James M. Bell, Bull. No.
+<b>33</b>, Bureau of Soils, U. S. Dept. Agriculture, 1906.</p></div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_129_129" href="#FNanchor_129_129" class="label">[129]</a>
+It will be interesting to compare with the above the following brief
+description of the Stassfurt salt deposits, taken from Ries’s Economic
+Geology of the United States, (1905), p. 127. “At the bottom is the
+main bed of rock salt which is broken up into layers 2-5 inches thick
+by layers of anhydrite. Above this come 200 feet of rock salt, with
+which are mixed layers of magnesium chloride and polyhalite.... Resting
+on this is 180 feet of rock salt, with alternating layers of sulphates
+chiefly kieserite, the sulphate of magnesia. These layers are about
+1 foot thick. Lastly, and uppermost, is a 135-foot bed consisting of
+a series of reddish layers of rock salts of magnesia and potassium,
+kainite ... kieserite ... carnallite ... tachhydrite ... as well as
+masses of snow-white boracite.”</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_130_130" href="#FNanchor_130_130" class="label">[130]</a>
+As examples, some of the gypsum deposits of Kansas may be cited,
+according to Haworth, Mineral resources of Kansas, 1897, p. 61, and the
+classical case at Bex, Switzerland, described by J. G. F. Charpentier,
+Uber die Salz-Lagerstätte von Bex: Ann. Phys. Chim., <b>3</b>,
+75-80, (1825), and by G. Bischof, Elements of chemical and physical
+geology, London, 1854-58, Vol. <span class="allsmcap">I</span>, p. 350-1.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_131_131" href="#FNanchor_131_131" class="label">[131]</a>
+The action of water and aqueous solutions upon soil carbonates, by
+Frank K. Cameron and James M. Bell, Bull. No. <b>49</b>, Bureau of
+Soils, U. S. Dept. Agriculture, 1907.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_132_132" href="#FNanchor_132_132" class="label">[132]</a>
+Application of the theory of solutions to study of soils, by F. K. Cameron,
+Report No. <b>64</b>, Field Operations of the Bureau of Soils, 1899, p. 149.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_133_133" href="#FNanchor_133_133" class="label">[133]</a>
+Alkali lakes and deposits, by W. C. Knight and E. E. Slosson, Bull. No.
+<b>49</b>, Wyoming Agr. Expt. Station, 1901, p. 108.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_134_134" href="#FNanchor_134_134" class="label">[134]</a>
+The solubility of certain salts present in alkali soils, by Frank K.
+Cameron, J. M. Bell and W. O. Robinson, Jour. Phys. Chem., <b>11</b>, 396-420, (1907).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_135_135" href="#FNanchor_135_135" class="label">[135]</a>
+It has been suggested that the fact that shales or similar geological
+deposits are frequently to be found near alkali areas, indicates that
+the shales are the principal sources of the alkali. It is supposed that
+the constituents of the alkali salts were formed by the action of water
+on the shale minerals at or about the time the shales were deposited,
+and carried down with the latter. Subsequently the alkali has been
+leached out to appear at the surface of soils, generally at a lower
+level than are the shales.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_136_136" href="#FNanchor_136_136" class="label">[136]</a>
+The water of Utah Lake, by F. K. Cameron: Jour. Am. Chem. Soc.,
+<b>27</b>, 113-116, (1905).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_137_137" href="#FNanchor_137_137" class="label">[137]</a>
+Sample collected May 18. Lake unusually high.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_138_138" href="#FNanchor_138_138" class="label">[138]</a>
+Sample collected Aug. 31. Lake still high for that season of the year.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_139_139" href="#FNanchor_139_139" class="label">[139]</a>
+For a recent interesting and valuable discussion of this subject with
+reference to a particular area, see: The origin of the salt deposits of
+Rajputana, by Sir Thomas H. Holland and W. A. K. Christie, Records of
+the Geological Survey of India, <b>38</b>, 154-186, (1909).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_140_140" href="#FNanchor_140_140" class="label">[140]</a>
+Some mutual relations between alkali soils and vegetation, by
+Thomas H. Kearney and Frank K. Cameron, Report No. <b>71</b>, U. S.
+Dept. Agriculture, 1902; The date-palm and its utilization in the
+Southwestern states, by Walter T. Swingle, Bull. <b>53</b>, Bureau
+of Plant Industry, U. S. Dept. Agriculture, 1904; The comparative
+tolerance of various plants for the salts common in alkali soils, by
+T. H. Kearney and L. L. Harter, Bull. <b>113</b>, Bureau of Plant
+Industry, U. S. Dept. Agriculture, 1907; Tolerance of alkali by various
+cultures, by R. H. Loughridge, Bull. <b>133</b>, California Agr. Expt.
+Sta., 1901.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_141_141" href="#FNanchor_141_141" class="label">[141]</a>
+Soils, by E. W. Hilgard. 1906, p. 457-458.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_142_142" href="#FNanchor_142_142" class="label">[142]</a>
+With the salts occurring in alkali, it is a generality that the effects
+produced on higher green plants are relatively less with mixtures than
+with an equivalent amount of a single salt. It has recently been shown,
+however, that the contrary is true for at least some kinds of bacterial
+flora. See, On the lack of antagonism between certain salts,
+by C. B. Lipman, Bot. Gaz., <b>49</b>, 41-50, (1910).</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_143_143" href="#FNanchor_143_143" class="label">[143]</a>
+See, Calcium sulphate in aqueous solution, by Frank K. Cameron and
+James M. Bell, Bull. No. <b>33</b>, 1906, p. 10 and 70, and Reclamation
+of alkali land in Salt Lake Valley, Utah, by Clarence W. Dorsey,
+Bull. No. <b>43</b>, 1907, p. 13, Bureau of Soils, U. S. Dept.
+Agriculture.</p>
+</div>
+
+<div class="footnote"><p class="no-indent">
+<a id="Footnote_144_144" href="#FNanchor_144_144" class="label">[144]</a>
+The removal of “black alkali” by leaching, by F. K. Cameron and H. E.
+Patten, Jour. Am. Chem. Soc., <b>28</b>, 1639, (1906).</p>
+</div></div>
+
+<div class="chapter">
+<div class="transnote bbox spa2">
+<p class="f120 spa1">Transcriber’s Notes:</p>
+<hr class="r10">
+<p>The cover image was created by the transcriber, and is in the public domain.</p>
+<p>Deprecated spellings or ancient words were not corrected.</p>
+<p>The illustrations and footnotes have been moved so that they do not break up
+ paragraphs and so that they are next to the text they illustrate.</p>
+<p>Typographical and punctuation errors have been silently corrected.</p>
+</div></div>
+
+
+<div style='text-align:center'>*** END OF THE PROJECT GUTENBERG EBOOK 78317 ***</div>
+</body>
+</html>
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