CHAPTER V
DRY-FARM SOILS
IMPORTANT as is the rainfall in making dry-farming
successful, it is not more so than the soils of the dry-farms. On a shallow soil,
or on one penetrated with gravel streaks, crop failures are probable even under a
large rainfall; but a deep soil of uniform texture, unbroken by gravel or hardpan,
in which much water may be stored, and which furnishes also an abundance of feeding
space for the roots, will yield large crops even under a very small rainfall. Likewise,
an infertile soil, though it be deep, and under a large precipitation, cannot be
depended on for good crops; but a fertile soil, though not quite so deep, nor under
so large a rainfall, will almost invariably bring large crops to maturity.
A correct understanding of the soil, from the
surface to a depth of ten feet, is almost indispensable before a safe Judgment can
be pronounced upon the full dry-farm possibilities of a district. Especially is it
necessary to know (a) the depth, (b) the uniformity of structure, and (c) the relative
fertility of the soil, in order to plan an intelligent system of farming that will
be rationally adapted to the rainfall and other climatic factors.
It is a matter of regret that so much of our
information concerning the soils of the dry-farm territory of the United States and
other countries has been obtained according to the methods and for the needs of humid
countries, and that, therefore, the special knowledge of our arid and semiarid soils
needed for the development of dry-farming is small and fragmentary. What is known
to-day concerning the nature of arid soils and their relation to cultural processes
under a scanty rainfall is due very largely to the extensive researches and voluminous
writings of Dr. E. W. Hilgard, who for a generation was in charge of the agricultural
work of the state of California. Future students of arid soils must of necessity
rest their investigations upon the pioneer work done by Dr. Hilgard. The contents
of this chapter are in a large part gathered from Hilgard's writings.
The formation of soils
"Soil is the more or less loose and friable
material in which, by means of their roots, plants may or do find a foothold and
nourishment, as well as other conditions of growth." Soil is formed by a complex
process, broadly known as weathering, from the rocks which constitute the
earth's crust. Soil is in fact only pulverized and altered rock. The forces that
produce soil from rocks are of two distinct classes, physical and chemical. The
physical agencies of soil production merely cause a pulverization of the rock; the
chemical agencies, on the other hand, so thoroughly change the essential nature of
the soil particles that they are no longer like the rock from which they were formed.
Of the physical agencies, temperature changes
are first in order of time, and perhaps of first importance. As the heat of the
day increases, the rock expands, and as the cold night approaches, contracts. This
alternate expansion and contraction, in time, cracks the surfaces of the rocks. Into
the tiny crevices thus formed water enters from the falling snow or rain. When winter
comes, the water in these cracks freezes to ice, and in so doing expands and widens
each of the cracks. As these processes are repeated from day to day, from year to
year, and from generation to generation, the surfaces of the rocks crumble. The smaller
rocks so formed are acted upon by the same agencies, in the same manner, and thus
the process of pulverization goes on.
It is clear, then, that the second great agency
of soil formation, which always acts in conjunction with temperature changes, is
freezing water. The rock particles formed in this manner are often washed
down into the mountain valleys, there caught by great rivers, ground into finer dust,
and at length deposited in the lower valleys. Moving water thus becomes another
physical agency of soil production. Most of the soils covering the great dry-farm
territory of the United States and other countries have been formed in this way.
In places, glaciers moving slowly down the canons
crush and grind into powder the rock over which they pass and deposit it lower down
as soils. In other places, where strong winds blow with frequent regularity, sharp
soil grains are picked up by the air and hurled against the rocks, which, under this
action, are carved into fantastic forms. In still other places, the strong winds
carry soil over long distances to be mixed with other soils. Finally, on the seashore
the great waves dashing against the rocks of the coast line, and rolling the mass
of pebbles back and forth, break and pulverize the rock until soil is formed.
Glaciers, winds, and waves are also, therefore, physical agencies of soil
formation.
It may be noted that the result of the action
of all these agencies is to form a rock powder, each particle of which preserves
the composition that it had while it was a constituent part of the rock. It may further
be noted that the chief of these soil-forming agencies act more vigorously in arid
than in humid sections. Under the cloudless sky and dry atmosphere of regions of
limited rainfall, the daily and seasonal temperature changes are much greater than
in sections of greater rainfall. Consequently the pulverization of rocks goes on
most rapidly in dry-farm districts. Constant heavy winds, which as soil formers are
second only to temperature changes and freezing water, are also usually more common
in arid than in humid countries. This is strikingly shown, for instance, on the Colorado
desert and the Great Plains.
The rock powder formed by the processes above
described is continually being acted upon by agencies, the effect of which is to
change its chemical composition. Chief of these agencies is water, which exerts
a solvent action on all known substances. Pure water exerts a strong solvent action,
but when it has been rendered impure by a variety of substances, naturally occurring,
its solvent action is greatly increased.
The most effective water impurity, considering
soil formation, is the gas, carbon dioxid. This gas is formed whenever plant
or animal substances decay, and is therefore found, normally, in the atmosphere and
in soils. Rains or flowing water gather the carbon dioxid from the atmosphere and
the soil; few natural waters are free from it. The hardest rock particles are disintegrated
by carbonated water, while limestones, or rocks containing lime, are readily dissolved.
The result of the action of carbonated water
upon soil particles is to render soluble, and therefore more available to plants,
many of the important plant-foods. In this way the action of water, holding in solution
carbon dioxid and other substances, tends to make the soil more fertile.
The second great chemical agency of soil formation
is the oxygen of the air. Oxidation is a process of more or less rapid burning, which
tends to accelerate the disintegration of rocks.
Finally, the plants growing in soils are
powerful agents of soil formation. First, the roots forcing their way into the soil
exert a strong pressure which helps to pulverize the soil grains; secondly, the acids
of the plant roots actually dissolve the soil, and third, in the mass of decaying
plants, substances are formed, among them carbon dioxid, that have the power of making
soils more soluble.
It may be noted that moisture, carbon dioxid,
and vegetation, the three chief agents inducing chemical changes in soils, are most
active in humid districts. While, therefore, the physical agencies of soil formation
are most active in arid climates, the same cannot be said of the chemical agencies.
However, whether in arid or humid climates, the processes of soil formation, above
outlined, are essentially those of the "fallow" or resting-period given
to dry-farm lands. The fallow lasts for a few months or a year, while the process
of soil formation is always going on and has gone on for ages; the result, in quality
though not in quantity, is the same--the rock particles are pulverized and the plant-foods
are liberated. It must be remembered in this connection that climatic differences
may and usually do influence materially the character of soils formed from one and
the same kind of rock.
Characteristics of arid soils
The net result of the processes above described
Is a rock powder containing a great variety of sizes of soil grains intermingled
with clay. The larger soil grains are called sand; the smaller, silt, and those that
are so small that they do not settle from quiet water after 24 hours are known as
clay.
Clay differs materially from sand and silt, not
only in size of particles, but also in properties and formation. It is said that
clay particles reach a degree of fineness equal to 1/2500 of an inch. Clay itself,
when wet and kneaded, becomes plastic and adhesive and is thus easily distinguished
from sand. Because of these properties, clay is of great value in holding together
the larger soil grains in relatively large aggregates which give soils the desired
degree of filth. Moreover, clay is very retentive of water, gases, and soluble plant-foods,
which are important factors in successful agriculture. Soils, in fact, are classified
according to the amount of clay that they contain. Hilgard suggests the following
classification:--
Very sandy soils0.5 to 3 per cent clay
Ordinary sandy soils3.0 to 10 per cent clay
Sandy loams10.0 to 15 per cent clay
Clay loams15.0 to 25 per cent clay
Clay soils25.0 to 35 per cent clay
Heavy clay soils35.0 per cent and over
Clay may be formed from any rock containing some
form of combined silica (quartz). Thus, granites and crystalline rocks generally,
volcanic rocks, and shales will produce clay if subjected to the proper climatic
conditions. In the formation of clay, the extremely fine soil particles are attacked
by the soil water and subjected to deep-going chemical changes. In fact, clay represents
the most finely pulverized and most highly decomposed and hence in a measure the
most valuable portion of the soil. In the formation of clay, water is the most active
agent, and under humid conditions its formation is most rapid.
It follows that dry-farm soils formed under a
more or less rainless climate contain less clay than do humid soils. This difference
is characteristic, and accounts for the statement frequently made that heavy clay
soils are not the best for dry-farm purposes. The fact is, that heavy clay soils
are very rare in arid regions; if found at all, they have probably been formed under
abnormal conditions, as in high mountain valleys, or under prehistoric humid climates.
Sand.--The sand-forming rocks that are
not capable of clay production usually consist of uncombined silica or quartz,
which when pulverized by the soil-forming agencies give a comparatively barren soil.
Thus it has come about that ordinarily a clayey soil is considered "strong"
and a sandy soil "weak." Though this distinction is true in humid climates
where clay formation is rapid, it is not true in arid climates, where true clay is
formed very slowly. Under conditions of deficient rainfall, soils are naturally less
clayey, but as the sand and silt particles are produced from rocks which under humid
conditions would yield clay, arid soils are not necessarily less fertile.
Experiment has shown that the fertility in the
sandy soils of arid sections is as large and as available to plants as in the clayey
soils of humid regions. Experience in the arid section of America, in Egypt, India,
and other desert-like regions has further proved that the sands of the deserts produce
excellent crops whenever water is applied to them. The prospective dry-farmer, therefore,
need not be afraid of a somewhat sandy soil, provided it has been formed under arid
conditions. In truth, a degree of sandiness is characteristic of dry-farm soils.
The humus content forms another characteristic
difference between arid and humid soils. In humid regions plants cover the soil thickly;
in arid regions they are bunched scantily over the surface; in the former case the
decayed remnants of generations of plants form a large percentage of humus in the
upper soil; in the latter, the scarcity of plant life makes the humus content low.
Further, under an abundant rainfall the organic matter in the soil rots slowly; whereas
in dry warm climates the decay is very complete. The prevailing forces in all countries
of deficient rainfall therefore tend to yield soils low in humus.
While the total amount of humus in arid soils
is very much lower than in humid soils, repeated investigation has shown that it
contains about 3-1/2 times more nitrogen than is found in humus formed under an abundant
rainfall. Owing to the prevailing sandiness of dry-farm soils, humus is not needed
so much to give the proper filth to the soil as in the humid countries where the
content of clay is so much higher. Since, for dry-farm purposes, the nitrogen content
is the most important quality of the humus, the difference between arid and humid
soils, based upon the humus content, is not so great as would appear at first sight.
Soil and subsoil.--In countries of abundant
rainfall, a great distinction exists between the soil and the subsoil. The soil is
represented by the upper few inches which are filled with the remnants of decayed
vegetable matter and modified by plowing, harrowing, and other cultural operations.
The subsoil has been profoundly modified by the action of the heavy rainfall, which,
in soaking through the soil, has carried with it the finest soil grains, especially
the clay, into the lower soil layers.
In time, the subsoil has become more distinctly
clayey than the topsoil. Lime and other soil ingredients have likewise been carried
down by the rains and deposited at different depths in the soil or wholly washed
away. Ultimately, this results in the removal from the topsoil of the necessary plant-foods
and the accumulation in the subsoil of the fine clay particles which so compact the
subsoil as to make it difficult for roots and even air to penetrate it. The normal
process of weathering or soil disintegration will then go on most actively in the
topsoil and the subsoil will remain unweathered and raw. This accounts for the well-known
fact that in humid countries any subsoil that may have been plowed up is reduced
to a normal state of fertility and crop production only after several years of exposure
to the elements. The humid farmer, knowing this, is usually very careful not to let
his plow enter the subsoil to any great depth.
In the arid regions or wherever a deficient rainfall
prevails, these conditions are entirely reversed. The light rainfall seldom completely
fills the soil pores to any considerable depth, but it rather moves down slowly as
a him, enveloping the soil grains. The soluble materials of the soil are, in part
at least, dissolved and carried down to the lower limit of the rain penetration,
but the clay and other fine soil particles are not moved downward to any great extent.
These conditions leave the soil and subsoil of approximately equal porosity. Plant
roots can then penetrate the soil deeply, and the air can move up and down through
the soil mass freely and to considerable depths. As a result, arid soils are weathered
and made suitable for plant nutrition to very great depths. In fact, in dry-farm
regions there need be little talk about soil and subsoil, since the soil is uniform
in texture and usually nearly so in composition, from the top down to a distance
of many feet.
Many soil sections 50 or more feet in depth are
exposed in the dry-farming territory of the United States, and it has often been
demonstrated that the subsoil to any depth is capable of producing, without further
weathering, excellent yields of crops. This granular, permeable structure, characteristic
of arid soils, is perhaps the most important single quality resulting from rock disintegration
under arid conditions. As Hilgard remarks, it would seem that the farmer in the arid
region owns from three to four farms, one above the other, as compared with the same
acreage in the eastern states.
This condition is of the greatest importance
in developing the principles upon which successful dry-farming rests. Further, it
may be said that while in the humid East the farmer must be extremely careful not
to turn up with his plow too much of the inert subsoil, no such fear need possess
the western farmer. On the contrary, he should use his utmost endeavor to plow as
deeply as possible in order to prepare the very best reservoir for the falling waters
and a place for the development of plant roots.
Gravel seams.--It need be said, however,
that in a number of localities in the dry-farm territory the soils have been deposited
by the action of running water in such a way that the otherwise uniform structure
of the soil is broken by occasional layers of loose gravel. While this is not a very
serious obstacle to the downward penetration of roots, it is very serious in dry-farming,
since any break in the continuity of the soil mass prevents the upward movement of
water stored in the lower soil depths. The dry-farmer should investigate the soil
which he intends to use to a depth of at least 8 to 10 feet to make sure, first of
all, that he has a continuous soil mass, not too clayey in the lower depths, nor
broken by deposits of gravel.
Hardpan.--Instead of the heavy clay subsoil
of humid regions, the so-called hardpan occurs in regions of limited rainfall. The
annual rainfall, which is approximately constant, penetrates from year to year very
nearly to the same depth. Some of the lime found so abundantly in arid soils is dissolved
and worked down yearly to the lower limit of the rainfall and left there to enter
into combination with other soil ingredients. Continued through long periods of time
this results in the formation of a layer of calcareous material at the average depth
to which the rainfall has penetrated the soil. Not only is the lime thus carried
down, but the finer particles are carried down in like manner. Especially where the
soil is poor in lime is the clay worked down to form a somewhat clayey hardpan. A
hardpan formed in such a manner is frequently a serious obstacle to the downward
movement of the roots, and also prevents the annual precipitation from moving down
far enough to be beyond the influence of the sunshine and winds. It is fortunate,
however, that in the great majority of instances this hardpan gradually disappears
under the influence of proper methods of dry-farm tillage. Deep plowing and proper
tillage, which allow the rain waters to penetrate the soil, gradually break up and
destroy the hardpan, even when it is 10 feet below the surface. Nevertheless, the
farmer should make sure whether or not the hardpan does exist in the soil and plan
his methods accordingly. If a hardpan is present, the land must be fallowed more
carefully every other year, so that a large quantity of water may be stored in the
soil to open and destroy the hardpan.
Of course, in arid as in humid countries, it
often happens that a soil is underlaid, more or less near the surface, by layers
of rock, marl deposits, and similar impervious or hurtful substances. Such deposits
are not to be classed with the hardpans that occur normally wherever the rainfall
is small.
Leaching.--Fully as important as any of
the differences above outlined are those which depend definitely upon the leaching
power of a heavy rainfall. In countries where the rainfall is 30 inches or over,
and in many places where the rainfall is considerably less, the water drains through
the soil into the standing ground water. There is, therefore, in humid countries,
a continuous drainage through the soil after every rain, and in general there is
a steady downward movement of soil-water throughout the year. As is clearly shown
by the appearance, taste, and chemical composition of drainage waters, this process
leaches out considerable quantities of the soluble constituents of the soil.
When the soil contains decomposing organic matter,
such as roots, leaves, stalks, the gas carbon dioxid is formed, which, when dissolved
in water, forms a solution of great solvent power. Water passing through well-cultivated
soils containing much humus leaches out very much more material than pure water could
do. A study of the composition of the drainage waters from soils and the waters of
the great rivers shows that immense quantities of soluble soil constituents are taken
out of the soil in countries of abundant rainfall. These materials ultimately reach
the ocean, where they are and have been concentrated throughout the ages. In short,
the saltiness of the ocean is due to the substances that have been washed from the
soils in countries of abundant rainfall.
In arid regions, on the other hand, the rainfall
penetrates the soil only a few feet. In time, it is returned to the surface by the
action of plants or sunshine and evaporated into the air. It is true that under proper
methods of tillage even the light rainfall of arid and semiarid regions may he made
to pass to considerable soil depths, yet there is little if any drainage of water
through the soil into the standing ground water. The arid regions of the world, therefore,
contribute proportionately a small amount of the substances which make up the salt
of the sea.
Alkali soils.--Under favorable conditions
it sometimes happens that the soluble materials, which would normally be washed out
of humid soils, accumulate to so large a degree in arid soils as to make the lands
unfitted for agricultural purposes. Such lands are called alkali lands. Unwise irrigation
in arid climates frequently produces alkali spots, but many occur naturally. Such
soils should not be chosen for dry-farm purposes, for they are likely to give trouble.
Plant-food content.--This condition necessarily
leads at once to the suggestion that the soils from the two regions must differ greatly
in their fertility or power to produce and sustain plant life. It cannot be believed
that the water-washed soils of the East retain as much fertility as the dry soils
of the West. Hilgard has made a long and elaborate study of this somewhat difficult
question and has constructed a table showing the composition of typical soils of
representative states in the arid and humid regions. The following table shows a
few of the average results obtained by him:--
Partial Percentage Composition
| Source of soil |
Number of samples analyzed |
Insoluble residue |
Soluble silica |
Alumina |
Lime |
Potash |
Phos.
Acid |
Humus |
| Humid |
696 |
84.17 |
4.04 |
3.66 |
0.13 |
0.21 |
0.12 |
1.22 |
| Arid |
573 |
69.16 |
6.71 |
7.61 |
1.43 |
0.67 |
0.16 |
1.13 |
Soil chemists have generally attempted to arrive
at a determination of the fertility of soil by treating a carefully selected and
prepared sample with a certain amount of acid of definite strength. The portion which
dissolves under the influence of acids has been looked upon as a rough measure of
the possible fertility of the soil.
The column headed "Insoluble Residue"
shows the average proportions of arid and humid soils which remain undissolved by
acids. It is evident at once that the humid soils are much less soluble in acids
than arid soils, the difference being 84 to 69. Since the only plant-food in soils
that may be used for plant production is that which is soluble, it follows that it
is safe to assume that arid soils are generally more fertile than humid soils. This
is borne out by a study of the constituents of the soil. For instance, potash, one
of the essential plant foods ordinarily present in sufficient amount, is found in
humid soils to the extent of 0.21 per cent, while in arid soils the quantity present
is 0.67 per cent, or over three times as much. Phosphoric acid, another of the very
important plant-foods, is present in arid soils in only slightly higher quantities
than in humid soils. This explains the somewhat well-known fact that the first fertilizer
ordinarily required by arid soils is some form of phosphorus:
The difference in the chemical composition of
arid and humid soils is perhaps shown nowhere better than in the lime content. There
is nearly eleven times more lime in arid than in humid soils. Conditions of aridity
favor strongly the formation of lime, and since there is very little leaching of
the soil by rainfall, the lime accumulates in the soil.
The presence of large quantities of lime in arid
soils has a number of distinct advantages, among which the following are most important:
(1) It prevents the sour condition frequently present in humid climates, where much
organic material is incorporated with the soil. (2) When other conditions are favorable,
it encourages bacterial life which, as is now a well-known fact, is an important
factor in developing and maintaining soil fertility. (3) By somewhat subtle chemical
changes it makes the relatively small percentages of other plant-foods notably phosphoric
acid and potash, more available for plant growth. (4) It aids to convert rapidly
organic matter into humus which represents the main portion of the nitrogen content
of the soil.
Of course, an excess of lime in the soil may
be hurtful, though less so in arid than in humid regions. Some authors state that
from 8 to 20 per cent of calcium carbonate makes a soil unfitted for plant growth.
There are, however, a great many agricultural soils covering large areas and yielding
very abundant crops which contain very much larger quantities of calcium carbonate.
For instance, in the Sanpete Valley of Utah, one of the most fertile sections of
the Great Basin, agricultural soils often contain as high as 40 per cent of calcium
carbonate, without injury to their crop-producing power.
In the table are two columns headed " Soluble
Silica" and "Alumina," in both of which it is evident that a very
much larger per cent is found in the arid than in the humid soils. These soil constituents
indicate the condition of the soil with reference to the availability of its fertility
for plant use. The higher the percentage of soluble silica and alumina, the more
thoroughly decomposed, in all probability, is the soil as a whole and the more readily
can plants secure their nutriment from the soil. It will be observed from the table,
as previously stated, that more humus is found in humid than in arid soils, though
the difference is not so large as might be expected. It should be recalled, however,
that the nitrogen content of humus formed under rainless conditions is many times
larger than that of humus formed in rainy countries, and that the smaller per cent
of humus in dry-farming countries is thereby offset.
All in all, the composition of arid soils is
very much more favorable to plant growth than that of humid soils. As will be shown
in Chapter IX, the greater fertility of arid soils is one of the chief reasons for
dry-farming success. Depth of the soil alone does not suffice. There must be a large
amount of high fertility available for plants in order that the small amount of water
can be fully utilized in plant growth.
Summary of characteristics.--Arid soils
differ from humid soils in that they contain: less clay; more sand, but of fertile
nature because it is derived from rocks that in humid countries would produce clay;
less humus, but that of a kind which contains about 3-1/2 times more nitrogen than
the humus of humid soils; more lime, which helps in a variety of ways to improve
the agricultural value of soils; more of all the essential plant-foods, because the
leaching by downward drainage is very small in countries of limited rainfall.
Further, arid soils show no real difference between
soil and subsoil; they are deeper and more permeable; they are more uniform in structure;
they have hardpans instead of clay subsoil, which, however, disappear under the influence
of cultivation; their subsoils to a depth of ten feet or more are as fertile as the
topsoil, and the availability of the fertility is greater. The failure to recognize
these characteristic differences between arid and humid soils has been the chief
cause for many crop failures in the more or less rainless regions of the world.
This brief review shows that, everything considered,
arid soils are superior to humid soils. In ease of handling, productivity, certainty
of crop-lasting quality, they far surpass the soils of the countries in which scientific
agriculture was founded. As Hilgard has suggested, the historical datum that the
majority of the most populous and powerful historical peoples of the world have been
located on soils that thirst for water, may find its explanation in the intrinsic
value of arid soils. From Babylon to the United States is a far cry; but it is one
that shouts to the world the superlative merits of the soil that begs for water.
To learn how to use the "desert" is to make it "blossom like the rose."
Soil divisions
The dry-farm territory of the United States may
be divided roughly into five great soil districts, each of which includes a great
variety of soil types, most of which are poorly known and mapped. These districts
are:--
1. Great Plains district.
2. Columbia River district
3. Great Basin district.
4. Colorado River district.
5. California district.
Great Plains district.--On the eastern
slope of the Rocky Mountains, extending eastward to the extreme boundary of the dry-farm
territory, are the soils of the High Plains and the Great Plains. This vast soil
district belongs to the drainage basin of the Missouri, and includes North and South
Dakota, Nebraska, Kansas, Oklahoma, and parts of Montana, Wyoming, Colorado, New
Mexico, Texas, and Minnesota. The soils of this district are usually of high fertility.
They have good lasting power, though the effect of the higher rainfall is evident
in their composition. Many of the distinct types of the plains soils have been determined
with considerable care by Snyder and Lyon, and may be found described in Bailey's
"Cyclopedia of American Agriculture," Vol. I.
Columbia River district.--The second great
soil district of the dry-farming territory is located in the drainage basin of the
Columbia River, and includes Idaho and the eastern two thirds of Washington and Oregon.
The high plains of this soil district are often spoken of as the Palouse country.
The soils of the western part of this district are of basaltic origin; over the southern
part of Idaho the soils have been made from a somewhat recent lava flow which in
many places is only a few feet below the surface. The soils of this district are
generally of volcanic origin and very much alike. They are characterized by the properties
which normally belong to volcanic soils; somewhat poor in lime, but rich in potash
and phosphoric acid. They last well under ordinary methods of tillage.
The Great Basin.--The third great soil
district is included in the Great Basin, which covers nearly all of Nevada, half
of Utah, and takes small portions out of Idaho, Oregon, and southern California.
This basin has no outlet to the sea. Its rivers empty into great saline inland lakes,
the chief of which is the Great Salt Lake. The sizes of these interior lakes are
determined by the amounts of water flowing into them and the rates of evaporation
of the water into the dry air of the region.
In recent geological times, the Great Basin was
filled with water, forming a vast fresh-water lake known as Lake Bonneville, which
drained into the Columbia River. During the existence of this lake, soil materials
were washed from the mountains into the lake and deposited on the lake bottom. When
at length, the lake disappeared, the lake bottom was exposed and is now the farming
lands of the Great Basin district. The soils of this district are characterized by
great depth and uniformity, an abundance of lime, and all the essential plant-foods
with the exception of phosphoric acid, which, while present in normal quantities,
is not unusually abundant. The Great Basin soils are among the most fertile on the
American Continent.
Colorado River district.--The fourth soil
district lies in the drainage basin of the Colorado River It includes much of the
southern part of Utah, the eastern part of Colorado, part of New Mexico, nearly all
of Arizona, and part of southern California. This district, in its northern part,
is often spoken of as the High Plateaus. The soils are formed from the easily disintegrated
rocks of comparatively recent geological origin, which themselves are said to have
been formed from deposits in a shallow interior sea which covered a large part of
the West. The rivers running through this district have cut immense canons with perpendicular
walls which make much of this country difficult to traverse. Some of the soils are
of an extremely fine nature, settling firmly and requiring considerable tillage before
they are brought to a proper condition of tilth. In many places the soils are heavily
charged with calcium sulfate, or crystals of the ordinary land plaster. The fertility
of the soils, however, is high, and when they are properly cultivated, they yield
large and excellent crops.
California district.--The fifth soil district
lies in California in the basin of the Sacramento and San Joaquin rivers. The soils
are of the typical arid kind of high fertility and great lasting powers. They represent
some of the most valuable dry-farm districts of the West. These soils have been studied
in detail by Hilgard.
Dry-farming in the five districts. --It
is interesting to note that in all of these five great soil districts dry-farming
has been tried with great success. Even in the Great Basin and the Colorado River
districts, where extreme desert conditions often prevail and where the rainfall is
slight, it has been found possible to produce profitable crops without irrigation.
It is unfortunate that the study of the dry-farming territory of the United States
has not progressed far enough to permit a comprehensive and correct mapping of its
soils. Our knowledge of this subject is, at the best, fragmentary. We know, however,
with certainty that the properties which characterize arid soils, as described in
this chapter' are possessed by the soils of the dry-farming territory, including
the five great districts just enumerated. The characteristics of arid id soils increase
as the rainfall decreases and other conditions of aridity increase. They are less
marked as we go eastward or westward toward the regions of more abundant rainfall;
that is to say, the most highly developed arid soils are found in the Great Basin
and Colorado River districts. The least developed are on the eastern edge of the
Great Plains.
The judging of soils
A chemical analysis of a soil, unless accompanied
by a large amount of other information, is of little value to the farmer. The main
points in judging a prospective dry-farm are: the depth of the soil, the uniformity
of the soil to a depth of at least 10 feet, the native vegetation, the climatic conditions
as relating to early and late frosts, the total annual rainfall and its distribution,
and the kinds and yields of crops that have been grown in the neighborhood.
The depth of the soil is best determined by the
use of an auger. A simple soil auger is made from the ordinary carpenter's auger,
1-1/2 to 2 inches in diameter, by lengthening its shaft to 3 feet or more. Where
it is not desirable to carry sectional augers, it is often advisable to have three
augers made: one 3 feet, the other 6, and the third 9 or 10 feet in length. The short
auger is used first and the others afterwards as the depth of the boring increases.
The boring should he made in a large number of average places--preferably one boring
or more on each acre if time and circumstances permit--and the results entered on
a map of the farm. The uniformity of the soil is observed as the boring progresses.
If gravel layers exist, they will necessarily stop the progress of the boring. Hardpans
of any kind will also be revealed by such an examination.
The climatic information must be gathered from
the local weather bureau and from older residents of the section.
The native vegetation is always an excellent
index of dry-farm possibilities. If a good stand of native grasses exists, there
can scarcely be any doubt about the ultimate success of dry-farming under proper
cultural methods. A healthy crop of sagebrush is an almost absolutely certain indication
that farming without irrigation is feasible. The rabbit brush of the drier regions
is also usually a good indication, though it frequently indicates a soil not easily
handled. Greasewood, shadscale, and other related plants ordinarily indicate heavy
clay soils frequently charged with alkali. Such soils should be the last choice for
dry-farming purposes, though they usually give good satisfaction under systems of
irrigation. If the native cedar or other native trees grow in profusion, it is another
indication of good dry-farm possibilities.