CHAPTER VII
STORING WATER IN THE SOIL
THE large amount of water required for the production
of plant substance is taken from the soil by the roots. Leaves and stems do not absorb
appreciable quantities of water. The scanty rainfall of dry-farm districts or the
more abundant precipitation of humid regions must, therefore, be made to enter the
soil in such a manner as to be readily available as soil-moisture to the roots at
the right periods of plant growth.
In humid countries, the rain that falls during
the growing season is looked upon, and very properly, as the really effective factor
in the production of large crops. The root systems of plants grown under such humid
conditions are near the surface, ready to absorb immediately the rains that fall,
even if they do not soak deeply into the soil. As has been shown in Chapter IV, it
is only over a small portion of the dry-farm territory that the bulk of the scanty
precipitation occurs during the growing season. Over a large portion of the arid
and semiarid region the summers are almost rainless and the bulk of the precipitation
comes in the winter, late fall, or early spring when plants are not growing. If the
rains that fall during the growing season are indispensable in crop production, the
possible area to be reclaimed by dry-farming will be greatly limited. Even when much
of the total precipitation comes in summer, the amount in dry-farm districts is seldom
sufficient for the proper maturing of crops. In fact, successful dry-farming depends
chiefly upon the success with which the rains that fall during any season of the
year may be stored and kept in the soil until needed by plants in their growth. The
fundamental operations of dry-farming include a soil treatment which enables the
largest possible proportion of the annual precipitation to be stored in the soil.
For this purpose, the deep, somewhat porous soils, characteristic of arid regions,
are unusually well adapted.
Alway's demonstration
An important and unique demonstration of the
possibility of bringing crops to maturity on the moisture stored in the soil at the
time of planting has been made by Alway. Cylinders of galvanized iron, 6 feet long,
were filled with soil as nearly as possible in its natural position and condition
Water was added until seepage began, after which the excess was allowed to drain
away. When the seepage had closed, the cylinders were entirely closed except at the
surface. Sprouted grains of spring wheat were placed in the moist surface soil, and
1 inch of dry soil added to the surface to prevent evaporation. No more water was
added; the air of the greenhouse was kept as dry as possible. The wheat developed
normally. The first ear was ripe in 132 days after planting and the last in 143 days.
The three cylinders of soil from semiarid western Nebraska produced 37.8 grams of
straw and 29 ears, containing 415 kernels weighing 11.188 grams. The three cylinders
of soil from humid eastern Nebraska produced only 11.2 grams of straw and 13 ears
containing 114 kernels, weighing 3 grams. This experiment shows conclusively that
rains are not needed during the growing season, if the soil is well filled with moisture
at seedtime, to bring crops to maturity.
What becomes of the rainfall ?
The water that falls on the land is disposed
of in three ways: First, under ordinary conditions, a large portion runs off without
entering the soil; secondly, a portion enters the soil, but remains near the surface,
and is rapidly evaporated back into the air; and, thirdly, a portion enters the lower
soil layers, from which it is removed at later periods by several distinct processes.
The run-off is usually large and is a serious loss, especially in dry-farming regions,
where the absence of luxuriant vegetation, the somewhat hard, sun-baked soils, and
the numerous drainage channels, formed by successive torrents, combine to furnish
the rains with an easy escape into the torrential rivers. Persons familiar with arid
conditions know how quickly the narrow box cañons, which often drain thousands
of square miles, are filled with roaring water after a comparatively light rainfall.
The run-off
The proper cultivation of the soil diminishes
very greatly the loss due to run-off, but even on such soils the proportion may often
be very great. Farrel observed at one of the Utah stations that during a torrential
rain--2.6 inches in 4 hours--the surface of the summer fallowed plats was packed
so solid that only one fourth inch, or less than one tenth of the whole amount, soaked
into the soil, while on a neighboring stubble field, which offered greater hindrance
to the run-off, 1-1/2 inches or about 60 per cent were absorbed.
It is not possible under any condition to prevent
the run-off altogether, although it can usually be reduced exceedingly. It is a common
dry-farm custom to plow along the slopes of the farm instead of plowing up and down
them. When this is done, the water which runs down the slopes is caught by the succession
of furrows and in that way the runoff is diminished. During the fallow season the
disk and smoothing harrows are run along the hillsides for the same purpose and with
results that are nearly always advantageous to the dry-farmer. Of necessity, each
man must study his own farm in order to devise methods that will prevent the run-off.
The structure of soils
Before examining more closely the possibility
of storing water in soils a brief review of the structure of soils is desirable.
As previously explained, soil is essentially a mixture of disintegrated rock and
the decomposing remains of plants. The rock particles which constitute the major
portion of soils vary greatly in size. The largest ones are often 500 times the sizes
of the smallest. It would take 50 of the coarsest sand particles, and 25,000 of the
finest silt particles, to form one lineal inch. The clay particles are often smaller
and of such a nature that they cannot be accurately measured. The total number of
soil particles in even a small quantity of cultivated soil is far beyond the ordinary
limits of thought, ranging from 125,000 particles of coarse sand to 15,625,000,000,000
particles of the finest silt in one cubic inch. In other words, if all the particles
in one cubic inch of soil consisting of fine silt were placed side by side, they
would form a continuous chain over a thousand miles long. The farmer, when he tills
the soil, deals with countless numbers of individual soil grains, far surpassing
the understanding of the human mind. It is the immense number of constituent soil
particles that gives to the soil many of its most valuable properties.
It must be remembered that no natural soil is
made up of particles all of which are of the same size; all sizes, from the coarsest
sand to the finest clay, are usually present. These particles of all sizes are not
arranged in the soil in a regular, orderly way; they are not placed side by side
with geometrical regularity; they are rather jumbled together in every possible way.
The larger sand grains touch and form comparatively large interstitial spaces into
which the finer silt and clay grains filter. Then, again, the clay particles, which
have cementing properties, bind, as it were, one particle to another. A sand grain
may have attached to it hundreds, or it may be thousands, of the smaller silt grains;
or a regiment of smaller soil grains may themselves be clustered into one large grain
by cementing power of the clay. Further, in the presence of lime and similar substances,
these complex soil grains are grouped into yet larger and more complex groups. The
beneficial effect of lime is usually due to this power of grouping untold numbers
of soil particles into larger groups. When by correct soil culture the individual
soil grains are thus grouped into large clusters, the soil is said to be in good
tilth. Anything that tends to destroy these complex soil grains, as, for instance,
plowing the soil when it is too wet, weakens the crop-producing power of the soil.
This complexity of structure is one of the chief reasons for the difficulty of understanding
clearly the physical laws governing soils.
Pore-space of soils
It follows from this description of soil structure
that the soil grains do not fill the whole of the soil space. The tendency is rather
to form clusters of soil grains which, though touching at many points, leave comparatively
large empty spaces. This pore space in soils varies greatly, but with a maximum of
about 55 per cent. In soils formed under arid conditions the percentage of pore-space
is somewhere in the neighborhood of 50 per cent. There are some arid soils, notably
gypsum soils, the particles of which are so uniform size that the pore-space is exceedingly
small. Such soils are always difficult to prepare for agricultural purposes.
It is the pore-space in soils that permits the
storage of soil- moisture; and it is always important for the farmer so to maintain
his soil that the pore-space is large enough to give him the best results, not only
for the storage of moisture, but for the growth and development of roots, and for
the entrance into the soil of air, germ life, and other forces that aid in making
the soil fit for the habitation of plants. This can always be best accomplished,
as will be shown hereafter, by deep plowing, when the soil is not too wet, the exposure
of the plowed soil to the elements, the frequent cultivation of the soil through
the growing season, and the admixture of organic matter. The natural soil structure
at depths not reached by the plow evidently cannot be vitally changed by the farmer.
Hygroscopic soil-water
Under normal conditions, a certain amount of
water is always found in all things occurring naturally, soils included. Clinging
to every tree, stone, or animal tissue is a small quantity of moisture varying with
the temperature, the amount of water in the air, and with other well-known factors.
It is impossible to rid any natural substance wholly of water without heating it
to a high temperature. This water which, apparently, belongs to all natural objects
is commonly called hygroscopic water. Hilgard states that the soils of the arid regions
contain, under a temperature of 15° C. and an atmosphere saturated with water,
approximately 5-1/2 per cent of hygroscopic water. In fact, however, the air over
the arid region is far from being saturated with water and the temperature is even
higher than 15° C., and the hygroscopic moisture actually found in the soils
of the dry-farm territory is considerably smaller than the average above given. Under
the conditions prevailing in the Great Basin the hygroscopic water of soils varies
from .75 per cent to 3-1/2 per cent; the average amount is not far from 12 per cent.
Whether or not the hygroscopic water of soils
is of value in plant growth is a disputed question. Hilgard believes that the hygroscopic
moisture can be of considerable help in carrying plants through rainless summers,
and further, that its presence prevents the heating of the soil particles to a point
dangerous to plant roots. Other authorities maintain earnestly that the hygroscopic
soil-water is practically useless to plants. Considering the fact that wilting occurs
long before the hygroscopic water contained in the soil is reached, it is very unlikely
that water so held is of any real benefit to plant growth.
Gravitational water
It often happens that a portion of the water
in the soil is under the immediate influence of gravitation. For instance, a stone
which, normally, is covered with hygroscopic water is dipped into water The hydroscopic
water is not thereby affected, but as the stone is drawn out of the water a good
part of the water runs off. This is gravitational water That is, the gravitational
water of soils is that portion of the soil-water which filling the soil pores, flows
downward through the soil under the influence of gravity. When the soil pores are
completely filled, the maximum amount of gravitational water is found there. In ordinary
dry-farm soils this total water capacity is between 35 and 40 per cent of the dry
weight of soil.
The gravitational soil-water cannot long remain
in that condition; for, necessarily, the pull of gravity moves it downward through
the soil pores and if conditions are favorable, it finally reaches the standing water-table,
whence it is carried to the great rivers, and finally to the ocean. In humid soils,
under a large precipitation, gravitational water moves down to the standing water-table
after every rain. In dry-farm soils the gravitational water seldom reaches the standing
water-table; for, as it moves downward, it wets the soil grains and remains in the
capillary condition as a thin film around the soil grains.
To the dry-farmer, the full water capacity is
of importance only as it pertains to the upper foot of soil. If, by proper plowing
and cultivation, the upper soil be loose and porous, the precipitation is allowed
to soak quickly into the soil, away from the action of the wind and sun. From this
temporary reservoir, the water, in obedience to the pull of gravity, will move slowly
downward to the greater soil depths, where it will be stored permanently until needed
by plants. It is for this reason that dry-farmers find it profitable to plow in the
fall, as soon as possible after harvesting. In fact, Campbell advocates that the
harvester be followed immediately by the disk, later to be followed by the plow The
essential thing is to keep the topsoil open and receptive to a rain.
Capillary soil-water
The so-called capillary soil-water is of greatest
importance to the dry-farmer. This is the water that clings as a film around a marble
that has been dipped into water. There is a natural attraction between water and
nearly all known substances, as is witnessed by the fact that nearly all things may
be moistened. The water is held around the marble because the attraction between
the marble and the water is greater than the pull of gravity upon the water. The
greater the attraction, the thicker the film; the smaller the attraction, the thinner
the film will be. The water that rises in a capillary glass tube when placed in water
does so by virtue of the attraction between water and glass. Frequently, the force
that makes capillary water possible is called surface tension.
Whenever there is a sufficient amount of water
available, a thin film of water is found around every soil grain; and where the soil
grains touch, or where they are very near together, water is held pretty much as
in capillary tubes. Not only are the soil particles enveloped by such a film, but
the plant roots foraging in the soil are likewise covered; that is, the whole system
of soil grains and roots is covered, under favorable conditions, with a thin film
of capillary water. It is the water in this form upon which plants draw during their
periods of growth. The hygroscopic water and the gravitational water are of comparatively
little value in plant growth.
Field capacity of soils for capillary water
The tremendously large number of soil grains
found in even a small amount of soil makes it possible for the soil to hold very
large quantities of capillary water. To illustrate: In one cubic inch of sand soil
the total surface exposed by the soil grains varies from 42 square inches to 27 square
feet; in one cubic inch of silt soil, from 27 square feet to 72 square feet, and
in one cubic inch of an ordinary soil the total surface exposed by the soil grains
is about 25 square feet. This means that the total surface of the soil grains contained
in a column of soil 1 square foot at the top and 10 feet deep is approximately 10
acres. When even a thin film of water is spread over such a large area, it is clear
that the total amount of water involved must be large It is to be noticed, therefore,
that the fineness of the soil particles previously discussed has a direct bearing
upon the amount of water that soils may retain for the use of plant growth. As the
fineness of the soil grains increases, the total surface increases' and the water-holding
capacity also increases.
Naturally, the thickness of a water film held
around the soil grains is very minute. King has calculated that a film 275 millionths
of an inch thick, clinging around the soil particles, is equivalent to 14.24 per
cent of water in a heavy clay; 7.2 per cent in a loam; 5.21 per cent in a sandy loam,
and 1.41 per cent in a sandy soil.
It is important to know the largest amount of
water that soils can hold in a capillary condition, for upon it depend, in a measure,
the possibilities of crop production under dry-farming conditions. King states that
the largest amount of capillary water that can be held in sandy loams varies from
17.65 per cent to 10.67 per cent; in clay loams from 22.67 per cent to 18.16 per
cent, and in humus soils (which are practically unknown in dry-farm sections) from
44.72 per cent to 21.29 per cent. These results were not obtained under dry-farm
conditions and must be confirmed by investigations of arid soils.
The water that falls upon dry-farms is very seldom
sufficient in quantity to reach the standing water-table, and it is necessary, therefore,
to determine the largest percentage of water that a soil can hold under the influence
of gravity down to a depth of 8 or 10 feet--the depth to which the roots penetrate
and in which root action is distinctly felt. This is somewhat difficult to determine
because the many conflicting factors acting upon the soil-water are seldom in equilibrium.
Moreover, a considerable time must usually elapse before the rain-water is thoroughly
distributed throughout the soil. For instance, in sandy soils, the downward descent
of water is very rapid; in clay soils, where the preponderance of fine particles
makes minute soil pores, there is considerable hindrance to the descent of water,
and it may take weeks or months for equilibrium to be established. It is believed
that in a dry-farm district, where the major part of the precipitation comes during
winter, the early springtime, before the spring rains come, is the best time for
determining the maximum water capacity of a soil. At that season the water-dissipating
influences, such as sunshine and high temperature, are at a minimum, and a sufficient
time has elapsed to permit the rains of fall and winter to distribute themselves
uniformly throughout the soil. In districts of high summer precipitation, the late
fall after a fallow season will probably be the best time for the determination of
the field-water capacity.
Experiments on this subject have been conducted
at the Utah Station. As a result of several thousand trials it was found that, in
the spring, a uniform, sandy loam soil of true arid properties contained, from year
to year, an average of nearly 16-1/2 per cent of water to a depth of 8 feet. This
appeared to be practically the maximum water capacity of that soil under field conditions,
and it may be called the field capacity of that soil for capillary water. Other experiments
on dry-farms showed the field capacity of a clay soil to a depth of 8 feet to be
19 per cent; of a clay loam, to be 18 per cent; of a loam, 17 per cent; of another
loam somewhat more sandy, 16 per cent; of a sandy loam, 14-1/2 per cent; and of a
very sandy loam, 14 per cent. Leather found that in the calcareous arid soil of India
the upper 5 feet contained 18 per cent of water at the close of the wet season.
It may be concluded, therefore, that the field-water
capacities of ordinary dry-farm soils are not very high, ranging from 15 to 20 per
cent, with an average for ordinary dry-farm soils in the neighborhood of 16 or 17
per cent. Expressed in another way this means that a layer of water from 2 to 3 inches
deep can be stored in the soil to a depth of 12 inches. Sandy soils will hold less
water than clayey ones. It must not be forgotten that in the dry-farm region are
numerous types of soils, among them some consisting chiefly of very fine soil grains
and which would; consequently, possess field-water capacities above the average here
stated. The first endeavor of the dry-farmer should be to have the soil filled to
its full field-water capacity before a crop is planted.
Downward movement of soil-moisture
One of the chief considerations in a discussion
of the storing of water in soils is the depth to which water may move under ordinary
dry-farm conditions. In humid regions, where the water table is near the surface
and where the rainfall is very abundant, no question has been raised concerning the
possibility of the descent of water through the soil to the standing water. Considerable
objection, however, has been offered to the doctrine that the rainfall of arid districts
penetrates the soil to any great extent. Numerous writers on the subject intimate
that the rainfall under dry-farm conditions reaches at the best the upper 3 or 4
feet of soil. This cannot be true, for the deep rich soils of the arid region, which
never have been disturbed by the husbandman, are moist to very great depths. In the
deserts of the Great Basin, where vegetation is very scanty, soil borings made almost
anywhere will reveal the fact that moisture exists in considerable quantities to
the full depth of the ordinary soil auger, usually 10 feet. The same is true for
practically every district of the arid region.
Such water has not come from below, for in the
majority of cases the standing water is 50 to 500 feet below the surface. Whitney
made this observation many years ago and reported it as a striking feature of agriculture
in arid regions, worthy of serious consideration. Investigations made at the Utah
Station have shown that undisturbed soils within the Great Basin frequently contain,
to a depth of 10 feet, an amount of water equivalent to 2 or 3 years of the rainfall
which normally occurs in that locality. These quantities of water could not be found
in such soils, unless, under arid conditions, water has the power to move downward
to considerably greater depths than is usually believed by dry-farmers.
In a series of irrigation experiments conducted
at the Utah Station it was demonstrated that on a loam soil, within a few hours after
an irrigation, some of the water applied had reached the eighth foot, or at least
had increased the percentage of water in the eighth foot. In soil that was already
well filled with water, the addition of water was felt distinctly to the full depth
of 8 feet. Moreover, it was observed in these experiments that even very small rains
caused moisture changes to considerable depths a few hours after the rain was over.
For instance, 0.14 of an inch of rainfall was felt to a depth of 2 feet within 3
hours; 0.93 of an inch was felt to a depth of 3 feet within the same period.
To determine whether or not the natural winter
precipitation, upon which the crops of a large portion of the dry-farm territory
depend, penetrates the soil to any great depth a series of tests were undertaken.
At the close of the harvest in August or September the soil was carefully sampled
to a depth of 8 feet, and in the following spring similar samples were taken on the
same soils to the same depth. In every case, it was found that the winter precipitation
had caused moisture changes to the full depth reached by the soil auger. Moreover,
these changes were so great as to lead the investigators to believe that moisture
changes had occurred to greater depths.
In districts where the major part of the precipitation
occurs during the summer the same law is undoubtedly in operation; but, since evaporation
is most active in the summer, it is probable that a smaller proportion reaches the
greater soil depths. In the Great Plains district, therefore, greater care will have
to be exercised during the summer in securing proper water storage than in the Great
Basin, for instance. The principle is, nevertheless, the same. Burr, working under
Great Plains conditions in Nebraska, has shown that the spring and summer rains penetrate
the soil to the depth of 6 feet, the average depth of the borings, and that it undoubtedly
affects the soil-moisture to the depth of 10 feet. In general, the dry-farmer may
safely accept the doctrine that the water that falls upon his land penetrates the
soil far beyond the immediate reach of the sun, though not so far away that plant
roots cannot make use of it.
Importance of a moist subsoil
In the consideration of the downward movement
of soil-water it is to be noted that it is only when the soil is tolerably moist
that the natural precipitation moves rapidly and freely to the deeper soil layers.
When the soil is dry, the downward movement of the water is much slower and the bulk
of the water is then stored near the surface where the loss of moisture goes on most
rapidly. It has been observed repeatedly in the investigations at the Utah Station
that when desert land is broken for dry-farm purposes and then properly cultivated,
the precipitation penetrates farther and farther into the soil with every year of
cultivation. For example, on a dry-farm, the soil of which is clay loam, and which
was plowed in the fall of 1904 and farmed annually thereafter, the eighth foot contained
in the spring of 1905, 6.59 per cent of moisture; in the spring of 1906, 13.11 per
cent, and in the spring of 1907, 14.75 per cent of moisture. On another farm, with
a very sandy soil and also plowed in the fall of 1904, there was found in the eighth
foot in the spring of 1905, 5.63 per cent of moisture, in the spring of 1906, 11.41
per cent of moisture, and in the spring of 1907, 15.49 per cent of moisture. In both
of these typical cases it is evident that as the topsoil was loosened, the full field
water capacity of the soil was more nearly approached to a greater depth. It would
seem that, as the lower soil layers are moistened, the water is enabled, so to speak,
to slide down more easily into the depths of the soil.
This is a very important principle for the dry
farmer to understand. It is always dangerous to permit the soil of a dry-farm to
become very dry, especially below the first foot. Dry-farms should be so manipulated
that even at the harvesting season a comparatively large quantity of water remains
in the soil to a depth of 8 feet or more. The larger the quantity of water in the
soil in the fall, the more readily and quickly will the water that falls on the land
during the resting period of fall, winter, and early spring sink into the soil and
move away from the topsoil. The top or first foot will always contain the largest
percentage of water because it is the chief receptacle of the water that falls as
rain or snow but when the subsoil is properly moist, the water will more completely
leave the topsoil. Further, crops planted on a soil saturated with water to a depth
of 8 feet are almost certain to mature and yield well.
If the field-water capacity has not been filled,
there is always the danger that an unusually dry season or a series of hot winds
or other like circumstances may either seriously injure the crop or cause a complete
failure. The dry-farmer should keep a surplus of moisture in the soil to be carried
over from year to year, just as the wise business man maintains a sufficient working
capital for the needs of his business. In fact, it is often safe to advise the prospective
dry-farmer to plow his newly cleared or broken land carefully and then to grow no
crop on it the first year, so that, when crop production begins, the soil will have
stored in it an amount of water sufficient to carry a crop over periods of drouth.
Especially in districts of very low rainfall is this practice to be recommended.
In the Great Plains area, where the summer rains tempt the farmer to give less attention
to the soil-moisture problem than in the dry districts with winter precipitation
farther West, it is important that a fallow season be occasionally given the land
to prevent the store of soil moisture from becoming dangerously low.
To what extent is the rainfall stored in soils?
What proportion of the actual amount of water
falling upon the soil can be stored in the soil and carried over from season to season?
This question naturally arises in view of the conclusion that water penetrates the
soil to considerable depths. There is comparatively little available information
with which to answer this question, because the great majority of students of soil
moisture have concerned themselves wholly with the upper two, three, or four feet
of soil. The results of such investigations are practically useless in answering
this question. In humid regions it may be very satisfactory to confine soil-moisture
investigations to the upper few feet; but in arid regions, where dry-farming is a
living question, such a method leads to erroneous or incomplete conclusions.
Since the average field capacity of soils for
water is about 2.5 inches per foot, it follows that it is possible to store 25 inches
of water in 10 feet of soil. This is from two to one and a half times one year's
rainfall over the better dry-farming sections. Theoretically, therefore, there is
no reason why the rainfall of one season or more could not be stored in the soil.
Careful investigations have borne out this theory. Atkinson found, for example, at
the Montana Station, that soil, which to a depth of 9 feet contained 7.7 per cent
of moisture in the fall contained 11.5 per cent in the spring and, after carrying
it through the summer by proper methods of cultivation, 11 per cent.
It may certainly be concluded from this experiment
that it is possible to carry over the soil moisture from season to season. The elaborate
investigations at the Utah Station have demonstrated that the winter precipitation,
that is, the precipitation that comes during the wettest period of the year, may
be retained in a large measure in the soil. Naturally, the amount of the natural
precipitation accounted for in the upper eight feet will depend upon the dryness
of the soil at the time the investigation commenced. If at the beginning of the wet
season the upper eight feet of soil are fairly well stored with moisture, the precipitation
will move down to even greater depths, beyond the reach of the soil auger. If, on
the other hand, the soil is comparatively dry at the beginning of the season, the
natural precipitation will distribute itself through the upper few feet, and thus
be readily measured by the soil auger.
In the Utah investigations it was found that
of the water which fell as rain and snow during the winter, as high as 95-1/2 per
cent was found stored in the first eight feet of soil at the beginning of the growing
season. Naturally, much smaller percentages were also found, but on an average, in
soils somewhat dry at the beginning of the dry season, more than three fourths of
the natural precipitation was found stored in the soil in the spring. The results
were all obtained in a locality where the bulk of the precipitation comes in the
winter, yet similar results would undoubtedly be obtained where the precipitation
occurs mainly in the summer. The storage of water in the soil cannot be a whit less
important on the Great Plains than in the Great Basin. In fact, Burr has clearly
demonstrated for western Nebraska that over 50 per cent of the rainfall of the spring
and summer may be stored in the soil to the depth of six feet. Without question,
some is stored also at greater depths.
All the evidence at hand shows that a large portion
of the precipitation falling upon properly prepared soil, whether it be summer or
winter, is stored in the soil until evaporation is allowed to withdraw it Whether
or not water so stored may be made to remain in the soil throughout the season or
the year will be discussed in the next chapter. It must be said, however, that the
possibility of storing water in the soil, that is, making the water descend to relatively
great soil depths away from the immediate and direct action of the sunshine and winds,
is the most fundamental principle in successful dry-farming.
The fallow
It may be safely concluded that a large portion
of the water that falls as rain or snow may be stored in the soil to considerable
depths (eight feet or more). However, the question remains, Is it possible to store
the rainfall of successive years in the soil for the use of one crop? In short, Does
the practice of clean fallowing or resting the ground with proper cultivation for
one season enable the farmer to store in the soil the larger portion of the rainfall
of two years, to be used for one crop? It is unquestionably true, as will be shown
later, that clean fallowing or "summer tillage" is one of the oldest and
safest practices of dry-farming as practiced in the West, but it is not generally
understood why fallowing is desirable.
Considerable doubt has recently been cast upon
the doctrine that one of the beneficial effects of fallowing in dry-farming is to
store the rainfall of successive seasons in the soil for the use of one crop. Since
it has been shown that a large proportion of the winter precipitation can be stored
in the soil during the wet season, it merely becomes a question of the possibility
of preventing the evaporation of this water during the drier season. As will be shown
in the next chapter, this can well be effected by proper cultivation.
There is no good reason, therefore, for believing
that the precipitation of successive seasons may not be added to water already stored
in the soil. King has shown that fallowing the soil one year carried over per square
foot, in the upper four feet, 9.38 pounds of water more than was found in a cropped
soil in a parallel experiment; and, moreover, the beneficial effect of this. water
advantage was felt for a whole succeeding season. King concludes, therefore, that
one of the advantages of fallowing is to increase the moisture content of the soil.
The Utah experiments show that the tendency of fallowing is always to increase the
soil-moisture content. In dry-farming, water is the critical factor, and any practice
that helps to conserve water should be adopted. For that reason, fallowing, which
gathers soil-moisture, should be strongly advocated. In Chapter IX another important
value of the fallow will be discussed.
In view of the discussion in this chapter it
is easily understood why students of soil-moisture have not found a material increase
in soil-moisture due to fallowing. Usually such investigations have been made to
shallow depths which already were fairly well filled with moisture. Water falling
upon such soils would sink beyond the depth reached by the soil augers, and it became
impossible to judge accurately of the moisture-storing advantage of the fallow. A
critical analysis of the literature on this subject will reveal the weakness of most
experiments in this respect.
It may be mentioned here that the only fallow
that should be practiced by the dry-farmer is the clean fallow. Water storage is
manifestly impossible when crops are growing upon a soil. A healthy crop of sagebrush,
sunflowers, or other weeds consumes as much water as a first-class stand of corn,
wheat, or potatoes. Weeds should be abhorred by the farmer. A weedy fallow is a sure
forerunner of a crop failure. How to maintain a good fallow is discussed in Chapter
VIII, under the head of Cultivation. Moreover, the practice of fallowing should be
varied with the climatic conditions. In districts of low rainfall, 10-15 inches,
the land should be clean summer-fallowed every other year; under very low rainfall
perhaps even two out of three years; in districts of more abundant rainfall, 15-20
inches, perhaps one year out of every three or four is sufficient. Where the precipitation
comes during the growing season, as in the Great Plains area, fallowing for the storage
of water is less important than where the major part of the rainfall comes during
the fall and winter. However, any system of dry-farming that omits fallowing wholly
from its practices is in danger of failure in dry years.
Deep plowing for water storage
It has been attempted in this chapter to demonstrate
that water falling upon a soil may descend to great depths, and may be stored in
the soil from year to year, subject to the needs of the crop that may be planted.
By what cultural treatment may this downward descent of the water be accelerated
by the farmer? First and foremost, by plowing at the right time and to the right
depth. Plowing should be done deeply and thoroughly so that the falling water may
immediately be drawn down to the full depth of the loose, spongy, plowed soil, away
from the action of the sunshine or winds. The moisture thus caught will slowly work
its way down into the lower layers of the soil. Deep plowing is always to be recommended
for successful dry-farming.
In humid districts where there is a great difference
between the soil and the subsoil, it is often dangerous to turn up the lifeless subsoil,
but in arid districts where there is no real differentiation between the soil and
the subsoil, deep plowing may safely be recommended. True, occasionally, soils are
found in the dry-farm territory which are underlaid near the surface by an inert
clay or infertile layer of lime or gypsum which forbids the farmer putting the plow
too deeply into the soil. Such soils, however' are seldom worth while trying for
dry-farm purposes. Deep plowing must be practiced for the best dry-farming results.
It naturally follows that subsoiling should be
a beneficial practice on dry-farms. Whether or not the great cost of subsoiling is
offset by the resulting increased yields is an open question; it is, in fact, quite
doubtful. Deep plowing done at the right time and frequently enough is possibly sufficient.
By deep plowing is meant stirring or turning the soil to a depth of six to ten inches
below the surface of the land.
Fall plowing far water storage
It is not alone sufficient to plow and to plow
deeply; it is also necessary that the plowing be done at the right time. In the very
great majority of cases over the whole dry-farm territory, plowing should be done
in the fall. There are three reasons for this: First, after the crop is harvested,
the soil should be stirred immediately, so that it can be exposed to the full action
of the weathering agencies, whether the winters be open or closed. If for any reason
plowing cannot be done early it is often advantageous to follow the harvester with
a disk and to plow later when convenient. The chemical effect on the soil resulting
from the weathering, made possible by fall plowing, as will be shown in Chapter IX,
is of itself so great as to warrant the teaching of the general practice of fall
plowing. Secondly, the early stirring of the soil prevents evaporation of the moisture
in the soil during late summer and the fall. Thirdly, in the parts of the dry-farm
territory where much precipitation occurs in the fall, winter, or early spring, fall
plowing permits much of this precipitation to enter the soil and be stored there
until needed by plants.
A number of experiment stations have compared
plowing done in the early fall with plowing done late in the fall or in the spring,
and with almost no exception it has been found that early fall plowing is water-conserving
and in other ways advantageous. It was observed on a Utah dry-farm that the fall-plowed
land contained, to a depth of 10 feet, 7.47 acre-inches more water than the adjoining
spring-plowed land--a saving of nearly one half of a year's precipitation. The ground
should be plowed in the early fall as soon as possible after the crop is harvested.
It should then be left in the rough throughout the winter, so that it may be mellowed
and broken down by the elements. The rough lend further has a tendency to catch and
hold the snow that may be blown by the wind, thus insuring a more even distribution
of the water from the melting snow.
A common objection to fall plowing is that the
ground is so dry in the fall that it does not plow up well, and that the great dry
clods of earth do much to injure the physical condition of the soil. It is very doubtful
if such an objection is generally valid, especially if the soil is so cropped as
to leave a fair margin of moisture in the soil at harvest time. The atmospheric agencies
will usually break down the clods, and the physical result of the treatment will
be beneficial. Undoubtedly, the fall plowing of dry land is somewhat difficult, but
the good results more than pay the farmer for his trouble. Late fall plowing, after
the fall rains have softened the land, is preferable to spring plowing. If for any
reason the farmer feels that he must practice spring plowing, he should do it as
early as possible in the spring. Of course, it is inadvisable to plow the soil when
it is so wet as to injure its tilth seriously, but as soon as that danger period
has passed, the plow should be placed in the ground. The moisture in the soil will
thereby be conserved, and whatever water may fall during the spring months will be
conserved also. This is of especial importance in the Great Plains region and in
any district where the precipitation comes in the spring and winter months.
Likewise, after fall plowing, the land must be
well stirred in the early spring with the disk harrow or a similar implement, to
enable the spring rains to enter the soil easily and to prevent the evaporation of
the water already stored. Where the rainfall is quite abundant and the plowed land
has been beaten down by the frequent rains, the land should be plowed again in the
spring. Where such conditions do not exist, the treatment of the soil with the disk
and harrow in the spring is usually sufficient.
In recent dry-farm experience it has been fairly
completely demonstrated that, providing the soil is well stored with water, crops
will mature even if no rain falls during the growing season. Naturally, under most
circumstances, any rains that may fall on a well-prepared soil during the season
of crop growth will tend to increase the crop yield, but some profitable yield is
assured, in spite of the season, if the soil is well stored with water at seed time.
This is an important principle in the system of dry-farming.