CHAPTER II
THE THEORETICAL BASIS OF DRY-FARMING
THE confidence with which scientific investigators,
familiar with the arid regions, have attacked the problems of dry-farming rests largely
on the known relationship of the water requirements of plants to the natural precipitation
of rain and snow. It is a most elementary fact of plant physiology that no plant
can live and grow unless it has at its disposal a sufficient amount of water.
The water used by plants is almost entirely taken
from the soil by the minute root-hairs radiating from the roots. The water thus taken
into the plants is passed upward through the stem to the leaves, where it is finally
evaporated. There is, therefore, a more or less constant stream of water passing
through the plant from the roots to the leaves.
By various methods it is possible to measure
the water thus taken from the soil. While this process of taking water from the soil
is going on within the plant, a certain amount of soil-moisture is also lost by direct
evaporation from the soil surface. In dry-farm sections, soil-moisture is lost only
by these two methods; for wherever the rainfall is sufficient to cause drainage from
deep soils, humid conditions prevail.
Water for one pound dry matter
Many experiments have been conducted to determine
the amount of water used in the production of one pound of dry plant substance. Generally,
the method of the experiments has been to grow plants in large pots containing weighed
quantities of soil. As needed, weighed amounts of water were added to the pots. To
determine the loss of water, the pots were weighed at regular intervals of three
days to one week. At harvest time, the weight of dry matter was carefully determined
for each pot. Since the water lost by the pots was also known, the pounds of water
used for the production of every pound of dry matter were readily calculated.
The first reliable experiments of the kind were
undertaken under humid conditions in Germany and other European countries. From the
mass of results, some have been selected and presented in the following table. The
work was done by the famous German investigators, Wollny, Hellriegel, and Sorauer,
in the early eighties of the last century. In every case, the numbers in the table
represent the number of pounds of water used for the production of one pound of ripened
dry substance:
Pounds Of Water For One Pound Of Dry Matter
| |
Wollny |
Hellreigel |
Sorauer |
| Wheat |
|
338 |
459 |
| Oats |
665 |
376 |
569 |
| Barley |
|
310 |
431 |
| Rye |
774 |
353 |
236 |
| Corn |
233 |
|
|
| Buckwheat |
646 |
363 |
|
| Peas |
416 |
273 |
|
| Horsebeans |
|
282 |
|
| Red clover |
|
310 |
|
| Sunflowers |
490 |
|
|
| Millet |
447 |
|
|
It is clear from the above results, obtained
in Germany, that the amount of water required to produce a pound of dry matter is
not the same for all plants, nor is it the same under all conditions for the same
plant. In fact, as will be shown in a later chapter, the water requirements of any
crop depend upon numerous factors, more or less controllable. The range of the above
German results is from 233 to 774 pounds, with an average of about 419 pounds of
water for each pound of dry matter produced.
During the late eighties and early nineties,
King conducted experiments similar to the earlier German experiments, to determine
the water requirements of crops under Wisconsin conditions. A summary of the results
of these extensive and carefully conducted experiments is as follows:--
| Oats |
385 |
| Barley |
464 |
| Corn |
271 |
| Peas |
477 |
| Clover |
576 |
| Potatoes |
385 |
The figures in the above table, averaging
about 446 pounds, indicate that very nearly the same quantity of water is required
for the production of crops in Wisconsin as in Germany. The Wisconsin results tend
to be somewhat higher than those obtained in Europe, but the difference is small.
It is a settled principle of science, as will
be more fully discussed later, that the amount of water evaporated from the soil
and transpired by plant leaves increases materially with an increase in the average
temperature during the growing season, and is much higher under a clear sky and in
districts where the atmosphere is dry. Wherever dry-farming is likely to be practiced,
a moderately high temperature, a cloudless sky, and a dry atmosphere are the prevailing
conditions. It appeared probable therefore, that in arid countries the amount of
water required for the production of one pound of dry matter would be higher than
in the humid regions of Germany and Wisconsin. To secure information on this subject,
Widtsoe and Merrill undertook, in 1900, a series of experiments in Utah, which were
conducted upon the plan of the earlier experimenters. An average statement of the
results of six years' experimentation is given in the subjoined table, showing the
number of pounds of water required for one pound of dry matter on fertile soils:--
| Wheat |
1048 |
| Corn |
589 |
| Peas |
1118 |
| Sugar Beets |
630 |
These Utah findings support strongly the doctrine
that the amount of water required for the production of each pound of dry matter
is very much larger under arid conditions, as in Utah, than under humid conditions,
as in Germany or Wisconsin. It must be observed, however, that in all of these experiments
the plants were supplied with water in a somewhat wasteful manner; that is, they
were given an abundance of water, and used the largest quantity possible under the
prevailing conditions. No attempt of any kind was made to economize water. The results,
therefore, represent maximum results and can be safely used as such. Moreover, the
methods of dry-farming, involving the storage of water in deep soils and systematic
cultivation, were not employed. The experiments, both in Europe and America, rather
represent irrigated conditions. There are good reasons for believing that in Germany,
Wisconsin, and Utah the amounts above given can be materially reduced by the employment
of proper cultural methods.
The water in the large bottle would be required to produce the
grain in the small bottle.
In view of these findings concerning the water
requirements of crops, it cannot be far from the truth to say that, under average
cultural conditions, approximately 750 pounds of water are required in an arid district
for the production of one pound of dry matter. Where the aridity is intense, this
figure may be somewhat low, and in localities of sub-humid conditions, it will undoubtedly
be too high. As a maximum average, however, for districts interested in dry-farming,
it can be used with safety.
Crop-producing power of rainfall
If this conclusion, that not more than 750 pounds
of water are required under ordinary dry-farm conditions for the production of one
pound of dry matter, be accepted, certain interesting calculations can be made respecting
the possibilities of dry-farming. For example, the production of one bushel of wheat
will require 60 times 750, or 45,000 pounds of water. The wheat kernels, however,
cannot be produced without a certain amount of straw, which under conditions of dry-farming
seldom forms quite one half of the weight of the whole plant. Let us say, however,
that the weights of straw and kernels are equal. Then, to produce one bushel of wheat,
with the corresponding quantity of straw, would require 2 times 45,000, or 90,000
pounds of water. This is equal to 45 tons of water for each bushel of wheat. While
this is a large figure, yet, in many localities, it is undoubtedly well within the
truth. In comparison with the amounts of water that fall upon the land as rain, it
does not seem extraordinarily large.
One inch of water over one acre of land weighs
approximately 226,875 pounds. or over 113 tons. If this quantity of water could be
stored in the soil and used wholly for plant production, it would produce, at the
rate of 45 tons of water for each bushel, about 2-1/2 bushels of wheat. With 10 inches
of rainfall, which up to the present seems to be the lower limit of successful dry-farming,
there is a maximum possibility of producing 25 bushels of wheat annually.
In the subjoined table, constructed on the basis
of the discussion of this chapter, the wheat-producing powers of various degrees
of annual precipitation are shown:--
One acre inch of water will produce 2-1/2 bushels of wheat.
Ten acre inches of water will produce 25 bushels of wheat.
Fifteen acre inches of water will produce 37-1/2 bushels of wheat.
Twenty acre inches of water will produce 50 bushels of wheat.
It must be distinctly remembered, however, that
under no known system of tillage can all the water that falls upon a soil be brought
into the soil and stored there for plant use. Neither is it possible to treat a soil
so that all the stored soil-moisture may be used for plant production. Some moisture,
of necessity, will evaporate directly from the soil, and some may be lost in many
other ways. Yet, even under a rainfall of 12 inches, if only one half of the water
can be conserved, which experiments have shown to be very feasible, there is a possibility
of producing 30 bushels of wheat per acre every other year, which insures an excellent
interest on the money and labor invested in the production of the crop.
It is on the grounds outlined in this chapter
that students of the subject believe that ultimately large areas of the 'desert"
may be reclaimed by means of dry-farming. The real question before the dry-farmer
is not, "Is the rainfall sufficient?" but rather, "Is it possible
so to conserve and use the rainfall as to make it available for the production of
profitable crops?"