Soil moisture limits forage product

Soil moisture limits forage production potential the most in semiarid regions. Estimated water use
efficiency for irrigated and dry-land crop production systems is 50 percent, and available soil water
has a large impact on management decisions producers make throughout the year. Soil moisture
available for plant growth makes up approximately 0.01 percent of the world's stored water.
By understanding a little about the soil's physical properties and its relationship to soil moisture,
you can make better soil-management decisions. Soil texture and structure greatly influence water
infiltration, permeability, and water-holding capacity.
Soil texture refers to the composition of the soil in terms of the proportion of small, medium, and
large particles (clay, silt, and sand, respectively) in a specific soil mass. For example, a coarse
soil is a sand or loamy sand, a medium soil is a loam, silt loam, or silt, and a fine soil is a sandy
clay, silty clay, or clay.
Soil structure refers to the arrangement of soil particles (sand, silt, and clay) into stable units
called aggregates, which give soil its structure. Aggregates can be loose and friable, or they can
form distinct, uniform patterns. For example, granular structure is loose and friable, blocky
structure is six-sided and can have angled or rounded sides, and platelike structure is layered and
may indicate compaction problems.
Soil porosity refers to the space between soil particles, which consists of various amounts of
water and air. Porosity depends on both soil texture and structure. For example, a fine soil has
smaller but more numerous pores than a coarse soil. A coarse soil has bigger particles than a fine
soil, but it has less porosity, or overall pore space. Water can be held tighter in small pores than in
large ones, so fine soils can hold more water than coarse soils.
Water infiltration is the movement of water from the soil surface into the soil profile. Soil texture,
soil structure, and slope have the largest impact on infiltration rate. Water moves by gravity into the
open pore spaces in the soil, and the size of the soil particles and their spacing determines how
much water can flow in. Wide pore spacing at the soil surface increases the rate of water
infiltration, so coarse soils have a higher infiltration rate than fine soils.
Permeability refers to the movement of air and water through the soil, which is important because
it affects the supply of root-zone air, moisture, and nutrients available for plant uptake. A soil's
permeability is determined by the relative rate of moisture and air movement through the most
restrictive layer within the upper 40 inches of the effective root zone. Water and air rapidly
permeate coarse soils with granular subsoils, which tend to be loose when moist and don't restrict
water or air movement. Slow permeability is characteristic of a moderately fine subsoil with
angular to subangular blocky structure. It is firm when moist and hard when dry.