High boron concentration in the soil causes yield reduction. Recently,
a piecewise linear response curve was applied to describe yield respo
nse to B in near steady-state conditions. However, application of simi
lar curves to field situations where water, B, and other ion contents
are transient and nonhomogeneous is limited. The objective of this stu
dy was to develop a model for simulation of the integrated effects of
B, inert salt, and water on crop yield under field conditions. The mod
el computes water flow in response to irrigation, rain, or evapotransp
iration processes and subsequently computes inert salt and B transport
. Crop yield is related to soil matric and osmotic potentials and B to
xicity. Effects of B toxicity are considered by adapting the steady-st
ate approach to the transient situation. Field experiments with barley
(Hordeum vulgare L.) and corn (Zea mays L.) were conducted on the Uta
h Power & Light Co. research farm (Huntington, UT). Soil was Penoyer l
oam [coarse-silty, mixed (calcareous), mesic Typic Torriorthent]. Line
source irrigation was used to obtain different irrigation levels. The
effects of B, Salt (mixture of Na, Ca, Cl, and SO4), and B + Salt on
yield were studied in barley. The effect of B + Salt was studied also
in corn. Measurements and simulations were in close agreement for both
crops. Barley yield ranked B + Salt < B < Salt < control. Corn yield
ranked B + Salt < control. The B adsorption properties result in less
leaching than do those of an inert ion like Cl. The effects of initial
and boundary conditions together with the B adsorption characteristic
s on B concentration in the soil solution and the subsequent yield red
uction are presented. This model can serve for an analysis of the long
-term effects of high B and help in understanding the relative effects
of available water, inert salt, and B on yields.