Jr. Frederick et Jj. Camberato, WATER AND NITROGEN EFFECTS ON WINTER-WHEAT IN THE SOUTHEASTERN COASTAL-PLAIN .1. GRAIN-YIELD AND KERNEL TRAITS, Agronomy journal, 87(3), 1995, pp. 521-526
Understanding how environmental factors affect winter wheat (Triticum
aestivum L. emend. Thell.) responses to spring N application is an imp
ortant component of economically and environmentally sound winter whea
t production on the southeastern Coastal Plain of the USA. Increasing
the amount of N applied to winter wheat grown in this region has been
shown to result in a greater severity of drought stress during grain f
ill and loner individual kernel weights. This 2-yr field study was con
ducted to determine whether drought-induced reductions in kernel weigh
t with high spring N rates are the result of decreases in the rate or
the duration of kernel growth. Winter wheat was grown with different r
ates of springapplied N (0, 45, 90 and 135 kg N ha(-1)) under both irr
igated and nonirrigated conditions. Increases in the rate of springapp
lied N resulted in a greater severity of soil water deficits under non
irrigated conditions. Quadratic increases in grain yield and kernel nu
mber per square meter occurred in response to increased spring N under
both levels of soil water treatment. Grain yield and individual kerne
l weight responses to irrigation were greater at the higher N rates th
an at the lower N rates. Over both years, the average increase in indi
vidual kernel weight due to irrigation was 3.9 and 13.3% at the 0 and
135 kg N ha(-1) rates, respectively. Similar responses were found for
the effective filling period (EFP), where irrigation increased the EFP
an average of 3.2 and 14.5% at the lowest and highest spring N rates,
respectively. Soil water treatment had no effect on kernel growth rat
e. Results indicate that high rates of spring-applied N increase the s
everity of drought stress in nonirrigated winter wheat grown on the Co
astal Plain, resulting in reductions in the EFP and, consequently, ker
nel weight.