200 lb. of nitrogen, or less, because the soil provides the rest of the nitrogen. Our challenge is to make sure sufficient nitrogen is present when the plant needs it throughout the growing season. That requirement is small at the beginning and becomes very large later in the season. And it varies
by hybrid.” As shown in the graph, right after emergence, corn takes up only a very small amount of nitrogen. By the time a plant reaches the V5 growth stage (five leaf collars showing), it might contain only 8 to 10 grams of dry matter in its leaves, stalks and roots, and that dry matter is only 1.5% to 2% nitrogen. So at 36,000 plants per acre, one acre of corn takes up only about 1.2 lb. of nitrogen through the V5 stage.
1 lb. of nitrogen,” Ferrie says. “If you applied anhydrous ammonia 7" to 8" deep the previous fall, the nitrogen might still be there, but it will be out of reach for the plant.” Another factor is the carbon penalty, in which a large volume of old
crop residue stimulates microorganism populations and causes soil nitrogen to become tied up and unavailable until later in the season. Ferrie’s studies show the carbon penalty can tie up 100 lb. per acre of applied nitrogen. “So you must manage for the soil environment,” he says. “It will be different for continuous corn than for a corn/soybean rotation, and it will be affected by various cover crops and tillage systems.” At the V8 stage, corn plants shift into rapid uptake. From then through the rest of the season, plants take up
5 lb. to 10 lb. of nitrogen per day. During the V5 through V8 growth stages, sufficient nitrogen is critical because that’s when many hybrids begin adjusting their potential ear size. “If a plant suffers serious nitrogen deficiency between the V5 and V8 growth stages, it might cut back from 18 rows of kernels to 14 or 16,” Ferrie says. “Once a plant scales back its ear girth, we can’t get it back.” From V12 to R3, plants store nitrogen in their stalks. If at any time a plant can’t meet its nitrogen needs, it translocates nitrogen from its stalk to the grain. At about R3, the plant begins heavy translocation of nitrogen from the stalk to the grain, as plants work on filling kernel depth. Through R4 and R5, entering the dent stage, the plant continues to translocate nitrogen from the stalk into the grain. “If the stalk is empty of nitrogen at this time, it will affect grain fill,” Ferrie says. At V12, growth becomes so rapid that, as farmers often say, you can hear the corn grow. “At this stage, the nitrogen uptake rate is steep, and the supply is critical,” Ferrie says. “This is the crucial period in which maximum ear length still is being negotiated inside the plant. It continues all the way to grain fill. After V12, if we stress the plant very long, without enough nitrogen, it might start to abort kernels. “Kernel abortion can continue into the dough stage, and, once it happens, you can’t get those kernels back. Our studies have shown, by the time we see lighter green color in nitrogen-
deficient strips, we usually have given up some yield. We can turn those plants green again by applying nitrogen—and we have to, to avoid losing much more yield—but we can’t make up the lost yield potential. “If corn plants change color, you were not just-in-time with your nitrogen application; the corn plant has already slowed down,” he adds. The final factor in your nitrogen is your hybrids’ response pattern. “Companies are starting to provide information about whether their hybrids prefer nitrogen up front, at the back end of the season or broken up with split applications,” Ferrie says. “If this information is not available for your hybrids, you can incorporate nitrogen timing into a hybrid test plot and observe the response.” To analyze a hybrid’s response to nitrogen timing, consider how it flexes its ear. “Our studies convince me all hybrids flex,” Ferrie says. “They flex only one direction—downward. In other words, if you plant a hybrid at a very low population, it will maximize ear size to its genetic potential; with enough sun and nutrients you may get multiple ears. As we crowd plants in the row, ears flex downward in size.” Based on three years of hand-harvested hybrid studies, in which Ferrie and his crew counted and weighed every kernel, they found the hybrids in their plots flexed three ways: number of rows of kernels, length and depth of kernel. “Some hybrids flex all three—girth, length and depth; I call them full-flex hybrids,” Ferrie says. “Others, which we call determinate, flex only in depth of kernel. In between are some semi-flex and semi-determinate hybrids.