Within about 24 hours or so after successfully fertilizing an ovule, the attached silk deteriorates at the base, collapses, and drops away. The pollen tubes contain the male gametes that eventually fertilize the ovules. Pollen grains "captured" by silks quickly germinate and develop pollen tubes that penetrate the silk tissue and elongate to the ovule within about 24 hours. Failure of silks to emerge in the first place (for example, in response to silkballing or severe drought stress) does not bode well for successful pollination. Silk emergence usually occurs in close synchrony with pollen shed ( Nielsen, 2020c), so that duration of silk receptivity is normally not a concern. Natural senescence of silk tissue over time results in collapsed tissue that restricts continued growth of the pollen tube. Silks remain receptive to pollen grain germination for up to 10 days after silk emergence ( Nielsen, 2020b), but deteriorate quickly after about the first 5 days of emergence. Silks continue to elongate until pollen grains are captured and germinate or until they simply deteriorate with age. Silks elongate about 1.5 inches per day during the first few days after they emerge from the husk leaves. Turgor pressure "fuels" the elongation of the silks and so severe drought stress often delays silk elongation and emergence from the husk leaves. Consequently, the silks from the base half of the ear are typically the first to emerge from the husk leaves. Silks begin to elongate soon after the V12 leaf stage (12 leaves with visible leaf collars), beginning with the ovules near the base of the cob and then sequentially up the cob, with the tip ovules silking last. Every ovule (potential kernel) on the ear develops its own silk (the functional stigma of the female flower). Silk emergence is technically the first recognized stage of the reproductive period. A large proportion of that decrease occurs during grain filling and may be partially related to shorter and cooler days in late September and October that naturally slow photosynthesis and encourage plant senescence.
As with leaf staging protocols, the kernel growth stage for an entire field is defined when at least 50% of the plants in a field have reached that stage.ĭelayed planting of corn decreases the apparent thermal time (GDDs) required between planting and physiological maturity ( Nielsen, 2019).
Kernel development proceeds through several distinct stages that were originally described by Hanway (1971) and most recently by Abendroth et al. Some research indicates that the upper leaf canopy, from the ear leaf to the uppermost leaf, is responsible for no less than 60% of the photosynthate necessary for filling the grain. The health of the upper leaf canopy is particularly important for achieving maximum grain filling capacity. A stress-free grain fill period can maximize the yield potential of a crop, while severe stress during grain fill can cause kernel abortion or lightweight grain and encourage the development of stalk rot.