Corn Pollination Affected by Heat and Drought

Key Points

 

  • Extended periods of high temperatures may negatively affect corn pollination. 
  • Heat can reduce viability, production, and release of pollen grains. 
  • Silks can dry out under extreme high temperatures before pollen shed. 

Heat Stress and Drought Stress

 

High-temperature damage to corn typically coincides with drought stress. It is difficult to separate the effects of drought and heat stress. However, high temperatures alone are not believed to severely stress corn pollination when there is adequate soil moisture.1     

High-Temperature Effects on Silking

 

Silks that dry out before pollen shed become less receptive to pollen, which can lead to reduced kernel set in ears. Consistent and timely silking is needed to allow for a viable silk and pollen grain to unite. Exposed corn silks can be killed prematurely when humidity is low and temperatures exceed 95 °F.1   Hot weather does not greatly slow the rate of silk elongation.  

Figure 1. High temperatures alone do not affect the rate of silk elongation.   Figure 1. High temperatures alone do not affect the rate of silk elongation.

Pollen Shed is Affected by Heat

 

Each tassel produces millions of pollen grains providing adequate pollen in most conditions.2,3 An individual tassel can shed pollen for a week with peak shed occurring on the second or third day.2  Hot temperatures along with dry weather can hasten pollen shed. Pollen production may be reduced by continuous hot weather occurring a few days before and during pollination as photosynthesis may not be efficient and carbohydrate production can be reduced.   

Pollen shed from anthers is called dehiscence and occurs when there is a drop in humidity as temperatures begin to rise.4  Typically, pollen shed begins in the early to mid-morning when temperatures are not as extreme with a second ‘flush’ of pollen shed sometimes occurring in the later afternoon with cooler temperatures. Humidity and temperature conditions can affect dehiscence, and a decrease in pollen shed has been reported when temperatures are greater than 86 °F.   

Until all anthers have shed pollen from the tassel, new pollen continues to mature from anthers. Pollen grains have a thin outer membrane and remain viable for 18 to 24 hours in favorable conditions.3  Viability is reduced to a couple of hours or less in extreme heat.4  Temperatures of 100 °F or greater cause extreme heat stress that can sometimes desiccate pollen before it can successfully fertilize an ovule or kernel.2   High temperatures can also reduce viability before pollen grains are shed by anthers.4  

Figure 2. Tassels provide millions of pollen grains in a typical year, but pollen load can be reduced or have reduced viability in extreme heat.  Figure 2. Tassels provide millions of pollen grains in a typical year, but pollen load can be reduced or have reduced viability in extreme heat.

Summary

 

Kernel set can be irregular on ears when pollen shed and silk elongation are not synchronized. This is more common when moisture stress accompanies heat stress. Pollination can be successful during stretches of high temperatures if adequate moisture is supplied to the plant. Additional conditions that facilitate successful pollination include cooler nighttime temperatures, healthy soil structure, and corn products with close timing between mid-pollen shed and mid-silking date.   

 

 

Sources

1How high temperatures and stress affect corn pollination. Iowa State University. http://www.agronext.iastate.edu. 

2Nielsen, R.L. 2010. Tassel emergence and pollen shed. Corny News Network. Purdue University Extension.

3Thomison, P. Corn pollination—an overview. The Ohio State University. AGF-128-95.

4Hoegemeyer, T. 2011. How extended high heat disrupts corn pollination. University of Nebraska—Lincoln. https://cropwatch.unl.edu.

Web sources verified 05/26/16 .  

 

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