Kansas State University and DuPont Pioneer Agronomy Partner To Analyze 30 Years of Data on Corn Plant Population Responses

Manhattan, KS (July 20, 2018) - A collaboration between Kansas State University and DuPont Pioneer Agronomy analyzing 30 years of corn plant population responses shows that as agronomic optimum plant density increased, the range for maximizing yields also widened.

DuPont Pioneer has collected data on corn plant population responses and yield gains to provide better information on hybrids. From 1987 to 2015, nearly 200,000 yield and plant population data points were collected from more than 40 locations throughout North America. In collaboration with Pioneer, the data was analyzed by Ignacio A. Ciampitti, an associate professor in crop production and cropping systems at Kansas State University, and his team. Recently, the study was published in Scientific Reports and recognized for its discovery of trends in optimum plant density and yield gains.

Analysis of 30 years of corn plant population responses shows that as agronomic optimum plant density increased, the range for maximizing corn yields also widened. This means modern hybrids benefit from increased plant populations without the previous instability that resulted from higher populations. Study findings show a 53 bushel per acre yield increase.

"It used to be that we were primarily achieving yield gains by improving the plant density tolerance, but there is evidence from this and other recent studies that we are seeing yield per plant increasing," said Paul Carter, DuPont Pioneer agronomy manager.

Key findings

The average agronomic optimum plant density across environments and hybrids increased from 30,500 plants per acre from 1987 to 1991 to 37,900 plants per acre from 2012 to 2016. During the first five years, the range of optimal agronomic plant density was very narrow but this increased over time.

"This indicates that modern hybrids not only need more plants in order to push for higher yields, but also they are showing a stability that the old hybrids did not. For farmers, that means they have some leverage," Ciampitti said. "It's really unique to have this amount of data, from multiple sites, across that many years in order to track plant density and its relationship to corn yields."

Over the duration of the study, average corn yield over all locations at the agronomic optimum plant density increased from 135 bushels per acre in 1987 to 188 bushels per acre in 2015, representing an overall yield gain of 53 bushels per acre. As the agronomic optimum plant density increased, the range for maximizing corn yields also widened. New elite hybrids are credited for these increases in yield per plant.

"This data shows that yield gains might be due to increased planting density, but also that yield per plant might have increased," said Stephen Smith, affiliate professor of agronomy, Iowa State University and retired research fellow at DuPont Pioneer. "If this is the case, then breeders will have found a level and class of genetic response that has mostly remained hidden. Additional studies will be needed to determine if there are additional genetic mechanisms at work contributing to yield. Hopefully, there are breeders who will be able to identify at least some of those and further increase that genetic contribution to yield gains."

Others involved in the study were Yared Assefa, postdoctoral researcher Ciampitti's lab at Kansas State University; and Mark Hinds, Steve Paszkiewicz, Gaurav Bhalla, March Jeschke, and Ryan Schon with DuPont Pioneer.

Read more about the study online.