URBANA, Ill. — From flooded spring fields to summer hailstorms and drought, farmers are well aware the weather is changing. It often means spring planting can’t happen on time or has to happen twice to make up for catastrophic losses of young seedlings.
According to a joint study between University of Illinois and USDA-ARS, it also means common pre-emergence herbicides are less effective. With less weed control at the beginning of the season, farmers are forced to rely more heavily on post-emergence herbicides or risk yield loss.
“We’re having more variable precipitation, including conditions where folks aren’t able to plant because fields are too wet. In those cases, pre-emergence herbicide applications are getting pushed back into a period that is consistently drier,” Marty Williams, USDA-ARS ecologist, affiliate professor at Illinois, and corresponding author on the study, says in a news release.
Drier weather may be better for getting equipment onto the field for planting, but it’s a problem for pre-emergence herbicides. Using data spanning 25 years and 252 unique weather environments, Williams and his team found most pre-emergence herbicides needed 5 to 15 centimeters of rain within 15 days of application. If that didn’t happen, weed control rates plummeted.
“We already knew some rain after application was critical for the herbicide to move into the soil, but we didn’t know how much or when,” Williams says. “As we look to the future, having more variable rainfall and potentially increasing the frequency of falling below a critical rainfall threshold is problematic.”
Christopher Landau, a doctoral candidate on the project, leveraged the university’s long-running herbicide evaluation program, for which digital data are available across multiple Illinois locations from 1992 forward. He evaluated the effects of four common pre-emergence herbicides (atrazine, acetochlor, S-metolachlor, and mesotrione) alone and in combination, on three economically important weed species: common lambsquarters, giant foxtail and waterhemp. He also extracted rainfall and soil temperature data.
The analyses clearly showed the overall need for rain after application, but the pre-emergence herbicides varied in their requirements for rainfall within that 15-day post-application window. For example, S-metolachlor required 10 to 15 centimeters of rainfall to maximize waterhemp control, whereas acetochlor only needed 5 centimeters to control the same weed.
Results also indicated herbicide combinations helped to minimize the amount of rainfall required for successful control. When atrazine was added to S-metolachlor, the combination needed only 5 centimeters to achieve the same level of control.
“Herbicide combinations often provide additional benefits to weed control programs, including more consistent weed control. The continual evolution of herbicide resistance in species such as waterhemp requires more integrated control measures, and herbicide combinations can be one component of integrated systems designed to minimize weed seed production,” says Aaron Hager, study co-author and associate professor and faculty Extension specialist in crop sciences at Illinois.
The researchers note their findings may be especially important in the western Corn Belt, where erratic weather and low rainfall probabilities are even more common than in Illinois. But they still recommend the use of pre-emergence herbicides in combination, and urge farmers to be strategic in timing their application when rain is in the forecast.