Weeds don’t stand a chance…if you time it right. New research is finally providing much-needed data to upper Midwest farmers on using cereal rye as a cover crop in their production systems. The findings show that it’s all about the timing – of both cover crop termination and cash crop planting.
In his 2024 doctoral dissertation, Dr. Eric Yu aimed to provide Minnesota farmers with data helping to substantiate current cereal rye recommendations. He found that while cereal rye successfully suppressed weeds in both corn and soybean rotations, soybeans appeared more tolerant to cereal rye (allowing for a later termination timing), and corn yields decreased with delayed termination timing. Several factors may contribute to the decreased corn yields, including nitrogen uptake by the cereal rye, which is a critical nutrient for corn production. However, nitrogen dynamics were not studied in this research.
Yu found that higher cereal rye seeding rates didn’t impact cover crop biomass, weed suppression, or cash crop yield. This suggests that Minnesota farmers can successfully seed cereal rye at 60 pounds per acre without negative effects. “The results show no significant difference between cereal rye seeding rates observed in our study.” Yu explains. Finally, Yu dug into how cover crop residue can reduce the amount of preemergence herbicides reaching the soil – and how farmers can address this.
Yu’s research, conducted from 2021 and 2023 at sites in southwestern and southeastern Minnesota, examined various cereal rye seeding rates (60, 90, and 120 pounds per acre), and termination timings (one week before cash crop planting, at planting, and one week after planting). Cereal rye was terminated with glyphosate, with an additional termination treatment involving the application of a preemergence herbicide tank-mixed with glyphosate at the time of cash crop planting. The study also included two cash crop planting dates (mid-May and early-June), with the later planting meant to allow for greater cereal rye biomass accumulation.
Corn-Soybean Rotation
Research in the corn-soybean rotation plots found that while the cover crop seeding rate had no significant impact on weed suppression, cover crop biomass, or soybean yield, both cereal rye termination timing and soybean planting date did.
When considering weed suppression and soybean yields, the optimal planting date was mid-May with cereal rye termination at planting (with or without preemergence herbicides) or seven days after planting. Under these conditions, weed suppression ranged from 85% to 91%.
In the southwest, early-planted soybeans had yields ranging from 55.5 to 58.2 bushels per acre. In the southeast, early-planted soybeans had yields of 69.26 to 71.1 bushels per acre. Late-planted soybean yields were reduced by 24% at both locations when compared to early-planted soybean yields.
Continuous Corn System
Research in continuous corn system plots demonstrated that the cover crop seeding rate did not impact weed control, but yield was impacted by the combination of corn seeding rate, corn planting date, and rye termination timing.
In this production system, Yu observed similar results to those in the corn-soybean rotation, but with a tradeoff: late-planted corn provided the best weed control (over 91%), but resulted in lower overall yields. Early-planted corn had greater yields, but overall lower weed suppression (77%).
Despite a three-way effect on corn yield, no differences were observed in cereal rye seeding rates. The greatest corn yield occurred with early-planted corn, where cereal rye was terminated at planting (with or without preemergence herbicides).
Early-planted corn yields ranged from 53.7 to 162.2 bushels per acre at the southwest site, and 76.15 to 165.5 bushels per acre at the southeast site. When compared to early-planted corn yields, late-planted corn yields were reduced by 16% at the southwest site, and 38% at the southeast site.
Herbicide Spray Coverage
Yu also used water-sensitive spray cards to learn how much herbicide reaches the soil when it’s sprayed over cereal rye. “I thought farmers might be concerned about how cover crops could affect the application of preemergence herbicides,” Yu states. “For these herbicides to be effective, they really need to reach the soil.”
Yu found that in late-planted fields, which produce more cover crop biomass, a greater amount of herbicide was unable to reach the soil. In late-planted fields, herbicide coverage ranged from 4% to 15%, compared to about 30% in early-planted fields.
To mitigate herbicide loss, Yu suggests that farmers increase herbicide carrier volume, ultimately increasing ground coverage while maintaining weed control and cutting herbicide loss. “Increase your carrier volume,” Yu advises. “While this may lower herbicide concentration, achieving adequate ground coverage is more important in this case.”
Given the lack of data substantiating cereal rye recommendations in Minnesota, Yu’s findings help provide Minnesota farmers with information on how best to incorporate cereal rye to suppress weeds, while preserving cash crop yields. For farmers looking to begin incorporating cover crops for the first time, Yu recommends starting with a small plot of land, testing the approach outlined in his dissertation, and making adjustments as needed.
Visit GROW’s website for more information about cover crop management and termination.
Article by Amy Sullivan, GROW and Eric Yu, University of Minnesota; header and feature photo by Eric Yu, University of Minnesota.
