Seedbank Depletion and Emergence Patterns of Giant Ragweed (Ambrosia trifida) in Minnesota Cropping Systems

In the midwestern United States, biotypes of giant ragweed resistant to multiple herbicide biochemical sites of action have been identified. Weeds with resistance to multiple herbicides reduce the utility of existing herbicides and necessitate the development of alternative weed control strategies....

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Published in:Weed science 2017-01, Vol.65 (1), p.52-60
Main Authors: Goplen, Jared J., Sheaffer, Craig C., Becker, Roger L., Coulter, Jeffrey A., Breitenbach, Fritz R., Behnken, Lisa M., Johnson, Gregg A., Gunsolus, Jeffrey L.
Format: Article
Language:English
Subjects:
Agricultural practices
Alfalfa
Biotypes
Cereal crops
Competitive advantage
Corn
Crop rotation
Cropping systems
Crops
herbicide resistance
Herbicides
Predation
Seasons
Seed banks
Seedlings
Seeds
Soybeans
Vegetables
WEED BIOLOGY AND ECOLOGY
Weed control
weed emergence
weed seedbank depletion
Weeds
Wheat
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cited_by cdi_FETCH-LOGICAL-b412t-8fa87ee3c842cf2323e816f5f9544608aa7bad746db4a235d9feec114029142e3
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creator Goplen, Jared J.
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description In the midwestern United States, biotypes of giant ragweed resistant to multiple herbicide biochemical sites of action have been identified. Weeds with resistance to multiple herbicides reduce the utility of existing herbicides and necessitate the development of alternative weed control strategies. In two experiments in southeastern Minnesota, we determined the effect of six 3 yr crop-rotation systems containing corn, soybean, wheat, and alfalfa on giant ragweed seedbank depletion and emergence patterns. The six crop-rotation systems included continuous corn, soybean–corn–corn, corn–soybean–corn, soybean–wheat–corn, soybean–alfalfa–corn, and alfalfa–alfalfa–corn. The crop-rotation system had no effect on the amount of seedbank depletion when a zero-weed threshold was maintained, with an average of 96% of the giant ragweed seedbank being depleted within 2 yr. Seedbank depletion occurred primarily through seedling emergence in all crop-rotation systems. However, seedling emergence tended to account for more of the seedbank depletion in rotations containing only corn or soybean compared with rotations with wheat or alfalfa. Giant ragweed emerged early across all treatments, with on average 90% emergence occurring by June 4. Duration of emergence was slightly longer in established alfalfa compared with other cropping systems. These results indicate that corn and soybean rotations are more conducive to giant ragweed emergence than rotations including wheat and alfalfa, and that adopting a zero-weed threshold is a viable approach to depleting the weed seedbank in all crop-rotation systems.
doi_str_mv 10.1614/WS-D-16-00084.1
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source Cambridge University Press; JSTOR
subjects Agricultural practices
Alfalfa
Biotypes
Cereal crops
Competitive advantage
Corn
Crop rotation
Cropping systems
Crops
herbicide resistance
Herbicides
Predation
Seasons
Seed banks
Seedlings
Seeds
Soybeans
Vegetables
WEED BIOLOGY AND ECOLOGY
Weed control
weed emergence
weed seedbank depletion
Weeds
Wheat
title Seedbank Depletion and Emergence Patterns of Giant Ragweed (Ambrosia trifida) in Minnesota Cropping Systems
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