Weed Seedbank and Weed Biomass Dynamics in a Long-Term Organic Vegetable Cropping Systems Experiment

Most previous research on changes in weed abundance and community composition in cropping systems has focused on field crops. The study presented here examined changes in the weed seedbank and aboveground biomass in four organic vegetable cropping systems over a 10-yr period. The systems included an...

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Veröffentlicht in:Weed science 2018-09, Vol.66 (5), p.611-626
Hauptverfasser: Mohler, Charles L, Caldwell, Brian A, Marschner, Caroline A, Cordeau, Stephane, Maqsood, Qaiser, Ryan, Matthew R, DiTommaso, Antonio
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container_end_page 626
container_issue 5
container_start_page 611
container_title Weed science
container_volume 66
creator Mohler, Charles L
Caldwell, Brian A
Marschner, Caroline A
Cordeau, Stephane
Maqsood, Qaiser
Ryan, Matthew R
DiTommaso, Antonio
description Most previous research on changes in weed abundance and community composition in cropping systems has focused on field crops. The study presented here examined changes in the weed seedbank and aboveground biomass in four organic vegetable cropping systems over a 10-yr period. The systems included an Intensive system with six crops per 4-yr rotation, an Intermediate system with one cash crop per year, a Bio-extensive system with alternating cash crop and tilled fallow years plus prevention of seed rain, and a Ridge-tillage system with one cash crop per year. Systems also differed in the types and number of cover crops between cash crops. During the course of the experiment, the weed community shifted from one dominated by summer annual broadleaf species that reproduce at the end of their lives to a community dominated by summer and winter annuals that mature rapidly. This shift in community composition can be attributed to the change in land use from conventionally managed corn (Zea mays L.) and alfalfa (Medicago sativa L.) to organic vegetable production. In particular, crop rotations with diverse preplantings and postharvest tillage dates interrupted the life cycle of common lambsquarters (Chenopodium album L.) and pigweed species (Amaranthus spp.: mostly Powell amaranth [Amaranthus powellii S. Watson], with small numbers of redroot pigweed [Amaranthus retroflexus L.] and smooth pigweed [Amaranthus hybridus L.]), while favoring a diverse assemblage of quickly maturing species. The study thus demonstrates that an appropriate crop rotation can control the seedbank of weeds like C. album that potentially persist well in the soil. The Ridge-tillage system greatly reduced the frequency and depth of tillage relative to other systems while effectively suppressing perennial weeds. The early-reproducing annuals, however, became more abundant in the Ridge-tillage system than in the other systems, primarily due to escapes along the edge of the scraped ridges. The tilled fallow periods coupled with prevention of seed rain in the Bio-extensive system substantially reduced weed abundance through time and relative to the other systems.
doi_str_mv 10.1017/wsc.2018.52
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source JSTOR Archive Collection A-Z Listing; Cambridge University Press Journals Complete
subjects Abundance
Agricultural practices
Agriculture
Alfalfa
Amaranth
Amaranthus retroflexus
Biomass
Cash crops
Chenopodium album
Communities
Community composition
Composition
Corn
Cover crops
Crop production
Crop rotation
Cropping systems
Crops
Energy crops
Environmental Sciences
Experiments
Farmers
Farms
Land use
Land use management
Life cycle engineering
Life cycles
Life Sciences
Organic farming
Prevention
Productivity
Rain
Seed banks
seed persistence
Seeds
Soil erosion
Sorghum
Species
Summer
System effectiveness
Tillage
timing of tillage
Vegetables
Vegetal Biology
WEED BIOLOGY AND ECOLOGY
weed community
Weed Management
Weeds
title Weed Seedbank and Weed Biomass Dynamics in a Long-Term Organic Vegetable Cropping Systems Experiment
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