Grain Legumes in Northern Great Plains: Impacts on Selected Biological Soil Processes

Cropping systems in the Northern Great Plains have shifted from fallow-based to legume-based systems. The introduction of grain legumes has impacted soil organisms, including both symbiotic and nonsymbiotic N-fixing bacteria, pathogens, mycorrhizae and fauna, and the processes they perform. These ch...

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Bibliographic Details
Published in:Agronomy journal 2007-11, Vol.99 (6), p.1700-1709
Main Authors: Lupwayi, N.Z, Kennedy, A.C
Format: Article
Language:English
Subjects:
biodegradation
Cicer arietinum
crop residues
cropping systems
crops
disease course
disease incidence
fallow
legumes
Lens culinaris
literature reviews
mycorrhizal fungi
nitrogen-fixing bacteria
nutrient availability
Phaseolus vulgaris
Pisum sativum
rhizosphere
root exudates
seeds
soil bacteria
soil biological properties
soil biology
soil fauna
soil-borne diseases
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Summary:Cropping systems in the Northern Great Plains have shifted from fallow-based to legume-based systems. The introduction of grain legumes has impacted soil organisms, including both symbiotic and nonsymbiotic N-fixing bacteria, pathogens, mycorrhizae and fauna, and the processes they perform. These changes occur through effects of legume seed exudates, rhizosphere exudates, and decomposing crop residues. The legume-Rhizobium symbiosis results in dinitrogen (N2) fixation that adds plant available N into the soil system. It is estimated that about 171 million kg N2 was fixed by field pea (Pisum sativum L.), lentil (Lens culinaris Medik.), dry bean (Phaseolus vulgaris L.), and chickpea (Cicer arietinum L.) crops in the Canadian Prairies in 2004, representing 7% of the total fertilizer-N (2580 million kg) used by Canadian prairie farmers in that year. Similarly, an estimated 40 million kg N2 was fixed by field pea, lentil, and dry bean (including chickpea) crops in U.S. agroecosystems in 2004. Some of the fixed N2 is recycled for the benefit of nonlegume crops grown after grain legumes. Many other associations benefit from the legume in a cropping system, including mycorrhizal associations that improve plant nutrient and water uptake, changes in the pathogen load and disease development, and overall changes in the soil community. Legumes contribute to greenhouse gas (N2O and CO2) emissions during nitrification and denitrification of fixed N. However, because less fertilizer-N is used in legume-based cropping systems, overall greenhouse gas emissions are usually less than those in fertilized monoculture cereals. Therefore, grain legumes in Northern Great Plains have positive effects on agriculture by adding and recycling biologically fixed N2, enhancing nutrient uptake, reducing greenhouse gas emissions by reducing N fertilizer use, and breaking nonlegume crop pest cycles.
ISSN:0002-1962
1435-0645
DOI:10.2134/agronj2006.0313s