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United States Department of Agriculture

Agricultural Research Service

Research Project: Integrated Strategies for Advanced Management of Fruit, Nut, and Oak Tree Diseases

Location: Crops Pathology and Genetics Research

Title: Chapter 10 – Management to Reduce Greenhouse Gas Emissions in Western U.S. Croplands

Authors
item Halvorson, Ardell
item Steenwerth, Kerri
item Suddick, Emma -
item Liebig, Mark
item Bronson, Kevin
item Collins, Harold

Submitted to: Elsevier
Publication Type: Book / Chapter
Publication Acceptance Date: March 1, 2012
Publication Date: May 21, 2012
Repository URL: http://www.sciencedirect.com/science/article/pii/B9780123868978000103
Citation: Halvorson, A.D., Steenwerth, K.L., Suddick, E.C., Liebig, M.A., Bronson, K.F., Collins, H.P. 2012. Chapter 10 – Management to Reduce Greenhouse Gas Emissions in Western U.S. Croplands. Elsevier. 167-182.

Technical Abstract: Agriculture is a major activity in the western U.S. with approximately 57 million ha of harvested cropland of which 27% is irrigated; however, irrigated crops account for a high proportion of the economic returns because of their high economic value. We sought to summarize greenhouse gas (GHG) flux research from crop production systems in the western U.S. published from 2005 to 2011. Limited GHG emissions data were found from irrigated cropping systems in California (grain, rice, vegetable, orchards), Texas (cotton), Colorado (corn), and Washington (corn and potato), and from dryland wheat systems in Montana and North Dakota. Converting from conventional tillage (CT) to minimum-till (MT) or no-till (NT) production generally sequestered soil organic carbon (SOC) and reduced carbon dioxide (CO2) emissions in many cropping systems, but not all. Methane (CH4) flux was not greatly influenced by crop management practices, except in rice and manure production systems. Nitrous oxide (N2O) emissions were affected by N availability, climatic factors, irrigation, and crop management practices, and tended to be lower under dryland than irrigated cropping conditions. Reducing N fertilization rate and selecting the right N source can reduce N2O emissions as much as 50%. Use of microjet sprinkler or subsurface drip irrigation reduced N2O emissions in vineyards and orchards as much as 50% compared to surface drip systems. Available GHG data could be used to verify models and develop local mitigation practices, but due to the large diversity of cropping systems and ecoregions, and a lack of representative cropping system GHG databases, generalized mitigation recommendations for the western U.S. are not possible at this time.

Last Modified: 12/18/2014
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