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Managing the nitrogen cycle to reduce greenhouse gas emissions from crop production and biofuel expansion
Authors:Stephen M. Ogle  Bruce A. McCarl  Justin Baker  Stephen J. Del Grosso  Paul R. Adler  Keith Paustian  William J. Parton
Affiliation:1.Natural Resource Ecology Laboratory,Colorado State University,Fort Collins,USA;2.Department of Ecosystem Science and Sustainability,Colorado State University,Fort Collins,USA;3.Department of Agricultural Economics,Texas A&M University,College Station,USA;4.Agricultural, Resource & Energy Economics and Policy Program,RTI International,Research Triangle Park,USA;5.Soil Plant Nutrient Research, Agriculture Research Service,US Department of Agriculture,Fort Collins,USA;6.Pasture Systems and Watershed Management Research Unit, Agriculture Research Service,US Department of Agriculture,University Park,USA;7.Department of Soil and Crop Sciences,Colorado State University,Fort Collins,USA
Abstract:Public policies are promoting biofuels as an alternative to fossil fuel consumption in order to mitigate greenhouse gas (GHG) emissions. However, the mitigation benefit can be at least partially compromised by emissions occurring during feedstock production. One of the key sources of GHG emissions from biofuel feedstock production, as well as conventional crops, is soil nitrous oxide (N2O), which is largely driven by nitrogen (N) management. Our objective was to determine how much GHG emissions could be reduced by encouraging alternative N management practices through application of nitrification inhibitors and a cap on N fertilization. We used the US Renewable Fuel Standards (RFS2) as the basis for a case study to evaluate technical and economic drivers influencing the N management mitigation strategies. We estimated soil N2O emissions using the DayCent ecosystem model and applied the US Forest and Agricultural Sector Optimization Model with Greenhouse Gases (FASOMGHG) to project GHG emissions for the agricultural sector, as influenced by biofuel scenarios and N management options. Relative to the current RSF2 policy with no N management interventions, results show decreases in N2O emissions ranging from 3 to 4 % for the agricultural sector (5.5–6.5 million metric tonnes CO2?eq.?year?1; 1 million metric tonnes is equivalent to a Teragram) in response to a cap that reduces N fertilizer application and even larger reductions with application of nitrification inhibitors, ranging from 9 to 10 % (15.5–16.6 million tonnes CO2?eq.?year?1). The results demonstrate that climate and energy policies promoting biofuel production could consider options to manage the N cycle with alternative fertilization practices for the agricultural sector and likely enhance the mitigation of GHG emissions associated with biofuels.
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