135-9 Annual Based Yield-Scaled Global Warming Potential of Rice Production In a Mediterranean Climate.

See more from this Division: S06 Soil & Water Management & Conservation
See more from this Session: Agricultural Practices to Increase Nitrogen-Use Efficiency, Carbon Sequestration, and Greenhouse Gas Mitigation: I
Monday, October 17, 2011: 10:45 AM
Henry Gonzalez Convention Center, Room 218
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Cameron Pittelkow, Arlene A. Adviento-Borbe, Johan Six, James Hill, Chris van Kessel and Bruce Linquist, Dept of Plant Sciences, University of California, Davis, Davis, CA
Management practices that reduce greenhouse gas (GHG) emissions while maintaining yields are an important option for reducing the global warming potential (GWP) of agriculture.  In flooded rice systems, nitrous oxide (N2O) and methane (CH4) are the primary GHGs emitted from soil.  Nitrogen (N) fertilizer is an important factor regulating N2O emissions, thus proper N management is both critical for optimizing yields and reducing environmental impacts.  To identify N management practices that minimize GHG emissions per unit of grain yield produced (i.e. yield-scaled GWP), an on-farm experiment was conducted to quantify N2O and CH4 emissions during the rice growing season and winter fallow periods.  Fertilizer N in the form of aqua ammonia was applied at five N rates ranging from 0 to 260 kg N ha-1.  GHG emissions were determined daily during specific management events (e.g. N application and field drainage periods), and every 7 d otherwise using the closed chamber technique.  Annual GHG emissions and yield-scaled GWP (N2O + CH4) were assessed with respect to N fertilizer rate, agronomic productivity, and N recovery efficiencies.  Results indicate that low N2O emissions occurred regardless of N fertilizer rate when a permanent flood was maintained, with daily emissions remaining under 3.5 g N2O-N ha-1 day-1.  During the growing season and fallow periods, CH4 emissions were similar across N rates and ranged from 0 to approximately 3000 g CH4-C ha-1 day-1, with the highest fluxes occurring midseason and during the drainage period before harvest.  Annual GWP was close to 3,000 kg CO2 eq ha-1 across treatments when N was applied.  As N rate increased yield-scaled GWP decreased from approximately 310 to 220 kg CO2 eq Mg-1, but significant differences were not observed between N rates.  These results suggest that optimal yields can be obtained at relatively constant yield-scaled GWP values when current N management recommendations are followed and N fertilizer inputs are closely matched with crop N demand.
See more from this Division: S06 Soil & Water Management & Conservation
See more from this Session: Agricultural Practices to Increase Nitrogen-Use Efficiency, Carbon Sequestration, and Greenhouse Gas Mitigation: I