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Projekt Druckansicht

Treibhausgas-Emission aus verschiedenen Fruchtfolgen von Reis (geflutet und nicht geflutet) und Mais

Fachliche Zuordnung Bodenwissenschaften
Förderung Förderung von 2011 bis 2014
Projektkennung Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 194371065
 
Erstellungsjahr 2019

Zusammenfassung der Projektergebnisse

For a comprehensive assessment of greenhouse gas (GHG) balances, we measured methane (CH4) nitrous oxide (N2O) emissions and agronomic parameters over 6 years in double-rice cropping (R-R) and paddy rice rotations diversified with either maize (R-M) or aerobic rice (R-A) in upland cultivation: Introduction of upland crops in the dry season reduced irrigation water use and CH4 emissions by 66–81% and 95–99%, respectively. Moreover, for practices including upland crops, CH4 emissions in the subsequent wet season with paddy rice were reduced by 54–60%. Although annual N2O emissions increased two- to threefold in diversified rice systems, the strong reduction in CH4 emission led to a significantly lower (P < 0.05) annual Global Warming Potential (GWP) as compared to the traditional double-rice cropping system. Adequate irrigation schemes have a high potential to reduce N2O emissions during upland cropping. We investigated if straw residue incorporation and/or catch crop cultivation impairs the greenhouse gas footprint of diversifying rice cropping systems and thus offers an alternative to open-field straw burning: Due to strong reduction in CH4 emissions lowest GWP for rice-maize (R-M) cropping systems, followed by R-A and R-R systems persists also with the incorporation of crop residues (straw and straw + mung bean), a requirement for farmers as the ban of open-field burning is increasingly enforced. Application of organic amendments increased substrate availability for methanogens and associated CH4 emissions during the following wet rice season. Thus, GWP was 9-39% higher in treatments including straw incorporation as compared to control treatments without organic substrate amendments. Surface application rather than incorporation and straw application during DS in diversified paddy rice upland crop rotations (R-M, R-A) lead to lowest increases in soil CH4 emissions. Additional incorporation of mung beans (straw + mung beans) further increased GWP, with highest increment in R-R (88%) and lowest in R-M rotation (55%). Compared to the traditional R-R system the R-M system with moderate organic residue applications allows for reducing irrigation water and GWP, which is important considering the expansion of diversified rice cropping systems in SE Asia. Our study shows that land-preparation and fallow periods substantially contribute to seasonal CH4 and N2O emissions and need to be considered when assessing / comparing GWPs of rice systems. Our work calls for a refinement of IPCC emission factors for lowland-upland rice rotations, application of organic amendments and the inclusion of the land-preparation periods within the GHG balance of rice cropping systems. Overall, methane (CH4) emissions from rice paddies often show significant diurnal variations, most likely driven by diurnal changes of radiation and temperature in air, floodwater, and soil: Disregarding the diurnal variability of fluxes results in an average overestimation of seasonal CH4 emissions of 22% (16–31%) if measurements were conducted only around noon, likely to happen with manual chamber sampling schemes. Scheduling manual sampling either at early morning (7:00–9:00) or evening (17:00–19:00) results in estimations of seasonal emissions within 94–101% of the ‘‘true’’ value as calculated from multiple daily flux measurements, an important information currently integrated into CH4 emission measurement protocols. In this context, we also provide correction factors, to convert flux rates to daily representative values at any sampling time of the day.

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