Straw management effects on global warming potential and yield-scaled greenhouse gas emissions in a subtropical rice ecosystem

IF 1.9 4区农林科学 Q3 SOIL SCIENCE

Revista Brasileira De Ciencia Do Solo Pub Date : 2023-05-01 DOI:10.36783/18069657rbcs20220134

Eduardo Lorensi de Souza, D. A. Weiler, C. Bayer, E. Marchesan, Bruno Chaves, Getúlio Elias Pilecco, R. Schmatz, S. Giacomini

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引用次数: 1

Abstract

: Global warming potential (GWP) of rice paddies depends on straw management. This study evaluated methane (CH 4 ) and nitrous oxide (N 2 O) emissions and soil C stocks to determine GWP and yield-scaled GWP under different strategies and intensities of rice straw management in a subtropical climate. We hypothesized that decreasing soil management intensity and straw incorporation in the soil would reduce GWP. Methane fluxes were substantially higher during the rice growing season than in the off-season, while the opposite was observed for N 2 O fluxes. The cumulative emissions of CH 4 during the growing season among the straw management strategies evaluated ranged from 165.8 to 586.0 kg ha -1 . Annual CH 4 emissions were lower when soil and straw received some type of management compared to no-tillage. Daily N 2 O fluxes ranged from -2.8 to 201.7 g ha -1 day -1 ; cumulative N 2 O emissions during the off-season ranged from 455.2 to 2816.5 g ha -1 . During the off-season, strategies to reduce N 2 O emissions include post-harvest straw incorporation using a disc harrow, winter straw removal, and ryegrass cropping. Soil organic C stocks ranged from 35.96 to 38.36 Mg ha -1 . Straw management using a disc harrow reduced soil organic C stocks, with more adverse effects than straw removal. Soil and rice straw management did not affect rice grain yield, with an average of 10.4 Mg ha -1 . Methane emissions were the main component of GWP in all straw management systems. The contribution of N 2 O emissions to GWP was small and mostly (>85 %) determined by off-season emissions. Yield-scaled GWP ranged from 0.64 to 1.06 Mg CO 2 eq Mg -1 yield and was lower when soil and straw management systems occurred shortly after the rice harvest. Our results indicate that soil and straw management immediately after rice harvest reduces CH 4 emissions, GWP, and yield-scaled GWP.

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秸秆管理对亚热带水稻生态系统全球变暖潜力和产量规模温室气体排放的影响

稻田的全球变暖潜能值(GWP)取决于秸秆管理。本研究评估了亚热带气候下不同秸秆管理策略和强度下的甲烷(ch4)和氧化亚氮(n2o)排放和土壤C储量，以确定全球变暖潜能值和产量比例的全球变暖潜能值。我们假设降低土壤管理强度和秸秆在土壤中的掺入会降低全球升温潜能值。甲烷通量在水稻生长季显著高于淡季，而氮氧通量则相反。各秸秆管理策略的生长季甲烷累积排放量在165.8 ~ 586.0 kg ha -1之间。与免耕相比，土壤和秸秆接受某种类型的管理时，年甲烷排放量较低。日氮氧通量为-2.8 ~ 2017 g / h -1 day -1;淡季累积氮氧化物排放量为455.2 ~ 2816.5 g ha -1。在淡季，减少氮氧化物排放的策略包括收获后使用盘耙秸秆，冬季秸秆清除和黑麦草种植。土壤有机碳储量为35.96 ~ 38.36 Mg ha -1。秸秆管理使用圆盘耙减少土壤有机碳储量，与秸秆去除相比，其不利影响更大。土壤和稻草管理对水稻产量没有影响，平均为10.4 Mg ha -1。在所有秸秆管理系统中，甲烷排放是全球变暖潜能值的主要组成部分。氮氧排放对全球变暖潜能值的贡献很小，大部分(约85%)由淡季排放决定。按产量比例计算的GWP值为0.64 ~ 1.06 Mg CO 2 = Mg -1，在水稻收获后不久实施土壤和秸秆管理时，GWP值较低。我们的研究结果表明，水稻收获后立即进行土壤和秸秆管理可以减少甲烷排放、全球变暖潜能值和产量比例的全球变暖潜能值。

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来源期刊

Revista Brasileira De Ciencia Do Solo 农林科学-土壤科学

CiteScore

3.00

自引率

11.80%

发文量

审稿时长

9-24 weeks

期刊介绍： The Revista Brasileira de Ciência do Solo is a scientific journal published by the Brazilian Society for Soil Science (SBCS), founded in 1947, and is responsible for the propagation of original and inedited technical-scientific work of interest for Soil Science. Contributions must not have been previously published or submit to other periodicals, with the only exception of articles presented in summarized form at professional meetings. Literature reviews are accepted when solicited by the Editorial Board.