The response of greenhouse gas emissions, crop yield, and soil health to water scarcity and biochar application in rice cultivation

Crop and Environment Pub Date : 2025-03-01 DOI:10.1016/j.crope.2024.12.005

Patikorn Sriphirom , Rattapon Onchang , Benjamas Rossopa , Amnat Chidthaisong

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引用次数: 0

Abstract

Projected climate change impacts, such as delayed rainfall and increased drought frequency, threaten rice cultivation and global food security. This study evaluated the effects of water scarcity at critical growth stages and biochar application on greenhouse gas (GHG) emissions, yield, and soil health in Central Thailand using the drought-tolerant cultivar Pathum Thani 1. Treatments included continuous flooding and water scarcity during tillering, reproductive, or both stages, with and without biochar, across wet and dry seasons. Water scarcity significantly reduced methane (CH₄) emissions by inhibiting hydrogenotrophic methanogenesis (Methanocella) and acetoclastic methanogenesis (GOM Arc I of Methanosarcinales) but increased nitrous oxide (N₂O) emissions via enhanced nitrification. Despite higher N₂O emissions, total GHG emissions, expressed as the global warming potential (GWP), were lower under water-scarce conditions than under continuous flooding, with reductions of 27.1%, 43.0%, and 58.1% during tillering, reproductive, and both stages, respectively. Water scarcity during tillering stage maintained yield, whereas water scarcity during reproductive stage caused a significant reduction in yield. Biochar amendment further mitigated GHG emissions, improved yield by 12.2%, and enhanced soil health by increasing soil pH, nutrient availability, and soil organic carbon sequestration. Its high porosity and surface area also suppressed methanogenesis and reduced N₂O formation while improving nutrient use efficiency. The strategic use of water restrictions during tillering, combined with biochar, provides a sustainable approach to mitigate GHG emissions, optimize water use, and sustain soil health and productivity. In resource-limited scenarios, prioritizing tillering-stage water scarcity over biochar application is recommended because of its greater GHG mitigation potential.

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温室气体排放、作物产量和土壤健康对水资源短缺和水稻生物炭施用的响应

预计的气候变化影响，如降雨延迟和干旱频率增加，威胁着水稻种植和全球粮食安全。本研究以泰国中部耐旱品种Pathum Thani 1为研究对象，评估了关键生长阶段缺水和生物炭施用对温室气体（GHG）排放、产量和土壤健康的影响。处理包括分蘖、繁殖或两个阶段的持续洪水和缺水，有或没有生物炭，在湿季和旱季。水资源短缺通过抑制氢营养产甲烷（Methanocella）和醋酸裂解产甲烷（GOM Arc I of Methanosarcinales）显著减少了甲烷（CH4）的排放，但通过强化硝化作用增加了氧化亚氮（N2O）的排放。尽管N2O排放量较高，但水资源短缺条件下的温室气体总排放量（以全球变暖潜势（GWP）表示）低于连续淹水条件，分蘖期、繁殖期和两个阶段的温室气体总排放量分别减少27.1%、43.0%和58.1%。分蘖期缺水维持了产量，而生殖期缺水导致产量显著下降。生物炭改良进一步减少了温室气体排放，提高了12.2%的产量，并通过提高土壤pH值、养分有效性和土壤有机碳固存来改善土壤健康。高孔隙度和高表面积抑制了甲烷的生成，减少了N2O的生成，同时提高了养分的利用效率。分蘖期间战略性地使用限水措施，结合生物炭，为减少温室气体排放、优化用水和维持土壤健康和生产力提供了可持续的方法。在资源有限的情况下，建议优先考虑分蘖阶段的水资源短缺，而不是生物炭的应用，因为它具有更大的温室气体缓解潜力。

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来源期刊

Crop and Environment

CiteScore

3.50

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0.00%

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