AI Article Synopsis
- Crop residue return in paddy fields significantly increases greenhouse gas (GHG) emissions, with methane (CH) emissions rising by 73% and nitrous oxide (NO) emissions by 14% on average.
- Key factors such as soil pH, organic matter, and nitrogen levels are crucial in influencing these emissions, with pH being the most significant.
- Tailored strategies, like combining straw return with specific nitrogen levels or irrigation practices based on soil type, can effectively mitigate GHG emissions, highlighting the importance of site-specific management practices.
Article Abstract
The stimulating impact of crop residue return on greenhouse gas (GHG) emissions from paddy fields have been widely accepted, while the influence of site environmental and human factors on the simulating degree remains unclear. Here, we performed a meta-analysis to assess the GHG emissions affected by residue return, and its mitigation potential combined with key factors in paddy fields. Drawing upon 1047 observation sets of CH and NO emissions from 155 peer-reviewed publications we found that residue return to paddy fields caused an average increase of 73% CH emissions and 14% in NO emissions. Utilizing meta-analytical models, we identified pH as the most significant driver modulating GHG emissions, followed by soil organic matter (SOC) and total nitrogen. In alkaline soils, combining straw return with intermittent irrigation (285.2%) or mid-season drainage (118.9%) significantly reduced CH emissions compared to continuous flooding (1201.9%). Additionally, pairing straw return with higher nitrogen inputs (above 150 kg N ha) improved soil NO uptake by -11.5%. In acid and neutral soils, straw carbonization achieved soil CH negative emissions (from -2.9% to -39.3%), but the long-term effects remained unclear. Reduced drainage frequency mitigates NO emissions but may increase CH emissions. To efficiently mitigate GHG emissions, we proposed low-carbon schemes for acid or neutral soils based on specific SOC content: For soils with SOC content <10 g kg, prioritize nitrogen input control with rates not exceeding 174 kg N ha. For soils with SOC content >10 g kg, prioritize adjusting the type of straw. Our study underscores the significance of site-specific factors in modulating GHG emissions. Efficient GHG mitigation can be achieved by combining residue return with other agronomic measures tailored to different soil conditions.
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| http://dx.doi.org/10.1016/j.jenvman.2024.122519 | DOI Listing |
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