生物炭能减轻降雨引起的土壤侵蚀吗?综述与荟萃分析

Yu Lu , Kai Gu , Bin Shi , Qiyou Zhou
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摘要

生物炭已成为一种很有前景的土壤改良剂,可改善土壤结构。然而,生物炭对降雨引起的土壤侵蚀的影响在不同的研究中存在差异。为了弥补这一不足,我们对 45 项已发表研究中的 174 项配对比较进行了统计荟萃分析,通过生物炭和土壤特性以及实验条件综合评估了生物炭对降雨引起的土壤侵蚀的影响。总体而言,生物炭明显减少了 27.86% 的土壤侵蚀。生物炭引起的土壤侵蚀的响应比(lnRR)在不同分组中表现出显著的差异性。在生物炭特性方面,与木质生物炭和农作物废料生物炭相比,其他来源的生物炭(如粪便和污水污泥生物炭)以及在较低热解温度(< 500 °C)下生产的生物炭具有更有利的影响。增加生物炭用量的效果并不一致。最佳范围为 0.8%-2%,结果土壤侵蚀减少了 36.07%。在土壤特性方面,土壤中砂/粘土的比例越高,生物炭的效果越明显(p <0.0001)。具体而言,细粒度土壤的影响不明显,而粗粒度土壤的影响最大,减少了 52.97%。此外,与短期实验室研究(29.62% 和 12.59%)相比,长期田间试验诱导生物炭更大程度地减少了土壤侵蚀(35.30%)。这项荟萃分析表明,生物炭作为一种潜在的土壤改良剂,可通过综合考虑土壤特性和生物炭的具体特性,有效减轻降雨引起的土壤侵蚀。
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Does biochar mitigate rainfall-induced soil erosion? A review and meta-analysis

Biochar has emerged as a promising soil amendment for improving soil structure. Yet, its impact on rainfall-induced soil erosion varies across individual studies. To address this gap, we conducted a statistical meta-analysis of 174 paired comparisons from 45 published studies to integratedly evaluate the impacts of biochar on rainfall-induced soil erosion through biochar and soil properties, as well as experimental conditions. Overall, biochar significantly reduced soil erosion by 27.86%. The response ratio (lnRR) of biochar-induced soil erosion exhibited significant variability across different subgroups. Concerning biochar properties, a more favorable influence was observed in other sources biochar (e.g., manure and sewage sludge biochar) compared to wood based and crop waste biochar, and those produced at lower pyrolysis temperatures (< 500 °C). Increasing biochar dosage was not consistently effective. The optimal range was 0.8%–2%, resulting in a 36.07% reduction in soil erosion. Regarding the soil properties, a higher sand/clay ratio of soil significantly enhanced the performance of biochar (p < 0.0001). Specifically, an insignificant effect was observed in fine-grained soils, whereas the highest reduction of 52.97% was noted in coarse-grained soils. Moreover, long-term field experiments induced greater reductions in soil erosion with biochar (35.30%) compared to short-term laboratory studies (29.62% and 12.59%). This meta-analysis demonstrates that biochar, as a potential soil amendment, could effectively mitigate rainfall-induced soil erosion by considering a combination of soil properties along with specific biochar properties.

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