生物炭
固碳
土壤碳
矿化(土壤科学)
环境化学
热解
环境科学
碳纤维
碳循环
化学
生物量(生态学)
土壤有机质
斜线和字符
溶解有机碳
环境工程
土壤污染物
土壤科学
负二氧化碳排放
大气碳循环
土壤水分
土壤肥力
污染物
污染
温室气体
生化工程
作者
Wei Han,Yujian Lai,Hongbing Ji
摘要
emissions through its stable aromatic structure and soil interactions, though its efficiency is limited by environmental, physicochemical and technological thresholds. Discrepancies among short-term experimental/model predictions and natural conditions suggest that current research may underestimate carbon oxidation risks by over-reliance on laboratory conditions and neglecting the complexity of natural environments. Negative priming effects arise only under specific conditions. Furthermore, the trade-off between biochar pyrolysis technology and energy recovery poses a significant challenge. This review critically analyzes the key mechanisms through which biochar stabilizes soil organic carbon, in accordance with the bidirectionality of priming effects. Key mechanisms include: (i) physical protection of organic-mineral complexes and soil aggregation; (ii) chemical stability of aromatic polymer condensation and oxidized biochar; and (iii) microbial metabolism and transformations of plant-derived carbon. Future research should clarify the molecular transformation mechanisms of soil carbon from various sources after biochar application, using diverse analytical techniques. Additionally, it should focus on developing biochar application systems tailored to different field conditions and regional soil characteristics. This review provides a theoretical framework for optimizing biochar's carbon sequestration pathways and establishes a scientific foundation for the development of technologies for carbon reduction.
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