生物炭
固碳
土壤碳
碳纤维
减缓气候变化
碳循环
环境化学
环境科学
化学
桥接(联网)
气候变化
生化工程
大气碳循环
地球系统科学
全球变暖
全球气候
矿化(土壤科学)
总有机碳
环境工程
地球科学
环境保护
负二氧化碳排放
温室气体
无机碳总量
土壤有机质
溶解有机碳
作者
Shengman Zhang,Chen Cai,Gao B,Yuhang Wang,Yiyang Zhang,Siyu Ren,Jia Liu,Kaiming Peng,Xiangfeng Huang
标识
DOI:10.1021/acs.est.6c00178
摘要
Enhancing soil carbon sequestration is a pivotal strategy for mitigating global climate change. Integrating the "microbial carbon pump (MCP)" and "mineral carbon pump (MnCP)" frameworks is essential for a holistic understanding of soil organic carbon (SOC) stabilization. While biochar (BC) is a recognized carbon sequestration tool, the mechanistic pathways by which it mediates the synergy between these distinct carbon pumps remain elusive. This review synthesizes current advances to position BC as a critical "bridge" driving the coupled MCP-MnCP system. Beyond serving as recalcitrant carbon, BC strengthens the MCP by providing microbial habitats, optimizing community structure, and enhancing carbon use efficiency to promote necromass accumulation. Simultaneously, BC fortifies the MnCP via mechanisms including the formation of stable organo-mineral complexes through surface functional groups, the facilitation of microaggregate genesis, and the mediation of redox reactions. This bridging efficacy offers a novel theoretical framework for developing predictable, controllable soil carbon technologies. Furthermore, we explore the theoretical basis for integrating BC into the coupled MCP-MnCP system. Future research must prioritize cross-scale mechanistic dissection, advance the precision design of BC functionality, and incorporate its "dual carbon pump" enhancement effects into life cycle assessment frameworks to fully realize its potential in climate mitigation and sustainable agriculture.
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