王高起, 袁丹, 吴萍, 秦树平, 胡春胜. 深层土壤有机碳储量、稳定性以及对人类活动响应的研究进展[J]. 中国生态农业学报 (中英文), 2025, 33(2): 1−15. DOI: 10.12357/cjea.20240125
引用本文: 王高起, 袁丹, 吴萍, 秦树平, 胡春胜. 深层土壤有机碳储量、稳定性以及对人类活动响应的研究进展[J]. 中国生态农业学报 (中英文), 2025, 33(2): 1−15. DOI: 10.12357/cjea.20240125
WANG G Q, YUAN D, WU P, QIN S P, HU C S. Deep soil organic carbon storage, stability and their responses to human activities[J]. Chinese Journal of Eco-Agriculture, 2025, 33(2): 1−15. DOI: 10.12357/cjea.20240125
Citation: WANG G Q, YUAN D, WU P, QIN S P, HU C S. Deep soil organic carbon storage, stability and their responses to human activities[J]. Chinese Journal of Eco-Agriculture, 2025, 33(2): 1−15. DOI: 10.12357/cjea.20240125

深层土壤有机碳储量、稳定性以及对人类活动响应的研究进展

Deep soil organic carbon storage, stability and their responses to human activities

  • 摘要: 土壤是陆地生态系统最大的有机碳库, 对全球气候变化有着重要的调节作用。目前, 大部分有关土壤有机碳储量与周转方面的研究只关注0-1 m深度的土层, 对1米以下深层土壤有机碳储量、稳定性及其对人类活动的响应还缺乏系统总结。本文系统总结了深层有机碳碳储量、来源、组成、稳定性及其对人类活动的响应规律方面的最新研究进展。发现在全球范围内, 深层土壤有机碳储量介于29.9~219.6 t hm−2, 占土壤有机碳储量百分比介于15%~84%之间。深层土壤有机碳的年龄介于4800~28 100年之间, 周转时间介于1000~4285年之间。深层土壤有机碳的稳定性显著高于表层土壤, 主要原因是深层土壤比表层土壤具有更高的厌氧环境, 另外深层土壤有机碳大部分被矿物保护且其化学组成更趋惰性。影响深层土壤有机碳稳定性的关键因素包括; 氮肥过量施用、种植制度转变、地下水位波动。虽然深层土壤有机碳的矿化速率显著低于表层土壤, 但人类活动导致的硝酸盐淋失、种植制度转变以及地下水位波动已在一些区域显著降低了深层有机碳的稳定性, 对全球气候变化可能造成深远影响。未来亟需1)评估区域/全球深层土壤碳库储量及其稳定性; 2)阐明深层土壤有机碳库储量及其稳定性对人类活动的响应机制; 3)量化人类活动导致的深层土壤有机碳释放对全球变暖的贡献。

     

    Abstract: Soil, as one of the largest carbon reservoirs in the ecosystem, holds a substantial storage capacity and significantly impacts global climate change. Currently, most research on soil organic carbon storage and turnover focuses on the surface soil organic carbon (0−1 m) (SSOM), while systematic studies on the storage, stability, and response to human activities of deep soil organic carbon (DSOM) below 1 m are relatively limited. This article offers a comprehensive review of the latest research advancements on the storage, sources, composition, stability, and human activity responses of DSOM. Globally, the storage of deep soil organic carbon ranges from 29.9 to 219.6 t·hm−2, accounting for 15%−84% of the total soil organic carbon storage. The average age of DSOM lies between 4800 and 28 100 a, with a turnover time spanning from 1000 to 4285 a. The stability of DSOM is significantly higher than that of SSOM, mainly due to the anaerobic environment, mineral protection, and chemical inertness of DSOM. Key factors affecting the stability of DSOM include excessive fertilization, intensified agricultural practices, and fluctuations in groundwater levels. Although the mineralization rate of DSOM is significantly lower than that of SSOM, human activities such as nitrate leaching due to excessive nitrogen fertilizer application, changes in cropping systems, and groundwater level fluctuations have significantly reduced the stability of DSOM in some regions, potentially having a profound impact on global climate change. The substantial storage potential of DSOM for carbon sequestration is compromised by these activities, which may lead to the release of stored carbon back into the atmosphere, thereby exacerbating global warming, Studies indicate that the substantial storage of DSOM has significant potential for carbon sequestration, and human activities may have compromised its stability, potentially leading to profound effects on global climate change. Therefore, it is crucial to investigate DSOM. However, the underlying mechanisms and processes have not been fully explored and require further in-depth research. The future urgently needs to: 1) assess the storage and stability of regional/global deep soil carbon pools; 2) clarify the mechanisms by which deep soil organic carbon pools respond to human activities; 3) quantify the contribution of human activity-induced deep soil organic carbon release to global warming. These research directions are essential to fully understand and leverage the role of DSOM in climate change mitigation and to ensure the sustainability of our planet for future generations. In summation, the study of DSOM is at the vanguard of soil science and global change research, necessitating a multidisciplinary convergence of pedology, geochemistry, microbiology, and environmental science. Advancing our grasp of DSOM is key to harnessing its capacity as a natural climate change mitigation tool and securing the planet’s sustainability for future generations.

     

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