Soil microbial carbon pump conceptual framework 2.0

doi:10.13287/j.1001-9332.202401.018

Abstract

Abstract: Microorganisms are essential actors in the biogeochemical cycling of elements within terrestrial ecosystems, with significant influences on soil health, food security, and global climate change. The contribution of microbial anabolism-induced organic compounds is a non-negligible factor in the processes associated with soil carbon (C) storage and organic matter preservation. In recent years, the conceptual framework of soil microbial carbon pump (MCP), with a focus on microbial metabolism and necromass generation process, has gained widespread attention. It primarily describes the processes of soil organic C formation and stabilization driven by the metabolic activities of soil heterotrophic microorganisms, representing an important mechanism and a focal point in current research on terrestrial C sequestration. Here, we reviewed the progress in this field and introduced the soil MCP conceptual framework 2.0, which expands upon the existing MCP model by incorporating autotrophic microbial pathway for C sequestration and integrating the concept of soil mineral C pump. These advancements aimed to enrich and refine our understanding of microbial-mediated terrestrial ecosystem C cycling and sequestration mechanisms. This refined framework would provide theoretical support for achieving China's “dual carbon” goals.

Key words: soil microbial carbon pump, microbial necromass, autotrophic microbes, mineral carbon pump, carbon cycling

ZHU Xuefeng, KONG Weidong, HUANG Yimei, XIAO Keqing, LUO Yu, AN Shaoshan, LIANG Chao. Soil microbial carbon pump conceptual framework 2.0[J]. Chinese Journal of Applied Ecology, 2024, 35(1): 102-110.

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