Patterns and drivers of soil microbial carbon use efficiency across soil depths in forest ecosystems
Junmin Pei, Jinquan Li, Yiqi Luo, Matthias C. Rillig, Pete Smith, Wenjing Gao, Bo Li, Changming Fang, Ming Nie
Abstract
Subsoils below 30 cm store more than half of global soil carbon. Microbial carbon use efficiency (CUE) serves as a key indicator of microbial control over soil carbon turnover, but the general patterns and drivers of microbial CUE across soil depths remain poorly understood. Here, we report a decreasing trend in microbial CUE with increasing soil depths through large-scale soil sampling across 60 sites spanning tropical to boreal forests. Using multiple analytical and statistical approaches complemented by experiments, we further identify depth-dependent drivers of microbial CUE. In the topsoil (0–10 cm), microbial CUE is primarily regulated by microbial diversity, whereas in deep subsoil (70–100 cm), it is predominantly driven by soil physicochemical protections. Our findings underscore the need to incorporate depth-specific microbial CUE drivers into carbon cycle models for more accurate predictions of whole-soil carbon storage and its feedback to climate change. Microbial carbon use efficiency (CUE) plays a key role in soil carbon storage. Here, the authors show that CUE declines with soil depth across 60 forest sites, driven by microbial diversity in topsoil and by physicochemical protection in deeper layers.