Lund University Publications

Tree species diversity influences soil carbon persistence by reconfiguring stabilization pathways

• Mark

Abstract

Increasing tree species diversity is known to enhance soil organic carbon (SOC) stocks, but its effect on SOC stability remains a critical uncertainty for climate mitigation. Through examination of a subtropical karst forest diversity gradient in southwest China, we reveal a fundamental shift in SOC stabilization mechanisms using physical fractionation, ¹³C nuclear magnetic resonance spectroscopy and metagenomic sequencing. Higher tree species diversity increased total SOC content but paradoxically decreased the ratio of mineral-associated to particulate organic carbon (MAOC:POC), a key metric traditionally linked to lower stability. This decrease, however, was accompanied by a critical reduction in SOC mineralization rate.... (More)

Increasing tree species diversity is known to enhance soil organic carbon (SOC) stocks, but its effect on SOC stability remains a critical uncertainty for climate mitigation. Through examination of a subtropical karst forest diversity gradient in southwest China, we reveal a fundamental shift in SOC stabilization mechanisms using physical fractionation, ¹³C nuclear magnetic resonance spectroscopy and metagenomic sequencing. Higher tree species diversity increased total SOC content but paradoxically decreased the ratio of mineral-associated to particulate organic carbon (MAOC:POC), a key metric traditionally linked to lower stability. This decrease, however, was accompanied by a critical reduction in SOC mineralization rate. Further analysis revealed that this enhanced persistence under high tree species diversity was associated with a trade-off between stabilization pathways. The role of traditional iron/aluminium oxide-mediated protection diminished, while two alternative mechanisms strengthened, that is (1) enhanced physical protection of POC through calcium carbonate aggregation, and (2) a profound shift in microbial ecology towards more efficient anabolism. Synthesis. This research demonstrates that tree species diversity actively reconfigures SOC stabilization pathways, emphasizing that ecosystem carbon persistence emerges from a dynamic interplay of physical, microbial and context-specific mineral controls. These findings suggest that managing for high species richness can enhance both the quantity and the resilience of forest carbon sinks, providing a robust nature-based solution for climate change mitigation.

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