Litcius/Paper detail

Mineral reactivity determines root effects on soil organic carbon

Guopeng Liang, John Stark, Bonnie G. Waring

2023Nature Communications90 citationsDOIOpen Access PDF

Abstract

Modern conceptual models of soil organic carbon (SOC) cycling focus heavily on the microbe-mineral interactions that regulate C stabilization. However, the formation of 'stable' (i.e. slowly cycling) soil organic matter, which consists mainly of microbial residues associated with mineral surfaces, is inextricably linked to C loss through microbial respiration. Therefore, what is the net impact of microbial metabolism on the total quantity of C held in the soil? To address this question, we constructed artificial root-soil systems to identify controls on C cycling across the plant-microbe-mineral continuum, simultaneously quantifying the formation of mineral-associated C and SOC losses to respiration. Here we show that root exudates and minerals interacted to regulate these processes: while roots stimulated respiratory C losses and depleted mineral-associated C pools in low-activity clays, root exudates triggered formation of stable C in high-activity clays. Moreover, we observed a positive correlation between the formation of mineral-associated C and respiration. This suggests that the growth of slow-cycling C pools comes at the expense of C loss from the system.

Topics & Concepts

CyclingRespirationCarbon cycleMineralSoil carbonChemistrySoil respirationOrganic matterEnvironmental chemistryCarbon fibersSoil waterMineralization (soil science)Soil scienceEcosystemEcologyBotanyEnvironmental scienceBiologyMaterials scienceOrganic chemistryComposite numberComposite materialHistoryArchaeologySoil Carbon and Nitrogen DynamicsClay minerals and soil interactionsSoil and Unsaturated Flow