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Elevated CO<sub>2</sub> decreases soil carbon stability in Tibetan Plateau

Guang Zhao, Chao Liang, Xiaojuan Feng, Lingli Liu, Juntao Zhu, Ning Chen, Yao Chen, Li Wang, Yangjian Zhang

2020Environmental Research Letters24 citationsDOIOpen Access PDF

Abstract

Abstract The lack of ecosystem-scale CO 2 enrichment experiments in alpine regions considerably restricts our ability to predict the feedback of the global carbon (C) cycle to climate change. Here we investigate soil C response in an experiment with 5-year CO 2 enrichment and nitrogen (N) fertilization in a Tibetan meadow (4585 m above the sea level). We found that despite non-significant increase in bulk soil C pool, elevated CO 2 dramatically altered the allocation of C in different soil fractions and soil mineralization potentials. By changing soil microbial composition and enhancing enzyme activities, elevated CO 2 significantly accelerated soil organic matter (SOM) mineralization rates and stimulated the microbial utilization of ‘old C’ relative to that of ‘new C’. Furthermore, N fertilization under elevated CO 2 altered the decomposition process, increased the fungi to bacteria ratio, and decreased the coarse particulate organic matter pool and enzyme activities, indicating that N fertilization counters the CO 2 fertilization effect. Overall, our findings suggest a growing threat of elevated CO 2 in reducing SOM stability, and highlight the key role of N availability in driving soil C turnover under elevated CO 2 .

Topics & Concepts

Mineralization (soil science)Soil carbonSoil organic matterCyclingEcosystemHuman fertilizationEnvironmental chemistryCarbon cycleNitrogen cycleOrganic matterEnvironmental sciencePlateau (mathematics)NitrogenChemistryAgronomySoil waterSoil scienceEcologyBiologyForestryMathematical analysisOrganic chemistryGeographyMathematicsSoil Carbon and Nitrogen DynamicsClimate change and permafrostPeatlands and Wetlands Ecology
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