Yunfeng Peng, Dianye Zhang, Fei Li, Yuanhe Yang, Jun Wang, Kai Fang, Guoying Zhou, Guanqin Wang, Guibiao Yang, Changbin Li
Unprecedented levels of nitrogen (N) have entered terrestrial ecosystems over the past century, which substantially influences the carbon (C) exchange between the atmosphere and biosphere. Temperature and moisture are generally regarded as the major controllers over the N effects on ecosystem C uptake and release. N-phosphorous (P) stoichiometry regulates the growth and metabolisms of plants and soil organisms, thereby affecting many ecosystem C processes. However, it remains unclear how the N-induced shift in the plant N:P ratio affects ecosystem production and C fluxes and its relative importance. We conducted a field manipulative experiment with eight N addition levels in a Tibetan alpine steppe and assessed the influences of N on aboveground net primary production (ANPP), gross ecosystem productivity (GEP), ecosystem respiration (ER), and net ecosystem exchange (NEE); we used linear mixed-effects models to further determine the relative contributions of various factors to the N-induced changes in these parameters. Our results showed that the ANPP, GEP, ER, and NEE all exhibited nonlinear responses to increasing N additions. Further analysis demonstrated that the plant N:P ratio played a dominate role in shaping these C exchange processes. There was a positive relationship between the N-induced changes in ANPP (ΔANPP) and the plant N:P ratio (ΔN:P), whereas the ΔGEP, ΔER, and ΔNEE exhibited quadratic correlations with the ΔN:P. In contrast, soil temperature and moisture were only secondary predictors for the changes in ecosystem production and C fluxes along the N addition gradient. These findings highlight the importance of plant N:P ratio in regulating ecosystem C exchange, which is crucial for improving our understanding of C cycles under the scenarios of global N enrichment.
Increasing nitrogen (N) deposition substantially influences the carbon (C) exchange between the atmosphere and terrestrial biosphere. Temperature and moisture are generally regarded as the major controllers over the N effects on ecosystem C uptake and release. Here we present evidence that plant N:phosphorous (P) ratio, too, is tightly linked to ecosystem production and C fluxes under N additions. Using a field experiment with various N addition levels, we found that plant N:P ratio played a dominate role in shaping these C exchange processes, whereas edaphic variables were relatively weaker in predicting the changes in ecosystem production and C fluxes induced by N additions. These findings highlight the importance of plant N-P stoichiometry in regulating ecosystem C exchange, which is crucial for improving our understanding of C cycles under the scenarios of global N enrichment.
