Abstract
Warming effects on agricultural and forest ecosystems have been well documented at broad spatiotemporal scales but less so at stand and landscape scales. To detect the changes in soil organic carbon (SOC) and carbon:nitogen:phosphorus (C:N:P) stoichiometry in response to a short-range warming gradient, we defined an inverse elevation-dependent warming gradient and developed a novel index of warming based on a common environmental lapse rate. We associated the warming gradient and warming index with the changes in SOC and C:N:P stoichiometry and tested the independence of warming effects using partial correlation analysis. SOC content and C:N:P stoichiometric ratios significantly decreased with warming, and the effect of warming on C:N:P stoichiometric ratios were stronger than on SOC content. The relationships of SOC content and C:N:P stoichiometric ratios with warming did not change after controlling for two other energy-related variables, i.e., transmitted total radiation and potential direct incident radiation. However, the strength in the relationships of C:N:P stoichiometric ratios with vegetation-related variables significantly decreased after the warming index was controlled for. As indicated by the random forest regression model, the warming index was the most important variable for predicting SOC variability and the second most important for predicting total N variability, while vegetation-related variables were the most important for predicting C:N:P stoichiometric ratios. Our results showed that warming was responsible for the decrease in SOC content and C:N:P stoichiometric ratios and the warming index was the most important variable for predicting SOC variability. Although the most important variables for C:N:P stoichiometric ratios were related to vegetation, the relationships between C:N:P stoichiometric ratios and vegetation-related variables were significantly affected by warming. These findings demonstrate that warming is the major driver of SOC variability and the decrease in SOC content, as well as of C:N:P stoichiometry, even along a short-range warming gradient.
Highlights
Climate warming has had profound impacts on terrestrial ecosystems and all aspects of human society
Our results showed that warming was responsible for the decrease in soil organic carbon (SOC) content and C:N:P stoichiometric ratios and the warming index was the most important variable for predicting SOC variability
We found medium spatial variability in the contents of topsoil organic carbon (SOC), total nitrogen (TN), total phosphorus (TP), and the C:N:P stoichiometric ratios across the sampling plots (Table 1)
Summary
Climate warming has had profound impacts on terrestrial ecosystems and all aspects of human society. Major effects of warming on forest ecosystems involve various limitations as well as enhancements of forest growth, production, and carbon (C) and nitrogen (N) dynamics of both biomass and soil C pool components [3,8,9,10], adding to the uncertainty about the effects of global warming and the occurrence of extreme climate events. This uncertainty is especially concerning for soil C pools, because soils contain the largest C pools in the terrestrial ecosystem and have the potential to counterbalance the greenhouse effects [11]. At a small scale warming effects on SOC will be altered by various biotic and abiotic factors, such as forest types, canopy structure, species composition, gap light regimes, and topography
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