Elevational shifts in foliar‐soil <scp>δ<sup>15</sup>N</scp> in the Hengduan Mountains and different potential mechanisms
Qiong Chen, Ji Chen, Mathias Neumann Andersen, Xiaoli Cheng
Abstract
Abstract The natural abundance of stable nitrogen isotopes (δ 15 N) provides insights into the N dynamics of terrestrial ecosystems, the determination of which is considered an effective approach for gaining a better understanding ecosystem N cycling. However, there is currently little information available regarding the patterns and mechanisms underlying the variation in foliar‐soil δ 15 N among mountain ecosystems. In this study, we examined the determinants of foliar‐soil δ 15 N in association with N transportation rates along an elevational gradient in the Hengduan Mountains. Despite the relatively high levels of available N produced from high N fixation and mineralization, we detected the lowest levels of foliar δ 15 N at 3500 m a.s.l., reflecting the stronger vegetation N limitation at medium high elevations. The enhanced vegetation N limitation was driven by the combined effects of higher microbial immobilization and inherent plant dynamic (the shifts of δ 15 N in vegetation preference, including vegetation community) with changing climate along the elevational gradient. Unexpectedly, we established that soil δ 15 N was characterized by an undulating rise and uncoupled correlation with foliar δ 15 N with increasing elevation, thereby indicating that litter input might not be a prominent driver of soil δ 15 N. Conversely, soil nitrification and denitrification were found to make a more pronounced contribution to the pattern of soil δ 15 N along the elevational gradient. Collectively, our results serve to highlight the importance of microbial immobilization in soil N dynamics and provide novel insights that will contribute to enhancing our understanding of N cycling as indicated by foliar‐soil δ 15 N along elevational gradients.