木质素
氮气
化学
草原
氨基糖
农学
糖
残留物(化学)
环境化学
土壤碳
微生物种群生物学
作文(语言)
氮气循环
营养物
苯酚
总有机碳
土壤水分
生态系统
土壤有机质
碳纤维
植物
碳氮比
野外试验
草地退化
作者
Xiaobo Yuan,Shize Yao,Guiyao Zhou,Adam Frew,Peter Dietrich,Yuan Li,Ying Wang,Tian Ma,Ning Chen,Yaodan Zhang,Jingrun Xu,Shujuan Wu,Mengfei Zhang,Yaodong Li,Baoming Du,Peijing Chang,Tianhu Han,Decao Niu,Hua Fu,ZengRu Wang
标识
DOI:10.5061/dryad.866t1g25j
摘要
Plant- and microbial-derived residues constitute the primary sources of soil organic carbon (SOC) in grassland ecosystems. However, their differential responses to chronic nitrogen (N) enrichment and the depth-dependent mechanisms governing their accumulation remain poorly characterized, particularly for water-limited grassland systems. Based on a 13-year field experiment in a semiarid grassland, we quantified the effects of long-term N addition on the accumulation of plant- (lignin phenols) and microbial-derived (amino sugars) residues. We found that N addition significantly increased lignin phenol content and its contribution to SOC in the topsoil, whereas lignin phenols exhibited a hump-shaped response peaking under moderate N levels in the subsoil. Amino sugar concentrations and their relative contribution to SOC increased in both soil layers under N addition, but declined at the highest N input. The dominant factors regulating residue accumulation varied with soil depth: in the topsoil, microbial K-/r-traits and community composition primarily explained lignin phenol and amino sugar dynamics, while in the subsoil, mineral-associated protection and microbial composition were the key drivers. These findings underscore the depth-dependent nature of SOC formation pathways and highlight the importance of incorporating both plant- and microbial-derived residues into Earth System Models to improve projections of carbon-climate feedback under changing nitrogen regimes.
科研通智能强力驱动
Strongly Powered by AbleSci AI