微生物种群生物学
微生物降解
化学
氮气
呼吸
呼吸速率
环境化学
生态系统
人事变更率
泰加语
北方的
溶解有机碳
氮气循环
生长季节
微生物
碳循环
农学
土壤碳
生态学
微生物代谢
碳纤维
细菌生长
土壤呼吸
总有机碳
有机质
沉积(地质)
动物科学
微生物生态学
生态系统呼吸
植物
作者
Xingyu Sun,Shuying Zang,Guoyong yan,YaJuan XING,Chao Liang,Liming Yin,Pengshuai Shao,Xinyu Liu,Guancheng Liu,Yuguo Gao,Qinggui Wang
出处
期刊:Geoderma
[Elsevier BV]
日期:2026-02-13
卷期号:467: 117733-117733
标识
DOI:10.1016/j.geoderma.2026.117733
摘要
• Low nitrogen addition promoted microbial CUE and accelerated turnover rate. • High nitrogen had either no effect on or inhibited microbial CUE. • Microbial CUE showed obvious seasonal dynamics, which was highest in spring. • Microbial respiration and turnover rate reached their peak in summer. • SOC was significantly positively correlated with microbial CUE and turnover rate. Microbial carbon use efficiency (CUE) is a key parameter in regulating the soil microbial C cycle, influencing C mineralization, turnover, and sequestration. The boreal forest plays a key role in the global C cycle, attributable to its substantial C stocks. However, seasonal variations in microbial CUE in boreal forest ecosystems and their response to enhanced nitrogen (N) deposition are poorly understood. We conducted a N addition experiment (0, 2.5, 5.0, and 7.5 g N m⁻ 2 yr⁻ 1 ) in a boreal forest, employing a substrate-independent 18 O-H 2 O labeling method to evaluate seasonal variations in microbial CUE and turnover rates. N effect on CUE was contingent on sampling season and N addition rate. Throughout the growing season, low N addition increased microbial CUE and accelerated microbial turnover rate. In contrast, high N addition had no significant effect or even decreased microbial CUE. Additionally, microbial respiration and turnover rate were highest in summer across all treatments, while microbial CUE peaked in spring. The findings also revealed a significant positive relationship between microbial CUE and factors such as the fungal-to-bacterial (F/B) ratio, dissolved organic carbon (DOC), and soil organic carbon (SOC), while being negatively correlated with the DOC/dissolved organic N (DON) ratio. Our results indicate that increases in microbial CUE and turnover under LN addition contribute to elevated SOC levels, likely through changes in microbial carbon allocation and stabilization processes. Overall, these findings highlight the crucial role of seasonal microbial CUE dynamics in regulating soil C processes under long-term N addition in boreal forest.
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