永久冻土
土壤碳
环境科学
微观世界
表土
土壤水分
总有机碳
碳纤维
碳循环
土壤科学
环境化学
土壤有机质
底土
碳汇
微生物种群生物学
气候变化
生态系统
生态学
二氧化碳
固碳
全球变暖
全球变化
横断面
溶解有机碳
土壤化学
无机碳总量
农学
土工试验
作者
S K Wang,Shuqi Qin,Yan Yang,Yan Yang,Leiyi Chen,Luyao Kang,Yuanhe Yang,Yuanhe Yang
摘要
ABSTRACT Soil freeze–thaw cycles (FTCs) are widespread across mid‐ to high‐latitude and high‐altitude regions, with particularly high frequency in permafrost areas where they can enhance soil carbon release and potentially accelerate climate warming. However, the response of soil carbon release to FTCs and its determinants at the regional scale remain unclear due to the lack of direct experimental evidence. Here, based on topsoil samples along a 1000‐km transect across the Tibetan permafrost region, we conducted a freeze–thaw microcosm experiment (5 cycles of 1‐day freezing and 3‐day thawing) to investigate patterns and predictors of FTC‐induced soil carbon dioxide (CO 2 ) release. The results revealed that FTCs significantly increased soil CO 2 release by 20% ± 2% relative to the thaw‐only control across all cycles. This response was primarily driven by soil carbon availability rather than microbial properties. Soils with higher carbon availability, as indicated by initially (prior to FTCs) larger soil organic carbon content and less mineral‐protected carbon, as well as greater post‐thaw increases in dissolved organic carbon, released more CO 2 under FTCs. Such an effect of carbon availability was further confirmed at the global scale. Although FTCs altered the microbial community composition, notably leading to an increase in the proportion of r ‐strategists, microbial properties played a minor role in influencing the CO 2 release. These results demonstrate the crucial role of soil carbon availability in affecting responses of CO 2 release to FTCs, highlighting the need for models to explicitly characterize pulsed CO 2 release associated with substrate availability to better predict permafrost carbon‐climate feedback.
科研通智能强力驱动
Strongly Powered by AbleSci AI