生态演替
土壤碳
期限(时间)
碳循环
环境科学
土壤科学
生态学
土壤水分
生态系统
生物
量子力学
物理
作者
Jingwei Shi,Lei Deng,Anna Gunina,Sulaiman Almwarai Alharbi,Kaibo Wang,Jiwei Li,Yulin Liu,Zhouping Shangguan,Yakov Kuzyakov
摘要
Forest restoration increases organic carbon (OC) sequestration mainly via the additional litter input and improvements in soil structure that result in biochemical and physical C stabilization over the short term. However, the pathways of long-term C stabilization in soil aggregates during forest succession are unclear. To characterize the long-term C fluxes, the aggregate-associated OC content and C flow pathways were examined over 160 years of secondary successional chronosequence from Lespedeza bicolor to Quercus liaotungensis. The contribution of plant-derived C (litter and fine root) to aggregate-associated OC was assessed using 13 C natural abundance. The proportion of macroaggregates was found to increase but microaggregates decreased along forest succession, and the macroaggregate-associated OC content increased from 4.6 to 28 g kg-1 soil during succession. The 13 C enrichment trend appeared in aggregate size classes: macroaggregates to silt and clay size classes. The maximum δ13 C was -23‰ in the silt and clay size classes in the pioneer weed stage in 20−30 cm soil depth. The C pathways followed the trend of macroaggregates to silt and clay size classes. The intensity of the C flow decreased in the topsoil (< 10 cm), but plant-derived C stocks within the aggregates increased during forest succession over the 160 years. Notably, compared to the contribution from aboveground litter, there was a greater contribution from fine root to the accumulation of OC within aggregates. The fine root and microbial biomasses were the important factors affecting fine root-derived C stocks in the aggregates. This analysis of natural δ13 C abundance provides detailed insights into long-term C stabilization pathways associated with soil aggregates during forest succession.
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