湿地
环境科学
环境化学
生物量(生态学)
有机质
红树林
土壤碳
蓝炭
土壤水分
碳循环
总有机碳
生态学
降级(电信)
微生物种群生物学
土壤有机质
分解
碳纤维
生态系统
固碳
土壤科学
盐沼
矿物
溶解有机碳
铅(地质)
沉积物
人事变更率
微生物降解
生物降解
木质素
生物地球化学循环
矿化(土壤科学)
作者
Yong Li,Chuancheng Fu,Peng Ren,Zhaoliang Song,Lingfang Ni,Ting Wang,Changxun Yu,Jianzhong Chen,Laodong Guo,Iain P. Hartley,Ding He,Xiaoguang Ouyang,Wei Zhi,Shaopan Xia,Weiqi Wang,Mingliang Zhao,Guangxuan Han,Yongming Luo
摘要
Coastal margins are critical sites for carbon (C) sequestration, yet the mechanisms stabilizing preaged, allochthonous C (externally-derived biospheric C) in these environments remain poorly understood. Specifically, the interplay between mineral association and microbial processing represents a significant knowledge gap. Here, we investigated C sequestration mechanisms in Chinese mangrove and saltmarsh soils by analyzing topsoils and cores across 36 sites spanning a 20-degree latitudinal transect. We found that saltmarshes, characterized by high mineral accretion and lower relative autochthonous C accumulation, exhibited significantly longer soil organic C (SOC) turnover times than mangroves (topsoils: ~2200 vs. ~500 years, respectively). This difference corresponded to higher proportions of preaged (~50%) and petrogenic (rock-derived; ~20%) SOC in saltmarshes. Linear mixed-effects models (LMM) confirmed that proxies for mineral protection (e.g., Al/Si) and advanced decomposition (lignin oxidation) were robust, positive predictors of turnover time across the latitudinal gradient. Further structural equation modeling (SEM) indicated a depth-dependent shift in drivers. In surface soils, microbial necromass accumulation was a significant predictor of C turnover (coefficient = 0.36). However, at depth (1 m), the degree of lignin degradation emerged as the primary predictor of multi-millennial C persistence (coefficient = 0.45). These results suggest a joint regulation mechanism whereby microbial processing transforms organic matter into stable forms that are subsequently protected by minerals. This mechanism effectively sequesters old, allochthonous C, challenging the paradigm that blue C storage is dominated solely by recent biomass and necessitating a reevaluation of coastal C management frameworks.
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