溶解有机碳
永久冻土
环境科学
碳循环
土壤碳
总有机碳
水文学(农业)
碳纤维
土壤水分
温带气候
放射性碳年代测定
有机质
环境化学
生物地球化学循环
土壤有机质
全球变暖
陆地生态系统
碳同位素
地表水
水生生态系统
微粒
水循环
生物地球化学
全球变化
土层
气候变化
表土
海洋学
地球科学
作者
Zhaohui Liu,Yongqiang Zhou,Gerard Rocher‐Ros,Joshua Dean,Jack J Middelburg,Pierre Regnier,Jan Karlsson,L Zhang,Weipeng Lin,Chenglong Wang,Lei Zhou,Jianjun Wang,Yunlin Zhang,R Iestyn Woolway,Travis W. Drake,Robert G M Spencer,Peter R. Leavitt
摘要
Abstract Riverine dissolved organic carbon (DOC) constitutes a pivotal component in the Earth’s carbon cycle, yet little is known about the global patterns, sources, and factors governing lotic DOC. Here, we integrate a global dataset and employ machine learning to generate a global atlas of riverine DOC concentration and its radiocarbon (Δ14C) and stable-carbon (δ13C) isotopic signatures. Globally, riverine DOC has an average Δ14C value of –22.5 ± 144.0‰ (radiocarbon age of 221 years), with fossil carbon contributing a minor fraction (6.7 ± 3.0%). Terrestrial and autochthonous riverine production are the dominant DOC sources (>80%) at the global scale, with contemporary terrestrial DOC predominant in tropical rivers and within-river production prominent in those within temperate and semi-arid regions. Rivers draining high-latitude regions and high-elevation sites have the lowest Δ14C values (–353‰ to –78‰; ages between 3400 and 600 years). River Δ14C-DOC values correlate with soil organic carbon and riverine particulate organic carbon Δ14C values, but river DOC has much higher Δ14C values than subsurface soils indicating that riverine DOC originates from surface rather than subsurface soils. Because warming mobilizes aged organic carbon from permafrost soils, export to and processing of old carbon in recipient aquatic systems may accelerate with climate change.
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