Anthropogenic Activities Generate High-Refractory Black Carbon along the Yangtze River Continuum

Combustion-driven particulate black carbon (PBC) is a crucial slow-cycling pool in the organic carbon flux from rivers to oceans. Since the refractoriness of PBC stems from the association of non-homologous char and soot, the composition and source of char and soot must be considered when investigat...

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Veröffentlicht in:Environmental science & technology 2023-06, Vol.57 (23), p.8598-8609
Hauptverfasser: Meng, Lize, Hao, Weiyue, Zhao, Chu, Li, Shuaidong, Xue, Jingya, Li, Jianhong, Tu, Luyao, Huang, Tao, Yang, Hao, Yu, Zhaoyuan, Yuan, Linwang, Huang, Changchun
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Sprache:eng
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Zusammenfassung:Combustion-driven particulate black carbon (PBC) is a crucial slow-cycling pool in the organic carbon flux from rivers to oceans. Since the refractoriness of PBC stems from the association of non-homologous char and soot, the composition and source of char and soot must be considered when investigating riverine PBC. Samples along the Yangtze River continuum during different hydrological periods were collected in this study to investigate the association and asynchronous combustion drive of char and soot in PBC. The results revealed that PBC in the Yangtze River, with higher refractory nature, accounts for 13.73 ± 6.89% of particulate organic carbon, and soot occupies 37.53 ± 11.00% of PBC. The preponderant contribution of fossil fuel combustion to soot (92.57 ± 3.20%) compared to char (27.55 ± 5.92%), suggested that fossil fuel combustion is a crucial driver for PBC with high soot percentage. Redundancy analysis and structural equation modeling confirmed that the fossil fuel energy used by anthropogenic activities promoting soot is the crucial reason for high-refractory PBC. We estimated that the Yangtze River transported 0.15–0.23 Tg of soot and 0.15–0.25 Tg of char to the ocean annually, and the export of large higher refractory PBC to the ocean can form a long-term sink and prolong the residence time of terrigenous carbon.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.2c09827