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- Title
Spatiotemporal Variability and Sources of DIC in Permafrost Catchments of the Yangtze River Source Region: Insights From Stable Carbon Isotope and Water Chemistry.
- Authors
Song, Chunlin; Wang, Genxu; Mao, Tianxu; Huang, Kewei; Sun, Xiangyang; Hu, Zhaoyong; Chang, Ruiying; Chen, Xiaopeng; Raymond, Peter A.
- Abstract
Riverine dissolved inorganic carbon (DIC) exports play a central role in the regional and global carbon cycles. Here, we investigated the spatiotemporal variability and sources of DIC in eight catchments in the Yangtze River source region (YRSR) with variable permafrost coverage and seasonally thawed active layers. The YRSR catchments are DIC‐rich (averagely 25 mg C L−1) and export 3.51 g m−2 yr−1 of DIC. The seasonal changes of temperature, active layer, flow path, and discharge can alter DIC and stable carbon isotope of DIC (δ13C‐DIC). The most depleted δ13C‐DIC values were found in the thawed period, suggesting the soil‐respired CO2 during the active layer thaw period can promote bicarbonate production via H2CO3 weathering. Spatially, δ13C‐DIC values increased downstream, likely due to CO2 outgassing and changed permafrost coverage and runoff. We found that evaporite dissolution and silicate weathering in the seasonally thawed active layer contributed 44.2% and 30.9% of stream HCO3‐, respectively, while groundwater and rainwater contributed 16.7% and 7.3% of HCO3‐, respectively. Pure carbonate rock weathering played a negligible role in DIC production. These results were compatible with δ13C‐DIC source approximation results. Silicate weathering increased from initial thaw to thawed period, reflecting the active layer thaw and subsequent hydrology change impacts. Silicate weathering consumed 1.25 × 1010 mol of CO2 annually, while evaporite dissolution may produce CO2 and neutralize this CO2 sink. This study provides new understanding of the riverine DIC export processes of the YRSR. As permafrost degrades, the quantity, sources, and sinks of riverine DIC may also change spatiotemporally. Key Points: Pronounced seasonal variability of δ13C‐DIC and DIC was affected by temperature, active layer thaw, hydrology, and mineral weatheringSpatially, δ13C‐DIC was negatively correlated with permafrost coverage, runoff, and CO2 outgassing rateRiverine HCO3‐ was mainly from evaporites (44.2%) and silicate weathering (30.9%), while carbonate rock weathering plays a minor role
- Subjects
WATER chemistry; CARBON isotopes; STABLE isotopes; WATERSHEDS; PERMAFROST; STREAM chemistry; CHEMICAL weathering
- Publication
Water Resources Research, 2020, Vol 56, Issue 1, pN.PAG
- ISSN
0043-1397
- Publication type
Article
- DOI
10.1029/2019WR025343