Please use this identifier to cite or link to this item: https://doi.org/10.5194/bg-14-2183-2017
Title: Dynamics of riverine CO2 in the Yangtze River fluvial network and their implications for carbon evasion
Authors: Ran, L
Lu, X.X 
Liu, S
Keywords: alkalinity
biogeochemistry
carbon budget
carbon cycle
carbon dioxide
carbonate
headwater
organic matter
partial pressure
terrestrial environment
water chemistry
China
Yangtze River
Issue Date: 2017
Citation: Ran, L, Lu, X.X, Liu, S (2017). Dynamics of riverine CO2 in the Yangtze River fluvial network and their implications for carbon evasion. Biogeosciences 14 (8) : 2183-2198. ScholarBank@NUS Repository. https://doi.org/10.5194/bg-14-2183-2017
Abstract: Understanding riverine carbon dynamics is critical for not only better estimates of various carbon fluxes but also evaluating their significance in the global carbon budget. As an important pathway of global land-ocean carbon exchange, the Yangtze River has received less attention regarding its vertical carbon evasion compared with lateral transport. Using long-term water chemistry data, we calculated CO2 partial pressure (pCO2) from pH and alkalinity and examined its spatial and temporal dynamics and the impacts of environmental settings. With alkalinity ranging from 415 to > 3400 μeq L-1, the river waters were supersaturated with dissolved CO2, generally 2-20-fold the atmospheric equilibrium (i.e., 390 μatm). Changes in pCO2 were collectively controlled by carbon inputs from terrestrial ecosystems, hydrological regime, and rock weathering. High pCO2 values were observed spatially in catchments with abundant carbonate presence and seasonally in the wet season when recently fixed organic matter was exported into the river network. In-stream processing of organic matter facilitated CO2 production and sustained the high pCO2, although the alkalinity presented an apparent dilution effect with water discharge. The decreasing pCO2 from the smallest headwater streams through tributaries to the mainstem channel illustrates the significance of direct terrestrial carbon inputs in controlling riverine CO2. With a basin-wide mean pCO2 of 2662 ± 1240 μatm, substantial CO2 evasion from the Yangtze River fluvial network is expected. Future research efforts are needed to quantify the amount of CO2 evasion and assess its biogeochemical implications for watershed-scale carbon cycle. In view of the Yangtze River's relative importance in global carbon export, its CO2 evasion would be significant for global carbon budget. © Author(s) 2017.
Source Title: Biogeosciences
URI: https://scholarbank.nus.edu.sg/handle/10635/176092
ISSN: 1726-4170
DOI: 10.5194/bg-14-2183-2017
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