AI Article Synopsis
- Urban rivers contribute significantly to methane (CH) and carbon dioxide (CO) emissions, with this study focusing on the Liao River in northern China to analyze how land use and urbanization affect these emissions across different watershed areas.
- The research found that CH emissions are highest in fall while CO emissions peak in summer, with water quality parameters accounting for a significant portion of the variations in these emissions.
- Nutrient inputs from urban areas are identified as the main factor influencing CH and CO levels, highlighting the need for effective land use management and nutrient control to reduce emissions from rivers.
Article Abstract
Urban rivers are recognized as significant sources of methane (CH) and carbon dioxide (CO) emissions. Despite this, the influence of land use and urbanization on carbon emissions across rural-urban rivers at the watershed scale has been insufficiently explored. This study utilized in-situ surveys of the Liao River in northern China to investigate the spatial and temporal variations of CH and CO emissions and their relationship with urbanization and its potential controlling factors. The findings revealed that CH emissions peaked in fall, whereas CO emissions were highest in summer. The average fluxes of CH and CO at the water-gas interface were 1387.22 ± 2474.98 µmol·m·d and 52.78 ± 54.44 mmol·m·d, respectively. Water quality parameters accounted for 80.49 % of the total variation in CH and CO concentrations and fluxes. Structural equation modeling indicated that TN, TP, DTC, and conductivity had direct effects on riverine CH and CO emissions, with standardized direct effects of 0.50 and 0.49, respectively. Nutrient input emerged as the primary driver, increasing CH and CO concentrations and fluxes, particularly in urban-adjacent river sections likely receiving higher nutrient loads. This study underscores that land use and urbanization indirectly influence riverine CH and CO emissions by modifying nutrient inputs. Effective land use management and nutrient input control are recommended strategies to mitigate riverine CH and CO emissions.
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| http://dx.doi.org/10.1016/j.watres.2024.122266 | DOI Listing |
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