Properties of river organic carbon affected by wastewater treatment plants

Tracking the sources of organic carbon (OC) is critical not only for understanding riverine carbon dynamics but also for providing management options to improve water quality. We collected water samples from upland forest streams to the mainstream Geumho River (GHR) of South Korea, which included a...

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Veröffentlicht in:The Science of the total environment 2023-02, Vol.858, p.159761, Article 159761
Hauptverfasser: Lee, Eun-Ju, Lee, Seung-Cheol, Lee, Kyuyeon, Cha, Ji-Yeon, Han, Yea-Na, Kim, Seok Gyu, Oh, Neung-Hwan
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Sprache:eng
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Zusammenfassung:Tracking the sources of organic carbon (OC) is critical not only for understanding riverine carbon dynamics but also for providing management options to improve water quality. We collected water samples from upland forest streams to the mainstream Geumho River (GHR) of South Korea, which included a variety of wastewater treatment plants (WWTP) effluents. We analyzed the concentrations, optical properties, and dual carbon isotope ratios of these samples to identify the sources of OC. Dissolved organic carbon (DOC) was the dominant form of OC in the GHR compared to particulate organic carbon (POC), as the former accounted for 87 % of OC. The concentrations of DOC and POC ranged from 1.2 to 11.2 mg L−1 and from 0 and 3.6 mg L−1, respectively, aside from the livestock WWTP effluent. Dominant fluorescence components were terrestrial humic substances in upper reaches whereas protein-like materials in lower reaches of the GHR whose watershed includes a large city with many WWTPs. Significantly lower Δ14C-DOC and Δ14C-POC were observed in industrial WWTP effluents than the other sites due to the contribution of fossil OC. Livestock WWTP effluents had higher δ13C-DOC and δ13C-POC than most of the sites, possibly due to the animal feed derived from C4 plants such as corn. Fossil OC contributed 29–52 % of [DOC] and 36–56 % of [POC] from industrial WWTP effluents, whereas C4-plants derived OC contributed about half of [DOC] and [POC] from a livestock WWTP effluent. The results suggest that anthropogenic sources of organic carbon could alter river carbon dynamics, and that caution is needed when we interpret isotope ratios of riverine organic carbon, particularly when the river passes through highly populated areas wherein WWTP effluents are large. [Display omitted] •Dissolved organic carbon was the dominant component of organic carbon at all sites.•Industrial wastewater treatment plant effluents had high amounts of fossil carbon.•Livestock wastewater treatment plant effluents had organic carbon from C4 plants.•Residential and industrial wastewater in cities can raise riverine 14C age.
ISSN:0048-9697
DOI:10.1016/j.scitotenv.2022.159761