Source partitioning using phosphate oxygen isotopes and multiple models in a large catchment

•First use of phosphate oxygen isotopes to resolve sources in a whole and large catchment.•Heavy rainfall contributed to the high TP loads in the wet season.•Coupling land use types and the mixed end-element model can effectively identify main P sources.•Phosphate oxygen isotopes combined with a Bay...

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Veröffentlicht in:Water research (Oxford) 2023-10, Vol.244, p.120382-120382, Article 120382
Hauptverfasser: Wang, Ziteng, Tian, Liyan, Zhao, Changqiu, Du, Chenjun, Zhang, Jun, Sun, Fuhong, Tekleab, Teklit Zerizghi, Wei, Rongfei, Fu, Pingqing, Gooddy, Daren C., Guo, Qingjun
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Sprache:eng
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Zusammenfassung:•First use of phosphate oxygen isotopes to resolve sources in a whole and large catchment.•Heavy rainfall contributed to the high TP loads in the wet season.•Coupling land use types and the mixed end-element model can effectively identify main P sources.•Phosphate oxygen isotopes combined with a Bayesian model can quantify multiple human P input. Excessive phosphorus (P) loadings cause major pollution concerns in large catchments. Quantifying the point and nonpoint P sources of large catchments is essential for catchment P management. Although phosphate oxygen isotopes (δ18O(PO4)) can reveal P sources and P cycling in catchments, quantifying multiple P sources in a whole catchment should be a research focus. Therefore, this study aimed to quantitatively identify the proportions of multiple potential end members in a typical large catchment (the Yangtze River Catchment) by combining the phosphate oxygen isotopes, land use type, mixed end-element model, and a Bayesian model. The δ18O(PO4) values of river water varied spatially from 4.9‰ to18.3‰ in the wet season and 6.0‰ to 20.9‰ in the dry season. Minor seasonal differences but obvious spatial changes in δ18O(PO4) values could illustrate how human activity changed the functioning of the system. The results of isotopic mass balance and the Bayesian model confirmed that controlling agricultural P from fertilizers was the key to achieving P emission reduction goals by reducing P inputs. Additionally, the effective rural domestic sewage treatment, development of composting technology, and resource utilization of phosphogypsum waste could also contribute to catchment P control. P sources in catchment ecosystems can be assessed by coupling an isotope approach and multiple-models. [Display omitted]
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2023.120382