Improving the identification of pollution source areas with catchment-resolution sensitivity analysis

• Published in: Environmental pollution (1987) Vol. 360; p. 124658
• Main Authors: Li, Xia, Du, Ling, Zhang, Shuhui, Shi, Ke, Yang, Qichun, Li, Liping, Jiang, Jiakun, Ren, Ze, Liu, Xinhui
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.11.2024
• Subjects: Catchment resolutions; China; Ecosystem; Environmental Monitoring - methods; Land use; Nitrogen - analysis; Phosphorus - analysis; Pollution source areas; Rivers - chemistry; Topography; Total nitrogen; Total phosphorus; Water Pollutants, Chemical - analysis; China; Pollution source areas; Total nitrogen; Catchment resolutions; Topography; Land use; Total phosphorus
• ISSN: 0269-7491; 1873-6424; 1873-6424
• DOI: 10.1016/j.envpol.2024.124658

The significant impacts of total nitrogen (TN) and total phosphorus (TP) on riverine ecosystems underscores the critical need to identify the primary nutrient source areas in watersheds. This study aims to unravel the influences of terrain and land use types on mean monthly TN (TNM) and mean monthly TP (TPM) export across varying catchment resolutions in the Qiantang River Watershed of China. The findings of this study illuminated the critical role of topography in understanding nutrient dynamics, wielding a profound influence over water flow patterns and nutrient dispersion. Both land slope and Stream Power Index (SPI) displayed substantial negative correlations (r < −0.6) with TNM and TPM concentrations, whereas the Topographic Wetness Index (TWI) showed positive correlations with the nutrient indexes. In addition to terrain characteristics, impervious land surfaces had a positive correlation with nutrient concentrations, while grassland and forest areas exhibited negative correlations. Results further underscored the substantial influence of catchment resolution on correlations between watershed properties and riverine nutrient concentrations. It was imperative to choose an effective catchment resolution in watershed delineation – not too coarse, nor too fine – to accurately capture the topographic and land use impacts on nutrient dynamics. With the most appropriate catchment size (Catchment 700 km2), the critical pollution source areas for TN and TP pollution were identified, and thus could be used to guide future pollution reduction efforts. The study not only highlights the importance of identifying an appropriate catchment size for water pollution, but also emphasizes the necessity of effectively extracting critical pollution source areas to mitigate water nutrient pollution and increase the ecological integrity of the Qiantang River Watershed. [Display omitted] •Both topography and land use significantly correlated with riverine nutrients.•The catchment resolutions shape the pollution source areas of nutrients.•Impervious lands were the most critical nutrient sources in the watershed.