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The impact of emissions controls on atmospheric nitrogen inputs to Chinese river basins highlights the urgency of ammonia abatement
Science Advances ( IF 11.7 ) Pub Date : 2024-09-11 , DOI: 10.1126/sciadv.adp2558 Sijie Feng 1, 2 , Mengru Wang 2 , Mathew R Heal 3 , Xuejun Liu 1 , Xueyan Liu 4 , Yuanhong Zhao 5 , Maryna Strokal 2 , Carolien Kroeze 2 , Fusuo Zhang 1 , Wen Xu 1
Science Advances ( IF 11.7 ) Pub Date : 2024-09-11 , DOI: 10.1126/sciadv.adp2558 Sijie Feng 1, 2 , Mengru Wang 2 , Mathew R Heal 3 , Xuejun Liu 1 , Xueyan Liu 4 , Yuanhong Zhao 5 , Maryna Strokal 2 , Carolien Kroeze 2 , Fusuo Zhang 1 , Wen Xu 1
Affiliation
Excessive nitrogen (N) deposition affects aquatic ecosystems worldwide, but effectiveness of emissions controls and their impact on water pollution remains uncertain. In this modeling study, we assess historical and future N deposition trends in Chinese river basins and their contributions to water pollution via direct and indirect N deposition (the latter referring to transport of N to water from N deposited on land). The control of acid gas emissions (i.e., nitrogen oxides and sulfur dioxide) has had limited effectiveness in reducing total N deposition, with notable contributions from agricultural reduced N deposition. Despite increasing controls on acid gas emissions between 2011 and 2019, N inputs to rivers increased by 3%, primarily through indirect deposition. Simultaneously controlling acid gas and ammonia emissions could reduce N deposition and water inputs by 56 and 47%, respectively, by 2050 compared to 2019. Our findings underscore the importance of agricultural ammonia mitigation in protecting water bodies.
更新日期:2024-09-11
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