Evolution of watershed phosphorus buffering capacity and its response to land-use change in Poyang Lake basin, China

The watershed buffering capacity is an important pivot to regulate phosphorus (P) pressure in aquatic environment, and land use is a key factor for its regulation. However, the response mechanism of buffer capacity to land use change remains unknown. Based on the variation of “buffering capacity ind...

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Published inJournal of cleaner production Vol. 365; p. 132606
Main Authors Zhong, Wenjun, Dong, Yue, Wang, Shengrui, Ni, Zhaokui, Wu, Daishe, Yang, Yulong, Deng, Zeyu
Format Journal Article
LanguageEnglish
Published 10.09.2022
Subjects
agricultural land
aquatic environment
buffering capacity
China
grasslands
hysteresis
issues and policy
land use change
landscapes
phosphorus
pollution control
watersheds
wetlands
China
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Summary:The watershed buffering capacity is an important pivot to regulate phosphorus (P) pressure in aquatic environment, and land use is a key factor for its regulation. However, the response mechanism of buffer capacity to land use change remains unknown. Based on the variation of “buffering capacity index” in the Poyang Lake basin from 1990 to 2019, the mechanism of their response relationship was revealed via quantifying watershed P retention threshold and P removal process in different landscapes. Results showed that the watershed P buffering capacity was significantly affected by the scale of landscape subject to certain conditions of net anthropogenic P inputs (NAPI) in the Poyang Lake basin. The decreases in agricultural land, grassland and wetland and the increase of artificial land jointly explained 66.9% of watershed P buffering capacity decrease before accumulative P retention reached the threshold. The contribution of land use to watershed P buffering capacity change decreased to 53.8% when the P retention exceeded the threshold. Decreasing in watershed P buffering capacity was closely related to the increase of P loss in cultivated land, and wetland P removal provided an optimized direction for restoring the watershed buffering capacity. The findings reinforce the understanding of P hysteresis on watershed environment, and provide a policy basis for developing sustainable P management and pollution control from the perspective of optimizing land-use.
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ISSN:0959-6526
DOI:10.1016/j.jclepro.2022.132606