环境科学
富营养化
分水岭
水质
水文学(农业)
缺氧(环境)
流域
农业
硝酸盐
营养物
氮气
空间变异性
氮气循环
构造盆地
水资源管理
营养污染
非点源污染
水污染
水流
水平衡
反硝化
气候变化
水资源
生态系统
电流(流体)
溪流
水文模型
土壤水分
水生生态系统
流域管理
空间生态学
出院手续
作者
Qianyu Zhao,Bin Peng,Zewei Ma,Mengqi Jia,Gregory F. McIsaac,Dale M. Robertson,David A. Saad,Richard W. Warner,Xiaocui Wu,Qu Zhou,Kaiyu Guan
标识
DOI:10.1021/acs.est.5c06476
摘要
Excessive nitrogen export from agricultural watersheds remains a critical water quality challenge, with the Upper Mississippi River Basin (UMRB) significantly contributing to downstream eutrophication and hypoxia in the Gulf. This study investigates the spatiotemporal dynamics of riverine nitrate plus nitrite (NO3- + NO2--N) export across the UMRB at high spatial resolution (12-digit Hydrologic Unit Codes or HUC12 subwatershed scale) during 2001-2020 and quantifies the effects of anthropogenic activities and hydrological variability on riverine NO3- + NO2--N export changes in the region between 2001-2005 and 2016-2020. Our results revealed hotspots of substantial increases in NO3- + NO2--N yields across the UMRB, with distinct regional patterns in driving factors. Over the entire UMRB, NO3- + NO2--N yields increased by 9.7 kg/ha/yr on average from 2001-2005 to 2016-2020, with anthropogenic activities contributing 4.8 kg/ha/yr and hydrological variability contributing 4.9 kg/ha/yr. The northern and western UMRB had combined influences from both anthropogenic activities and hydrological variability, while the east-central regions had predominantly hydrologically driven changes. Agricultural sources, including fertilizer, manure, and biological nitrogen fixation, collectively contributed over 80% of NO3- + NO2--N loading throughout the basin. This framework for disentangling human and hydrological impacts provides critical insights for developing effective and targeted watershed management strategies to reduce nutrient losses and improve water quality.
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