Hydrochemical and isotopic fingerprints of groundwater origin and evolution in the Urangulan River basin, China's Loess Plateau

The origin and evolution of groundwater in the Urangulan River basin area under growing concern as its situated in an economically and ecologically crucial area of China. In the present study, a combination of different methods (i.e. self-organizing maps (SOM), piper diagrams, ionic ratios, multiple...

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Veröffentlicht in:	The Science of the total environment 2023-03, Vol.866, p.161377-161377, Article 161377
Hauptverfasser:	Qu, Shen, Duan, Limin, Mao, Hairu, Wang, Chenyu, Liang, Xiangyang, Luo, Ankun, Huang, Lei, Yu, Ruihong, Miao, Ping, Zhao, Yuanzhen
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Sprache:	eng
Schlagworte:	atmospheric precipitation Bayesian isotope mixing model Bayesian theory cation exchange China environment evaporation evolution fertilizers geochemistry groundwater Groundwater origin gypsum humans Hydrochemical evolution hydrochemistry irrigation isotopes sewage Stable isotopes Urangulan River basin watersheds
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description	The origin and evolution of groundwater in the Urangulan River basin area under growing concern as its situated in an economically and ecologically crucial area of China. In the present study, a combination of different methods (i.e. self-organizing maps (SOM), piper diagrams, ionic ratios, multiple isotopic analyses and Bayesian isotope mixing model) provided an efficient way for analysing groundwater origin and evolution. The hydrochemical type was found to be Ca-HCO3 in low TDS and Na + K-Cl or Na + K-SO4 in high TDS groundwater. According to the δ2H and δ18Owater values, groundwater in the study area mainly originated from atmospheric precipitation and was influenced by evaporation. In addition, the rock weathering in conjunction with the cation exchange completely dominated the geochemical evolution process. The dual SO42− isotope and Bayesian isotope mixing model showed that gypsum dissolution, fertilizer input and sewage input were the main sources of SO42− in the study area, accounting for an average of 30.2 %, 28.5 %, and 17.3 % of SO42− in the groundwater, respectively. Other than water-rock interactions, human activity (mining and irrigation) distributed throughout the study area in combination with the spatial characteristics was the dominant factor controlling the hydrochemical evolution. The results of this study provided a basis for understanding groundwater origin and evolution while facilitating the effective management and utilization of groundwater. [Display omitted] •The SOM combined with isotopes are used to identify groundwater origin and evolution.•Rock weathering and cation exchange dominated the geochemical evolution process.•A Bayesian mixing model is used to quantity SO42− sources in a river basin.•The main source of SO42− was gypsum dissolution, fertilizer input, and sewage input.
doi_str_mv	10.1016/j.scitotenv.2022.161377
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In the present study, a combination of different methods (i.e. self-organizing maps (SOM), piper diagrams, ionic ratios, multiple isotopic analyses and Bayesian isotope mixing model) provided an efficient way for analysing groundwater origin and evolution. The hydrochemical type was found to be Ca-HCO3 in low TDS and Na + K-Cl or Na + K-SO4 in high TDS groundwater. According to the δ2H and δ18Owater values, groundwater in the study area mainly originated from atmospheric precipitation and was influenced by evaporation. In addition, the rock weathering in conjunction with the cation exchange completely dominated the geochemical evolution process. The dual SO42− isotope and Bayesian isotope mixing model showed that gypsum dissolution, fertilizer input and sewage input were the main sources of SO42− in the study area, accounting for an average of 30.2 %, 28.5 %, and 17.3 % of SO42− in the groundwater, respectively. Other than water-rock interactions, human activity (mining and irrigation) distributed throughout the study area in combination with the spatial characteristics was the dominant factor controlling the hydrochemical evolution. The results of this study provided a basis for understanding groundwater origin and evolution while facilitating the effective management and utilization of groundwater. [Display omitted] •The SOM combined with isotopes are used to identify groundwater origin and evolution.•Rock weathering and cation exchange dominated the geochemical evolution process.•A Bayesian mixing model is used to quantity SO42− sources in a river basin.•The main source of SO42− was gypsum dissolution, fertilizer input, and sewage input.</description><identifier>ISSN: 0048-9697</identifier><identifier>EISSN: 1879-1026</identifier><identifier>DOI: 10.1016/j.scitotenv.2022.161377</identifier><identifier>PMID: 36621476</identifier><language>eng</language><publisher>Netherlands: Elsevier B.V</publisher><subject>atmospheric precipitation ; Bayesian isotope mixing model ; Bayesian theory ; cation exchange ; China ; environment ; evaporation ; evolution ; fertilizers ; geochemistry ; groundwater ; Groundwater origin ; gypsum ; humans ; Hydrochemical evolution ; hydrochemistry ; irrigation ; isotopes ; sewage ; Stable isotopes ; Urangulan River basin ; watersheds</subject><ispartof>The Science of the total environment, 2023-03, Vol.866, p.161377-161377, Article 161377</ispartof><rights>2022</rights><rights>Copyright © 2022. 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In the present study, a combination of different methods (i.e. self-organizing maps (SOM), piper diagrams, ionic ratios, multiple isotopic analyses and Bayesian isotope mixing model) provided an efficient way for analysing groundwater origin and evolution. The hydrochemical type was found to be Ca-HCO3 in low TDS and Na + K-Cl or Na + K-SO4 in high TDS groundwater. According to the δ2H and δ18Owater values, groundwater in the study area mainly originated from atmospheric precipitation and was influenced by evaporation. In addition, the rock weathering in conjunction with the cation exchange completely dominated the geochemical evolution process. The dual SO42− isotope and Bayesian isotope mixing model showed that gypsum dissolution, fertilizer input and sewage input were the main sources of SO42− in the study area, accounting for an average of 30.2 %, 28.5 %, and 17.3 % of SO42− in the groundwater, respectively. Other than water-rock interactions, human activity (mining and irrigation) distributed throughout the study area in combination with the spatial characteristics was the dominant factor controlling the hydrochemical evolution. The results of this study provided a basis for understanding groundwater origin and evolution while facilitating the effective management and utilization of groundwater. [Display omitted] •The SOM combined with isotopes are used to identify groundwater origin and evolution.•Rock weathering and cation exchange dominated the geochemical evolution process.•A Bayesian mixing model is used to quantity SO42− sources in a river basin.•The main source of SO42− was gypsum dissolution, fertilizer input, and sewage input.</description><subject>atmospheric precipitation</subject><subject>Bayesian isotope mixing model</subject><subject>Bayesian theory</subject><subject>cation exchange</subject><subject>China</subject><subject>environment</subject><subject>evaporation</subject><subject>evolution</subject><subject>fertilizers</subject><subject>geochemistry</subject><subject>groundwater</subject><subject>Groundwater origin</subject><subject>gypsum</subject><subject>humans</subject><subject>Hydrochemical evolution</subject><subject>hydrochemistry</subject><subject>irrigation</subject><subject>isotopes</subject><subject>sewage</subject><subject>Stable isotopes</subject><subject>Urangulan River basin</subject><subject>watersheds</subject><issn>0048-9697</issn><issn>1879-1026</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><recordid>eNqFkU9vEzEQxS1ERUPhK4BvcOim_rOxvccqghYpElVFz5bXnk0cbexge1P1xFfHIaXX-jLW6DdvRu8h9JmSOSVUXG3n2foSC4TDnBHG5lRQLuUbNKNKdg0lTLxFM0Ja1XSik-fofc5bUp9U9B0650Iw2koxQ39un1yKdgM7b82ITXDY51ji3ls8-LCGtE8-lIzjgNcpTsE9mgIJx-TXPvzj4RDHqfgYcG2UDeCHZMJ6Gk3A9_5Q2d5kHy7xcuOD-ZLxKkLO-G6sOmb6gM4GM2b4-Fwv0MP3b7-Wt83q582P5fWqsS1pSwMOuBuE6ntBuKPMgRz4ogXqBCeyZ5wRy4xqVUf4wIb6a4ntKe2l6jpjGL9AX0-6-xR_T5CL3vlsYaxXQpyy5nTR0kUn1OJVlEnBFK2udhWVJ9SmmHOCQVe3diY9aUr0MSi91S9B6WNQ-hRUnfz0vGTqd-Be5v4nU4HrEwDVlYOHdBSCYMH5BLZoF_2rS_4ChtGqkA</recordid><startdate>20230325</startdate><enddate>20230325</enddate><creator>Qu, Shen</creator><creator>Duan, Limin</creator><creator>Mao, Hairu</creator><creator>Wang, Chenyu</creator><creator>Liang, Xiangyang</creator><creator>Luo, Ankun</creator><creator>Huang, Lei</creator><creator>Yu, Ruihong</creator><creator>Miao, Ping</creator><creator>Zhao, Yuanzhen</creator><general>Elsevier B.V</general><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>7S9</scope><scope>L.6</scope></search><sort><creationdate>20230325</creationdate><title>Hydrochemical and isotopic fingerprints of groundwater origin and evolution in the Urangulan River basin, China's Loess Plateau</title><author>Qu, Shen ; 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In the present study, a combination of different methods (i.e. self-organizing maps (SOM), piper diagrams, ionic ratios, multiple isotopic analyses and Bayesian isotope mixing model) provided an efficient way for analysing groundwater origin and evolution. The hydrochemical type was found to be Ca-HCO3 in low TDS and Na + K-Cl or Na + K-SO4 in high TDS groundwater. According to the δ2H and δ18Owater values, groundwater in the study area mainly originated from atmospheric precipitation and was influenced by evaporation. In addition, the rock weathering in conjunction with the cation exchange completely dominated the geochemical evolution process. The dual SO42− isotope and Bayesian isotope mixing model showed that gypsum dissolution, fertilizer input and sewage input were the main sources of SO42− in the study area, accounting for an average of 30.2 %, 28.5 %, and 17.3 % of SO42− in the groundwater, respectively. Other than water-rock interactions, human activity (mining and irrigation) distributed throughout the study area in combination with the spatial characteristics was the dominant factor controlling the hydrochemical evolution. The results of this study provided a basis for understanding groundwater origin and evolution while facilitating the effective management and utilization of groundwater. [Display omitted] •The SOM combined with isotopes are used to identify groundwater origin and evolution.•Rock weathering and cation exchange dominated the geochemical evolution process.•A Bayesian mixing model is used to quantity SO42− sources in a river basin.•The main source of SO42− was gypsum dissolution, fertilizer input, and sewage input.</abstract><cop>Netherlands</cop><pub>Elsevier B.V</pub><pmid>36621476</pmid><doi>10.1016/j.scitotenv.2022.161377</doi><tpages>1</tpages></addata></record>
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subjects	atmospheric precipitation Bayesian isotope mixing model Bayesian theory cation exchange China environment evaporation evolution fertilizers geochemistry groundwater Groundwater origin gypsum humans Hydrochemical evolution hydrochemistry irrigation isotopes sewage Stable isotopes Urangulan River basin watersheds
title	Hydrochemical and isotopic fingerprints of groundwater origin and evolution in the Urangulan River basin, China's Loess Plateau
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