Risk characterization and surface water quality assessment of Manas River, Assam (India) with an emphasis on the TOPSIS method of multi-objective decision making

The present study centers on the investigation of surface water quality with the aid of quality indices and explores the application of a multi-objective decision-making method (TOPSIS) in arranging decisions for policy makers on the basis of overall ranking of the sampling locations. A case study h...

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Veröffentlicht in:	Environmental earth sciences 2018-12, Vol.77 (23), p.1-10, Article 780
Hauptverfasser:	Singh, Kunwar Raghvendra, Dutta, Rahul, Kalamdhad, Ajay S., Kumar, Bimlesh
Format:	Artikel
Sprache:	eng
Schlagworte:	Biogeosciences Case studies Cluster analysis Contamination Decision making Decisions Earth and Environmental Science Earth Sciences Environmental Science and Engineering Geochemistry Geology Health hazards Heavy metals Hydrology/Water Resources Locations (working) Metals Methods Multiple objective analysis Organic chemistry Original Article Parameters Policies Pollution Pollution index Pollution levels Quality assessment Quality control Ranking Risk assessment Risk management Rivers Sampling Surface water Surface water quality Terrestrial Pollution Water pollution Water quality Water quality assessments
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creator	Singh, Kunwar Raghvendra Dutta, Rahul Kalamdhad, Ajay S. Kumar, Bimlesh
description	The present study centers on the investigation of surface water quality with the aid of quality indices and explores the application of a multi-objective decision-making method (TOPSIS) in arranging decisions for policy makers on the basis of overall ranking of the sampling locations. A case study has been performed on the Manas River, Assam (India). Water Quality Index (WQI) involving physico-chemical parameters, and heavy metal pollution index (HPI) and contamination index (CI) involving heavy metal influences were employed for water quality assessment. WQI graded two sampling locations “very poor” and all other locations “poor”. HPIs of all the locations were below the critical value of 100, but the CI depicted that two locations were “moderately contaminated”. Risk assessment to human health was done using hazard quotient and hazard index. Cluster analysis (CA) demonstrated site similarity by grouping the relatively more polluted and less polluted (LP) sites into two major clusters. However, there surfaced difficulty in discerning the overall water quality, as all the three quality indices included different parameters and contradicted each other. A multi-objective decision-making tool, TOPSIS was therefore employed for ranking the locations on the basis of their relative pollution levels. The novelty of the study reflects in the identification of the relatively more or relatively less polluted sites within the same cluster in CA by the application of TOPSIS. The study justifies the effectiveness of TOPSIS method in prioritizing decisions in complex scenarios for policy makers.
doi_str_mv	10.1007/s12665-018-7970-9
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A case study has been performed on the Manas River, Assam (India). Water Quality Index (WQI) involving physico-chemical parameters, and heavy metal pollution index (HPI) and contamination index (CI) involving heavy metal influences were employed for water quality assessment. WQI graded two sampling locations “very poor” and all other locations “poor”. HPIs of all the locations were below the critical value of 100, but the CI depicted that two locations were “moderately contaminated”. Risk assessment to human health was done using hazard quotient and hazard index. Cluster analysis (CA) demonstrated site similarity by grouping the relatively more polluted and less polluted (LP) sites into two major clusters. However, there surfaced difficulty in discerning the overall water quality, as all the three quality indices included different parameters and contradicted each other. A multi-objective decision-making tool, TOPSIS was therefore employed for ranking the locations on the basis of their relative pollution levels. The novelty of the study reflects in the identification of the relatively more or relatively less polluted sites within the same cluster in CA by the application of TOPSIS. The study justifies the effectiveness of TOPSIS method in prioritizing decisions in complex scenarios for policy makers.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><doi>10.1007/s12665-018-7970-9</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0001-6647-9796</orcidid></addata></record>
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subjects	Biogeosciences Case studies Cluster analysis Contamination Decision making Decisions Earth and Environmental Science Earth Sciences Environmental Science and Engineering Geochemistry Geology Health hazards Heavy metals Hydrology/Water Resources Locations (working) Metals Methods Multiple objective analysis Organic chemistry Original Article Parameters Policies Pollution Pollution index Pollution levels Quality assessment Quality control Ranking Risk assessment Risk management Rivers Sampling Surface water Surface water quality Terrestrial Pollution Water pollution Water quality Water quality assessments
title	Risk characterization and surface water quality assessment of Manas River, Assam (India) with an emphasis on the TOPSIS method of multi-objective decision making
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