Groundwater sustainability assessment based on socio-economic and environmental variables: a simple dynamic indicator-based approach

The Dehgolan aquifer, which lies in semiarid western Iran, was evaluated using a multi-influencing factor (MIF) analysis to determine groundwater sustainability. Eight indicators, including climatic variability, groundwater exploitation (pumping), groundwater quality, groundwater vulnerability, publ...

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Veröffentlicht in:	Hydrogeology journal 2022-11, Vol.30 (7), p.1963-1988
Hauptverfasser:	Karimi, Delnia, Bahrami, Jamil, Mobaraki, Jalil, Missimer, Thomas M., Taheri, Kamal
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Aquatic Pollution Aquifers Chi-square test Climate variability Earth and Environmental Science Earth Sciences Exploitation Geographical information systems Geology Geophysics/Geodesy Governance Groundwater Groundwater basins Groundwater levels Groundwater quality Hydrogeology Hydrology/Water Resources Management methods Public participation Socioeconomic aspects Sustainability Sustainable use Tabulation Thematic mapping Vulnerability Waste Water Technology Water levels Water Management Water Pollution Control Water quality Water Quality/Water Pollution Water use
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container_end_page	1988
container_issue	7
container_start_page	1963
container_title	Hydrogeology journal
container_volume	30
creator	Karimi, Delnia Bahrami, Jamil Mobaraki, Jalil Missimer, Thomas M. Taheri, Kamal
description	The Dehgolan aquifer, which lies in semiarid western Iran, was evaluated using a multi-influencing factor (MIF) analysis to determine groundwater sustainability. Eight indicators, including climatic variability, groundwater exploitation (pumping), groundwater quality, groundwater vulnerability, public participation, legal framework, water productivity, and occupation related to groundwater, were quantified and placed into a series of thematic maps within a GIS framework. Each factor was weighted based on the analyses obtained from the MIF model and the stacked maps were summed to yield a final map showing the degree of sustainability within the groundwater basin. The final groundwater sustainability map showed that 4% of the basin was in a critically unsustainable zone, 30% in an unsustainable zone, 40% in a semisustainable zone, 25% in a sustainable zone, and 1% in an ideally sustainable zone. The final map was validated using a receiver operating characteristic (ROC) method, cross-tabulation, and chi-square tests using groundwater-level decline as a test proxy. The analysis assessed the correlation between water levels that exhibited declines versus the degree of unsustainability of water levels and sustainable water use. The area under the curve was calculated to be 88%, cross-tabulation 64.4%, and the chi-square value was 260.5 with 4 degrees of freedom and values
doi_str_mv	10.1007/s10040-022-02512-6
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subjects	Analysis Aquatic Pollution Aquifers Chi-square test Climate variability Earth and Environmental Science Earth Sciences Exploitation Geographical information systems Geology Geophysics/Geodesy Governance Groundwater Groundwater basins Groundwater levels Groundwater quality Hydrogeology Hydrology/Water Resources Management methods Public participation Socioeconomic aspects Sustainability Sustainable use Tabulation Thematic mapping Vulnerability Waste Water Technology Water levels Water Management Water Pollution Control Water quality Water Quality/Water Pollution Water use
title	Groundwater sustainability assessment based on socio-economic and environmental variables: a simple dynamic indicator-based approach
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