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- Multi-criteria decision process to identify groundwater potential zones using geospatial tools in the Arghandab river basin, AfghanistanPublication . Farahmand, Asadullah; Hussaini, Mohammad Salem; Jawadi, Hussain Ali; Abrunhosa, Manuel; Thomas, Brian F.This study used remote sensing (RS) and geographic information system (GIS) techniques to assess groundwater potential areas by applying two multi-criteria decision-making analyses tools in the Arghandab river basin. Twelve influencing parameters summarizing basin characteristics were gathered and generated using geospatial RS and GIS tools. The analytical hierarchy process (AHP) and analytical network process (ANP) were examined to weigh, ranking, and reclassify raster to produce groundwater potential maps. Two multi-criteria decision models were applied to compare results and suitability in the study area. The results of the AHP analysis delineate five groundwater potential zones (GWPZs) classified as very poor (29%), poor (22%), moderate (17%), high (19%), and very high (14%). On the other hand, the results of the ANP analysis classified GWPZs as very poor (25%), poor (9%), moderate (25%), high (30%), and very high (11%). To validate generated GWPZs maps, a total of 270 well locations data were utilized in the receiver operating characteristic (ROC) curve analysis. ROC model accuracy in training and validation stages is marginally higher for the ANP model (0.810 and 0.823) as compared to the AHP model (0.749 and 0.742). The groundwater potential map delineated in this study offers a preliminary assessment to scientists, public authorities, and policy makers for sustainable management of groundwater resources in the study area.
- Evaluating groundwater storage variations in Afghanistan using GRACE, GLDAS, and in-situ measurementsPublication . Jawadi, Hussain Ali; Farahmand, Asadullah; Roderick Fensham; Nilanchal PatelGroundwater resources are essential for providing drinking water and irrigation in Afghanistan. However, the rising demand due to population growth and climate change is putting increasing pressure on these resources. Despite this, the lack of organized groundwater monitoring and comprehensive long-term data on groundwater storage fuctuations remains a signifcant challenge. This study aims to address this issue by ofering insights into groundwater storage fuctuations and providing a thorough overview of Afghanistan's groundwater situation. The study aims to delineate and explain the variations in groundwater storage within Afghanistan. Additionally, it seeks to evaluate the accuracy of the GRACE model's projected groundwater storage anomalies. By leveraging the GLDAS database, the study also explores several potential factors infuencing changes in groundwater storage. In Kabul, where an in-situ groundwater network and monitoring wells are available for validation, the study confrms the spatio-temporal analysis of groundwater storage. The fndings indicate a signifcant decline in groundwater storage across the region, peaking in February 2005 (exceeding 10 cm) and reaching its lowest point in January 2017 (more than -15 cm). The most afected areas are the Harirud-Murghab, Helmand, and Kabul Basins, with a total change of approximately 116 mm. The northern part of the Helmand River Basin (HRB) remains relatively unafected. Various factors contribute to changes in groundwater storage, including reduced precipitation in the Harirud-Murghab Basin, climate change, and geological conditions. In the Kabul River Basin (KRB), urbanization, population growth, and excessive groundwater extraction play signifcant roles. Additionally, the study suggests a direct correlation between precipitation variability and groundwater storage changes nationwide.
- Evaluation of hydro-geochemical processes controlling groundwater quality in Balkh center (Mazar-e-Sharif), northern AfghanistanPublication . Farahmand, Asadullah; Zaryab, Abdulhalim; Ameri, Nasrullah; Ali, Shakir; Eqrar, Mohammad NaimBackground: Groundwater in Afghanistan stands as the predominant water source employed for potable consumption, household utilization, irrigation, and industrial applications. Major cities of Afghanistan are largely dependent on groundwater resources. However, the groundwater quality of major cities in Afghanistan, including Mazar-e-Sharif city was not investigated in detail. Objective: This study aims to conduct a comprehensive analysis of the hydrochemical characteristics of the Mazare-Sharif groundwater, identify the factors influencing groundwater quality, and evaluate the groundwater contamination sources. Methods: A total of 18 groundwater samples were collected during the dry season (June 2020) and analyzed for various physico-chemical parameters. Methods such as multivariate statistical analyses, geochemical modeling, water quality index (WQI), and spatial distribution of groundwater quality were employed to evaluate the hydrogeochemistry of the study area. Results: The results reveal that 1) The prevailing groundwater within the study area is predominantly characterized by Na-(Ca)-HCO3 and Ca-(Mg)-SO4 water types. 2) Physicochemical variables such as NO3 − , F− , TDS, and SO4 2− exceeded the World Health Organization (WHO) safe limits in many wells. 3) Hydro-geochemical processes such as silicate weathering, cation exchange, and gypsum dissolution controls the groundwater chemistry. 4) Cl/ Br ratios reveal, that high salinity may originate from evaporitic lacustrine and evaporite deposits and found to be localized in nature. 5) The Water Quality Index (WQI) classification suggests that approximately 60 % of the groundwater samples fall into poor to very poor water quality categories, highlighting substantial public health concerns. Major contaminants like nitrate and fluoride were found to be higher than the safe limit in nearly half of the samples. Conclusion: The findings of this study hold value for decision-makers in formulating a proficient strategy for the management of groundwater resources in Mazar-e-Sharif City in achieving the UN sustainable goal (SDG) of providing sustainable water for all. Furthermore, new advanced techniques like environmental isotopes should be analyzed to evaluate groundwater hydro-chemical evolution in the future to enhance our understanding.