References

  1. D.R. Rahmawati, Supriyadi, N.P. Aryani, M.A. Naufal, Groundwater potential prediction by using geoelectricity method a case study in Simpang Lima and around it, J. Phys. Conf. Ser., 983 (2018) 012003, doi:10.1088/1742–6596/983/1/012003.
  2. S.P. Gorde, M.V. Jadhav, Assessment of water quality parameters. A review, Int. J. Eng. Appl. Sci., 3 (2013) 2029–2035.
  3. T. Ahmed, A. Pervez, M. Mehtab, S.K. Sherwani, Assessment of drinking water quality and its potential health impacts in academic institutions of Abbottabad Pakistan, Desal. Water Treat., 7 (2014) 1819–1828.
  4. A. Niaz, M. Imtiaz, M.R. Khan, F. Hameed, J. Niaz, A.Y. Khan, K. Mehmood, The use of GIS and geo-electric techniques for delineation surface and groundwater potential in Kotli City, District Kotli, Azad Jammu and Kashmir, Pakistan, Pak. J. Eng. Appl. Sci., 26 (2020) 1–15.
  5. S. Gaikwad, N.J. Pawar, P. Bedse, V. Wagh, A. Kadam, Delineation of groundwater potential zones using vertical electrical sounding (VES) in a complex bedrock geological setting of the West Coast of India, Model. Earth Syst. Environ., (2021), doi: 10.1007/s40808-021-01223-3.
  6. A. Niaz, R.M. Khan, U. Ijaz, M.Y. Khan, F. Hameed, Determination of groundwater potential by using geoelectrical method and petrographic analysis in Rawalakot and adjacent areas of Azad Kashmir,
    sub-Himalayas, Pakistan, Arabian J. Geosci., 11 (2017) 55, doi: 10.1007/s12517-018-3811-0.
  7. A. Stampolidis, P. Tsourlos, P. Soupios, T.H. Mimides, G. Tsokas, G. Vargemezis, A. Vafidis, Integrated geophysical investigation around the brackish spring of Rina, Kalimnos Island Greece, Balk Geophys. Soc., 8 (2005) 63–73.
  8. P. Soupios, M. Kouli, F. Vallianatos, A. Vafidis, G. Stavroulakis, Estimation of aquifer parameters from surficial geophysical methods. A case study of Keritis Basin in Crete, J. Hydrol., 338 (2007) 122–131.
  9. D. Kalisperi, P. Soupios, M. Kouli, P. Barsukov, S. Kershaw, P. Collins, F. Vallianatos, Coastal Aquifer Assessment Using Geophysical Methods (TEM, VES), Case Study: Northern Crete, Greece, 3rd IASME/WSEAS International Conference on Geology and Seismology (GES ‘09) Cambridge, UK, 2009, pp. 24–26.
  10. V. Kadam, S. Wagh, B. Patil, R. Umrikar, R. Sankhua, Seasonal assessment of groundwater contamination, health risk and chemometric investigation for a hard rock terrain of western India, Environ. Earth Sci., 80 (2021) 172, doi: 10.1007/s12665-021-09414-y.
  11. B. Redhaounia, M. Bédir, H. Gabtni, O.I. Batobo, M. Dhaoui, A. Chabaane, S. Khomsi, Hydro-geophysical characterization for groundwater resources potential of fractured limestone reservoirs in Amdoun Monts (North-western Tunisia), J. Appl. Geophys., 128 (2016) 150–162.
  12. V. Kadam, J. Wagh, S. Jacobs, N. Patil, B. Pawar, R. Umrikar, S. Sankhua, S. Kumar, Integrated approach for the evaluation of groundwater quality through hydro geochemistry and human health risk from Shivganga river basin, Pune, Maharashtra, India, Environ. Sci. Pollut. Res., 29 (2022) 4311–4333.
  13. M. Bersi, H. Saibi, Groundwater potential zones identification using geoelectrical sounding and remote sensing in Wadi Touil plain, Northwestern Algeria, J. Afr. Earth Sci., 172 (2020) 104014, doi:10.1016/j.jafrearsci.2020.104014.
  14. F. Bahri, H. Saibi, Characterization, classification, and determination of drinkability of some Algerian thermal waters, Arabian J. Geosci., 4 (2011) 207–219.
  15. H. Saibi, F. Bahri A. Semar, Hydrochemistry and bacteriology of western and Saharan spring waters of Algeria, Arabian J. Geosci., 6 (2013) 665–677.
  16. J.E. Liggett, S. Talwar, Groundwater vulnerability assessments and integrated water resource management, Watershed Manage. Bull., 13 (2009) 18–29.
  17. V.M. Wagh, D.B. Panaskar, J.A. Jacobs, S.V. Mukate, A.A. Muley, A.K. Kadam, Influence of hydro-geochemical processes on groundwater quality through geostatistical techniques in Kadava River basin, Western India, Arabian J. Geosci., 12 (2019) 1–25, doi: 10.1007/s12517-018-4136-8.
  18. Z.A. Soomro, M.A. Khokhar, W. Hussain, M. Hussain, Drinking Water Quality Challenges in Pakistan, Pakistan Council of Research in Water Resources, Lahore, 2011, pp. 17–28.
  19. S.M.I. Shah, Stratigraphy of Pakistan, Memoir of Geological Survey of Pakistan, 2009.
  20. S.S. Asadi, P. Vuppala, M.A. Reddy, Remote sensing and GIS techniques for evaluation of groundwater quality in Municipal Corporation of Hyderabad (Zone-V), India, Int. J. Environ. Res. Public Health, 4 (2007) 45–52.
  21. B.A. Skubon, Groundwater Quality and GIS Investigation of a Shallow Sand Aquifer, Oak Opening Region, Geolog. Soc. America Abstracts Programs, North West Ohio, 2005.
  22. S. Yammani, Groundwater quality suitable zones identification: application of GIS, Chittoor area, Andhra Pradesh, India, Environ. Geol., 53 (2007) 201–210.
  23. A. Niaz, M.R. Khan, S. Mustafa, F. Hameed, Determination of aquifer properties and vulnerability mapping by using geoelectrical investigation of parts of Sub-Himalayas, Bhimber, Azad Jammu and Kashmir, Pakistan,
    Q. J. Eng. Geol. Hydrogeol., 49 (2016) 36–46.
  24. A. Sarangi, C.A. Madramootoo, P. Enright, Comparison of spatial variability techniques for runoff estimation from a Canadian watershed, Biosyst. Eng., 95 (2006) 295–308.
  25. B.U. Nisar, M.R. Khan, S. Khan, M. Farooq, M. Rizwan, K.A. Ahmed, S.S. Razzaq, A. Niaz, Quaternary Paleodepositional Environments in relation to Ground water occurrence in lesser Himalayan Region, Pak. J. Himalayan Earth Sci., 51 (2018) 99–112.
  26. A. Niaz, M.R. Khan, A. Asghar, S. Mustafa, F. Hameed, B.N. Umair, S. Khan, M.S. Mughal, M. Farooq, M. Rizwan, The study of aquifers potential and contamination based on geoelectric technique and chemical analysis in Mirpur Azad Jammu and Kashmir, Pak. J. Himalayan Earth Sci., 50 (2017) 60–73.
  27. E.O. Joshua, O.O. Odeyemi, O.O. Fawehinmi, Geoelectric investigation of the groundwater potential of Moniya Area, Ibadan. J. Geol. Min. Res., 3 (2011) 54–62.
  28. S.K. Pal, R.K. Majumdar, Determination for groundwater potential zones using iso-resistivity map in the alluvial areas of Munger District, Bihar, J. Earth Sci., 1 (2001) 16–26.
  29. A. Zohdy, V. Eaton, D. Mabey, Application of surface geophysics to groundwater investigations. Techniques of Water-Resources Investigation, US Geol. Surv., 2 (1974) 116–119.
  30. D.S. Parasnis, Principle of Applied Geophysics, 3rd ed., Chapman and Hall, London, 1979, p. 275.
  31. E. Martinelli, Groundwater exploration by geoelectrical methods in Southern Africa, Bull. Eng. Geol., 15 (1978) 113–124.
  32. J. Oseji, M. Asokhia, E. Okolie, Determination of groundwater potential in obiaruku and environs using surface geoelectric sounding, Environmentalist, 26 (2006) 301–308.
  33. M.H. Khalil, Hydro-geophysical configuration for the quaternary aquifer of Nuweiba alluvial fan, J. Eng. Geophys., 15 (2010) 77–90.
  34. P. Sikandar, A. Bakhsh, M. Arshad, T. Rana, The use of vertical electrical sounding resistivity method for the location of low salinity groundwater for irrigation in Chaj and Rachna Doabs, Environ. Earth Sci., 60 (2010) 1113–1129.
  35. J.P. Henriet, Direct application of the Dar Zarrouk parameters in groundwater surveys, Geophys. Prospect., 24 (1976) 344–353.
  36. C. Nwanko, L. Nwasu, G. Emujakporue, Determination of Dar Zarouk parameters for assessment of groundwater potential: case study of Imo State, south eastern Nigeria, J. Econ. Sustain. Dev., 2 (2011) 571.
  37. L. Slater, Near-surface electrical characterization of hydraulic conductivity from petro physical properties to aquifer geometries, Revised Surv. Geophys., 28 (2007) 167–169.
  38. K. Arumugam, Assessment of Groundwater Quality in Tirupur Region, Ph.D. Thesis (Unpublished), Anna University, Chennai, 2010.
  39. S.K. Kumar, A. Logeshkumaran, N.S. Magesh, P.S. Godson, N. Chandrasekar, Hydro-geochemistry and application of water quality index (WQI) for groundwater quality assessment, Anna Nagar, part of Chennai City, Tamil Nadu, India, Appl. Water Sci., 5 (2015) 335–343.
  40. C.E. Delisle, J.W. Schmidt, The Effects of Sulphur on Water and Aquatic Life in Canada, In: Sulphur and its Inorganic Derivatives in the Canadian Environment, NRCC No. 15015, Associate Committee on Sci. Criteria for Environ. Quality, National Research Council of Canada, Ottawa, 1977.
  41. L. Elango, R. Kannan, Rock–water interaction and its control on the chemical composition of groundwater, Dev. Environ. Sci., 5 (2007) 229–243.
  42. U.B. Nisar, M.J. Khan, M. Imran, M.R. Khan, M. Farooq, S.A. Ehsan, A. Ahmad, H.H. Qazi, N. Rashid, T. Manzoor, Groundwater investigations in the Hattar industrial estate and its vicinity, Haripur district, Pakistan: an integrated approach, Kuwait J. Sci., 48 (2021) 1, doi: 10.48129/kjs.v48i1.7820.
  43. H. Saibi, M. Mesbah, A.S. Moulla, A. Guendouz, S. Ehara, Principal component, chemical, bacteriological, and isotopic analyses of Oued-Souf groundwaters (Revised), Environ. Earth Sci., 75 (2016) 1–17.
  44. M. Djemai, H. Saibi, M. Mesbah, A. Robertson, Spatio-temporal evolution of the physico-chemical water characteristics of the Sebaou river valley (Great Kabylia, Algeria), J. Hydrol. Region Stud., 12 (2017) 33–49.
  45. F. Bahri, H. Saibi, Characterization, classification, bacteriological, and evaluation of groundwater from 24 wells in 6 departments of Algeria, Arabian J. Geosci., 5 (2012) 1449–1458.
  46. N. Darwesh, M. Allam, Q. Meng, A. Helfdhallah, N.S.M Ramzy, K. Kharrim, A.A. Al Maliki, D. Belghyti, Using Piper trilinear diagrams and principal component analysis to determine variation in hydrochemical faces and understand the evolution of groundwater in Sidi Slimane Region, Morocco, Egypt. J. Aquat. Biol. Fish., 23 (2019) 17–30.