Abdulrazzaq Z.T., Agbasi O.E., Aziz N.A. & Etuk S.E., 2020, Identification of potential groundwater locations using geophysical data and fuzzy gamma operator model in Imo, Southeastern Nigeria. Applied Water Science 10(8),188.

Adewumi R., Agbasi O. & Mayowa A., 2023, Investigating groundwater potential in northeastern basement complexes: A Pulka case study using geospatial and geo-electrical techniques. HydroResearch 6: 73–88. http://dx.doi.org/10.1016/j.hydres.2023.02.003

Agbasi O.E. & Etuk S.E., 2016, Hydro-Geoelectric Study of Aquifer Potential in Parts of Ikot Abasi Local Government Area, Akwa Ibom State, Using Electrical Resistivity Soundings. International Journal of Geology and Earth Sciences 2(4): 43–54.

Agbasi O.E., Aziz N.A., Abdulrazzaq Z.T. & Etuk S.E., 2019, Integrated Geophysical Data and GIS Technique to Forecast the Potential Groundwater Locations in Part of South Eastern Nigeria. Iraqi Journal of Science 60(5): 1013–1022. http://dx.doi.org/10.24996/ijs.2019.60.5.11

Ahmed S., Tanko A.I., Eduvie M.O. & Ahmed M., 2017, Assessment of Groundwater Vulnerability in Kaduna Metropolis, Northwest Nigeria. Journal of Geoscience and Environment Protection 5: 97–115.

Akaolisa C.C.Z., Agbasi O., Okeke O.C. & Okechukwu S, 2022a, An assessment of the groundwater potentials of the farm with preliminary geophysical method and grain size analysis prior to the drilling of boreholes. HydroResearch 5: 85–98. http://dx.doi.org/10.1016/j.hydres.2022.09.001

Akaolisa C.C.Z., Ibeneche W., Ibeneme S., Agbasi O. & Okechukwu S., 2022b, Enhance groundwater quality assessment using integrated vertical electrical sounding and physio-chemical analyses in Umuahia South, Nigeria. International Journal of Energy and Water Resources. http://dx.doi.org/10.1007/s42108-022-00219-8

Aladeboyeje A.I., Coker J.O., Agbasi O.E. & Inyang N.J., 2021, Integrated hydrogeophysical assessment of groundwater potential in the Ogun drainage basin, Nigeria. International Journal of Energy and Water Resources 5(4): 461–475. http://dx.doi.org/10.1007/s42108-021-00121-9

Aller L., Bennet T., Leher J.H., Petty R.J. & Hackett G., 1987, DRASTIC: A standardized system for evaluating ground water pollution potential using hydrogeological settings. EPA 600/2-87-035, 622 pp.

Aller L., Bennett T., Lehr J.H. & Petty R.J., 1985, DRASTIC: A standardized system for evaluating groundwater pollution potential using hydrogeologic settings. Ada, OK: United States Environmental Protection Agency, Robert S. Kerr Environmental Research laboratory. EPA/600/2-85/0108

Amos-Uhegbu, C., Igboekwe, M. U., Chukwu, G. U., Okengwu, K. O., & Eke, T. K. (2012). Hydrogeophysical Delineation and Hydrogeochemical Characterization of the Aquifer Systems in Umuahia-South Area, Southern Nigeria. Current Journal of Applied Science and Technology, 2(4), 406–432. https://doi.org/10.9734/BJAST/2012/1645

Anomohanran O., 2011, Determination of groundwater potential in Asaba Nigeria using surface geoelectric sounding. International Journal of the Physical Sciences 6(33): 7651–7656.

Anomohanran O., 2013, Hydrogeophysical and Hydrogeological Investigations of Groundwater Resources in Delta Central, Nigeria. Journal of Taibah University for Science 9: 57–68.

Asonye C.C., Okolie N.P., Okenwa E.E. & Iwuanyanwu U.G., 2007, Some physiochemical characteristics and heavy metal profiles of Nigerian rivers, streams and wetland. African Journal of Biotechnology 6(5): 617–624.

Casas A., Himi M., Diaz Y. & Pinto V., 2008, Assessing aquifer vulnerability to pollutants by electrical resistivity tomography (ERT) at a nitrate vulnerable zone in NE Spain. Environmental Geology 54: 515–520.

Chowdhury A., Jha, M.K. & Chowdary V.M., 2010, Delineation of groundwater recharge zones and identification of artificial recharge sites in West Medinipur District, West Bengal using RS, GIS and MCDM techniques. Journal of Environmental Earth Sciences 59(6): 1209–1222.

Edet A.E. & Okereke C.S., 2002, Delineation of shallow groundwater aquifers in the Coastal Plain Sands area (Southern Nigeria) using surface resistivity and hydrogeological data. Journal of African Earth Sciences 35: 433–443. http://dx.doi.org/10.1016/S0899-5362(02)00148-3

Ekwe A.C. & Opara A.I., 2012, Aquifer transmissivity from surface geo-electrical data: A case study of owerri and environs, southeastern Nigeria. Journal of the Geological Society of India 80: 123–128.

Emenike E.A., 2001, Geophysical exploration for groundwater in a Sedimentary Environment. A case study from Nanka over Nanka Formation in Anambra Basin, Southeastern Nigeria. Global Journal of Pure and Applied Sciences 7(1): 97–102.

Engel B., Navulur K., Cooper B. & Hahn L., 1996, Estimating groundwater vulnerability to non-point source pollution from nitrates and pesticides on a regional scale. HydroGIS 96: Application of GIS in Hydrology and Water Resources Management, IAHS Publ. 235: 521–526.

George N.J., Agbasi O.E., Umoh J.A., Ekanem A.M., Ejepu J.S., Thomas J.E. & Udoinyang I.E., 2022, Contribution of electrical prospecting and spatiotemporal variations to groundwater potential in coastal hydro-sand beds: a case study of Akwa Ibom State, Southern Nigeria. Acta Geophysica. http://dx.doi.org/10.1007/s11600-022-00994-2

Ibe K.M., Nwankwor G.I. & Onyekuru S.O., 2007, Assessment of ground water vulnerability and its application to the development of protection strategy for the water supply aquifer Owerri, South-eastern Nigeria. Journal of Environmental Monitoring and Assessment 67: 323–360.

Ibe Sr K. & Sowa A.H.O., 2002, Hydrology of part of the Oramiriukwa River basin, southeast of Owerri, Imo State, Nigeria. Hydrogeology Journal 10(4): 509–521. http://dx.doi.org/10.1007/s10040-002-0207-7

Ibuot J.C., Aka M.U., Inyang N.J. & Agbasi O.E., 2022, Georesistivity and physicochemical evaluation of hydrogeologic units in parts of Akwa Ibom State, Nigeria. International Journal of Energy and Water Resources. http://dx.doi.org/10.1007/s42108-022-00191-3

Igboekwe M.U. & Achi, N.J., 2011, Finite Difference Method of Modelling Groundwater Flow. Journal of Water Resource and Protection 3: 192–198. http://dx.doi.org/10.4236/jwarp.2011.33025

Igboekwe M.U. & Udoinyang I.E., 2011, Modelling of suspended particulate matter by Kwa-Ibo River, Umudike, Soutteastern Nigeria.

Implications for pollutant dispersion. International Journal of Water Resources and Environmental Engineering 3: 109–116. https://api.semanticscholar.org/CorpusID:202588567

Kumar P., Thakur P.K., Bansod B.K.S. & Debnath S.K., 2016, Assessment of the effectiveness of DRASTIC in predicting the vulnerability of groundwater to contamination: A case study from Fatehgarh Sahib District in Punjab, India. Environmental Earth Science 75, 879. https://doi.org/10.1007/s12665-016-5712-4

Lawrence A.O. & Ojo T.A., 2012, The use of combined geophysical survey methods for groundwater prospecting in a typical basement complex terrain: case study of Ado-Ekiti Southwest Nigeria. Research Journal in Engineering and Applied Sciences 1(6): 362–376.

Nganje T.N., Hursthouse A.S., Edet A., Stirling D. & Adamu C.I., 2017, Hydrochemistry of surface water and groundwater in the shale bedrock, Cross River Basin and Niger Delta Region, Nigeria. Applied Water Science 7: 961–985.

Nwachukwu M.A., Feng H. & Alinnor J., 2010a, Assessment of heavy metal pollution in soil and their implications within and around mechanic villages. International Journal of Environmental Science and Technology 7(2): 347–358.

Nwachukwu M.A., Huan F. & Ophori D., 2010c, Groundwater flow model and particle track analysis for selecting water quality monitoring well sites, and soil sampling profiles. Journal of Spatial Hydrology 10(1): 1–14.

Nwachukwu M.A., Huan F., Maureen I.A. & Umunna F.U., 2010b, The causes and the control of selective pollution of shallow wells by coliform bacteria, Imo River Basin Nigeria. Water Quality Exposition Health 2: 75–84.

Nwosu L.I., Ekine A.S. & Nwankwo C.N., 2013, Geoelectric survey for mapping groundwater flow pattern in Okigwe District, Southeastern Nigeria. British Journal of Applied Sciences and Technology 3(3): 482–500.

Prasad K. & Shukla J.P., 2014, Assessment of groundwater vulnerability using GIS-based DRASTIC technology for the basaltic aquifer of Burhner watershed, Mohgaon block, Mandla (India). Current Science 107(10): 1649–1656.

Saha D. & Alam F., 2014, Groundwater vulnerability assessment using DRASTIC and Pesticide DRASTIC models in intense agriculture area of the Gangetic plains. IndianEnvironmental Monitoring and Assessment 186: 8741–8763.

Shahsavari H., Arefi H., Farahani M.D., Pirbasti M.A., Shobairi S.O.R., 2024, Mapping Groundwater Resource using Multispectral Sentinel 2 and Fuzzy Logic method, Case Study: Salafchegan, Qom, Iran. Ecological Questions 35(2): 1-26. http://dx.doi.org/10.12775/EQ.2024.014

Soupios P., Kouli M., Vallianatos F., Vafidis A. & Stavroulakis G., 2007, Estimation of aquifer parameters from surficial geophysical methods. A case study of Keritis Basin in Crete. Journal of Hydrology 338: 122–131.

Stigter T.Y., Ribeiro L. & Dill A., 2006, Evaluation of an intrinsic and a specific vulnerability assessment method in comparison with groundwater stalinization and nitrate contamination levels in two agricultural regions in the South of Portugal. Hydrological

Tirkey K., Gorai A.K. & Iqbal K., 2013, AHP-GIS based DRASTIC model for groundwater vulnerability to pollution assessment: A case study of Hazaribag district, Jharkhand, India. International Journal of Environmental Protection 2(3): 20–31.

United Nations Environmental Programe (UNEP), 2002, Global environmental outlook (GEO-3), Nairobi, 43 pp.