Vertical electrical sounding has been carried out in a coastal area in the southern part of Bangladesh to locate the groundwater aquifers containing fresh water. The Interpex1X1Dv3 computer program was used to process the field apparent resistivity data sets obtained from the vertical electrical sounding.  Geoelectric layers were identified in the context of resistivity and thickness from the vertical electrical sounding data. From the initial parameters layered model was achieved using the inversion technique. Correlation of the obtained layer model with a nearby lithologic log concludes the groundwater aquifer system of the area. From the electrical properties of the subsurface layers, water bearing layers were detected and characterized. Very fine sand geoelectric layer with a thickness varying from 20 to 143 meters is an upper aquifer and has 0.66–14.02 Ωm apparent resistivity value. Fine sand geoelectric layer with 0.21-5.99 Ωm apparent resistivity value is lower aquifer with maximum thickness ~250 meters. From the resistivity value, it is observed that the upper aquifer contains saline to brackish-fresh water while the resistivity value of the lower aquifer indicates that it contains saline water. The water quality of the upper zone varies geographically from the southern to the northern part in the investigated area. The water quality of the upper aquifer is fresh in the northern part of the study while lower aquifer contains saline water there.

Abd-Elhamid, H., and Javadi, A. (2011)A costeffective method to control seawater intrusion in Coastal aquifers. Water Resour. Manage. 25:2755–2780.

Alam, M., Alam, M.M., Curray, J., Chowdhury, R.M.L.R., and Gani, M.R. (2003) An overview of the sedimentary geology of the Bengal Basin in relation to the regional tectonic framework and basin-fill history. Sediment. Geol.155: 179–208.

Alam, M. Z., Boggs, L.C., Mitra, S. M., Haque, M.M., Halsey, J., Rokonuzzaman, M., Saha, B., and Moniruzzaman, M. (2017) Effect of salinity intrusion on food crops, livestock, and fish species at Kalapara Coastal Belt in Bangladesh.J. Food Qual. 1–23.

Basar, A. (2012) Water Security in Coastal Region of Bangladesh: Would Desalination be a Solution to the Vulnerable Communities of the Sundarbans? Bangladesh e-Journal of Sociology, 9(2): 31-39

Bataynch, A.T. (2006) Use of electrical resistivity methods for detecting subsurface fresh and saline water and delineating their interfacial configuration: a case study of the eastern Dead Sea coastal aquifers, Jordan.Hydrogeol. J. 14L 1277-1283.

BBS (2011) Patuakhali District Statistics, Govt. of the People’s Republic of Bangladesh.

BGS and DPHE (2001) Arsenic contamination of groundwater in Bangladesh. Final report, BGS tech. report WC/00/19:51.

DMB (2010) National plan for disaster management 2010–2015. Government of the People’s Republic of Bangladesh.

Huq, S., and Rabbani, G. (2011) Adaptation Technologies in Agriculture; The Economics of rice farming technology. Climate vulnerable areas of Bangladesh. 185-201.

Dola, S.S., Bahsar, K., Islam, M., Sarker, M.M.R. (2018) Hydrogeological classification and the correlation of groundwater chemistry with basin flow in the south-western part of Bangladesh. J. Bangladesh Acad. Sci., 42(1): 41-54.

DPHE (2006) Final Report on Development of Deep Aquifer Database and Preliminary Deep Aquifer Map (First Phase), Ground Water Circle, Department of Public Health Engineering, Local Government Division, Ministry of LGRD, and Cooperatives, Government of the People’s Republic of Bangladesh.

Ebraheem, A.M., Senosy, M.M., and Dahab, K.A. (1997) Geoelectrical and hydrogeochemical studies for delineating groundwater contamination due to saltwater intrusion in the northern part of the Nile Delta, Egypt. Ground Water 35(2): 216–222.

Huq, S., Karim, Z., Asaduzzaman, M. and Mahtab, F. (1999) Vulnerability and Adaptation to Climate
Change for Bangladesh.

Islam, M.N., Malak, M.A., and Islam, M.N. (2013) Community-based disaster risk and vulnerability models of a coastal municipality in Bangladesh. Nat. Hazards 69: 2083–2103.

Islam, S. M. D., (2014) Geoelectrical and Hydrogeochemical Studies for Delineating Seawater Intrusion in Coastal Aquifers of Kalapara Upazila, Patuakhali, Bangladesh.

Islam S. M. D., Majumder R. K., Uddin M. J., Khalil M. I., and Alam M. F. (2016) Hydrochemical Hydrochemical Characteristics and Quality Assessment of Groundwater in Patuakhali District, Southern Coastal Region of Bangladesh. Expo Health 9: 43-60. Islam, S.N. (2016) Deltaic floodplains development and wetland ecosystems management in the Ganges–Brahmaputra–Meghna Rivers Delta in Bangladesh. Sustain. Water Resour. Manag. 2, 237–256. Interpex (2011) 1X1Dv3, Interpex Limited.Golden Colorado, USA.

Lee, S., Kim, K., Ko, I., Lee, S., and Hwang, H. (2002) Geochemical and geophysical monitoring of saline water intrusion in Korean paddy fieldsEnviron. Geochem. Health 24: 277-291.

Mario, Z., Joan, B., Rogelio, L., Xavier, M.P. (2011) Electrical methods (VES and ERT) for identifying, mapping, and monitoring different saline domains in a coastal plain region (Alt Emporda, Northern Spain). J. Hydrol., 409: 407-422.

Mahtab, M.H., Zahid, A. (2018) Coastal surface water suitability analysis for irrigation in Bangladesh. Appl. Water Sci., 8: 28.

Mahmuduzzaman, M., Ahmed, Z.U., Nuruzzaman, A. K. M., Ahmed, F. R. S. (2014) Causes of Salinity Intrusion in Coastal Belt of Bangladesh. International Journal of Plant Research. 4(4A): 8–13.

MoA (1999). National agriculture policy, Ministry of Agriculture, Government of the People’s Republic of Bangladesh.

Morrow, F.J., Ingham, M.R., and McConchie, J.A. (2010) Monitoring of tidal influences on the saline interface using resistivity traversing and cross borehole resistivity tomography. J. Hydrol. 389: 69-77.

Paul, B. K., and Rashid, H. (2017) Salinity Intrusion and Impacts. Climatic Hazards in Coastal Bangladesh. Chapter 5, 153-182.

Roy, A. B., and Chatterjee, A. (2015) Tectonic framework and evolutionary history of the Bengal Basin in the Indian subcontinent. Current Science, 109(2): 271-279.

Sakamoto, M. (2017) Saline Drinking Water and Salt in Diet: An Approximate Picture of the Situation in a Coastal Area of Southeastern Bangladesh. Int. J. Disaster Risk Sci. 8: 109-120.

Shamsudduha, M., Chandler, R. E., Taylor, R.G., Ahmed, K.M. (2009) Recent trends in groundwater levels in a highly seasonal hydrological system: the Ganges-Brahmaputra-Meghna Delta. Hydrol. Earth Syst. Sci.13, 2373–2385.

Sherena, Ravikumar, V. (2018) Seawater Intrusion Signatures in Groundwater Quality of Coastal Zone. Journal of Soil Salinity and Water Quality 10(2): 1-7.

Stamatis, G., and Voudouris, K. (2003) Marine and human activity influences on the groundwater quality of southern Korinthos area (Greece). Hydrol. Process. 17: 2327–2345.

USEPA, (2016) Environmental Geophysics. U.S. Environmental Protection Agency Web Archive

Wilson, S.R., Ingham, M., and McConchie, J.A. (2006) The applicability of earth resistivity methods for saline interface definition.J. Hydrol. 316(14): 301-312.

Woobaidullah, A.S.M., Ahmed, K.M., Karmaker, U., Biswas, D., and Arafin, K.S. (2006) Geoelectric Survey in the Evaluation of Hydrogeological condition in the Coastal Area of KalaparaUpazila, Patuakhali District, Bangladesh. Dhaka Univ. J. Sci., 54 (1): 115-119.

Zohdy, A.A.R., Eaton, G.P., and Mabey, D.R. (1974) Application of surface geophysics to groundwater investigation. Techniques of Water Resources Investigations, U.S. Geological Survey. p. 116..