Time-lapse Geological Assessment of Groundwater; A Case Study of Oghara Farmlands, Delta State, Nigeria

Authors

  • Anslem Ozobeme Azubike Department of Physics, University of Benin, Benin City, Edo State, Nigeria
  • Osisanya Olajuwon Wasiu Department of Applied GeophysicsFederal University of Petroleum Resources, Effurun, Delta State, Nigeria
  • Airen Osariere John Department of Physics, University of Benin, Benin City, Edo State, Nigeria
  • Ibitoye Taiwo Abel Department of Petroleum Engineering and Geosciences, Petroleum Training Institute, Effurun, Delta State, Nigeria
  • Saleh A. Saleh Department of Petroleum Engineering and Geosciences, Petroleum Training Institute, Effurun, Delta State, Nigeria

Keywords:

Migration, Date, heavy metal, pH, Fertilizer, Permissible

Abstract

The use of mineral fertilizers and nutrients is widely adopted in conventional agricultural practices, playing an essential role in maintaining optimal crop yields and improving overall quality. To aid farmers in effective fertilization and crop management strategies, non-invasive geophysical techniques can offer insights into the nutrient distribution within the soil. This study deemed it imperative to assess the physicochemical parameters and heavy metals (HM) present in the groundwater of the study area. A total of three groundwater samples and five soil samples were collected and tested for different heavy metals (HM) checked included iron (Fe), chromium (Cr), lead (Pb), copper (Cu), zinc (Zn), nickel (Ni), manganese (Mn), and cadmium (Cd). Recently, electrical resistivity tomography (ERT) has been used in local studies to measure changes in soil properties. Unfortunately, the signals we measure from the ground are mixed up because of changes in the soil both sideways and up and down, making it hard to figure out what each change is contributing. The analysis of groundwater revealed that, with the exception of a few parameters, groundwater samples fell below the WHO permissible limit. The soil's porosity, permeability, and the surrounding topography influence the migration rate. The rates of migration vary between the first and second locations. It has been found that if the vertical migration rate in the dry sand layer (which is about 13.7 meters thick based on drilling data) stays the same, the fertilizer contaminant will take about 0.5 years to reach the wet sandy layer below it in the first location, while in the second location, it will take around 1 year. Detailed calculations to determine the arrival time at the sandy layer have been conducted. Ultimately, it is imperative for the government to guarantee the installation of water purification plants during the process of borehole drilling, as this will help further decrease the existing salinity levels in the groundwater.

Author Biographies

  • Osisanya Olajuwon Wasiu , Department of Applied GeophysicsFederal University of Petroleum Resources, Effurun, Delta State, Nigeria

    Department of Applied Geophysics and Assistant lecturer

  • Airen Osariere John, Department of Physics, University of Benin, Benin City, Edo State, Nigeria

    supervisor and senior lecturer

  • Saleh A. Saleh, Department of Petroleum Engineering and Geosciences, Petroleum Training Institute, Effurun, Delta State, Nigeria

    5Department of Petroleum Engineering and Geosciences and lecturer

References

Aghamelu, O.P., Eyankware, M.O., Akakuru O.C., 2025. Geochemical characterization and risk implications of groundwater for irrigation and drinking around the agrarian metropolis of southeastern Nigeria. Sustainable Water Resources Management 11 (6), 133.

Abu-Hassanein, Z.S., Benson, C.H., Blotz, L.R., 1996. Electrical resistivity of compacted clays. Journal of Geotechnical Engineering 122, 397-406.

Ahmed, A., Hossain, M.S., Khan, M.S., Greenwood, K., Shishani, A., 2017. Moisture Variation in Expansive Subgrade through Field Instrumentation and Geophysical Testing. In Proceedings of the International Congress and Exhibition “Sustainable Civil Infrastructures: Innovative Infrastructure Geotechnology”, Sharm El Sheikh, Egypt, 15–19 July 2017; Springer: Cham, Switzerland, pp. 45-58.

Aizebeokhai, A.P., . 2010. 2D and 3D geoelectrical resistivity imaging: Theory and field design. Scientific Research and Essays 5 (23), 3592-3605.

Akinseye, V.O., Osisanya, W.O., Eyankware. M.O., Korode, I.A., Ibitoye, A.T., 2023. Application of second order geoelectric indices in determination of groundwater vulnerability in hard rock terrain in SW. Nigeria. Sustainable Water Resources Management 9, 169. https://doi.org/10.1007/s40899-023-00936-w.

Akpoborie, I.A., Aweto, K.E., Ohwoghere-Asuma, O., 2015. Urbanization and major ion hydrogeochemistry of the shallow aquifer at the Effurun-Warri metropolis, Nigeria. Environment and Pollution 4 (1), 37.

de Groot-Hedlin, C., Constable, S., 1990. Occam’s Inversion to Generate Smooth, Two-Dimensional Models from Magnetotelluric Data. Geophysics 55, 1613-1624. https://doi.org/10.1190/1.1442813.

Emmanuela, A.A., Wasiu, O.O., Eyankware M.O., 2024. Delineation of groundwater potential using electrical resistivity imaging techniques at Ibule Akure, Southwestern Nigeria. Malaysian Journal of Geosciences 8 (1), 01-09.

Ekwue, E., Bartholomew, J., 2011. Electrical conductivity of some soils in Trinidad as affected by density, water and peat content. Biosystem Engineering 108, 95-103.

Esi, E.O., Orisekpabor O.P., Eyankware, M.O., 2025. Integration of geophysical and radiological assessment of solid waste diposal impact on groundwater and human health in southern Nigeria. Geosystems and Geoenvironment 5 (1), 100425. https://doi.org/10.1016/j.geogeo.2025.100425.

Eyankware. M.O., Nnajieze, V.S., Aleke, C.G., 2018. Geochemical assessment of water quality for irrigation purpose, in abandoned limestone quarry pit at Nkalagu area, Southern Benue Trough Nigeria 77, 66. https://doi.org/10.1007/s12665-018-7232-x.

Eyankware. M.O., Effam, S.C., 2019. A preliminary assessment of hydrogeochemical quality of groundwater around rural communities of abandoned Nkalagu limestone quarry. SE Nigeria. Annals of Chemical Science Research 1 (5), ACSR.000522.2019. https://doi.org/10.31031/ACSR.2019.01.000522.

Eyankware. M.O., Omo-Irabor, O.O., 2019. An integrated approach to groundwater quality assessment in determining factors that influence the geochemistry and origin of sandstone aquifers, Southern Niger Delta Region of Nigeria. Malaysian Journal of Geosciences 3 (2), 23-32. https://doi.org/10.26480/mjg.02.2019.23.32.

Eyankware, M.O., Igwe, E.O., Ulakpa, R.O.E., Ogwah, C., 2020a. Achieving sustainable use and management of water resources for irrigation in Nigeria-Review. Journal of Environmental & Earth Sciences 2 (2), 47-55.

Eyankware. M.O., Ogwah, C., Ulakpa. R.O.E., 2020b. The study of sea water intrusion in coastal aquifer of Niger Delta Region, Nigeria. Middle-East Journal of Scientific Research 28 (4), 369-379.

Eyankware., M.O., Ephraim, B. E., 2021. A comprehensive review of water quality monitoring and assessment in Delta State, Southern Part of Nigeria. Journal of Environmental and Earth Sciences 3 (1), 16-28. https://doi.org/10.30564/jees.v3i1.2900.

Eyankware, M.O., Aleke, G., 2021. Geoelectric investigation to determine fracture zones and aquifer vulnerability in southern Benue Trough southeastern Nigeria. Arabian Journal of Geosciences 14, 2259. https://doi.org/10.1007/s12517-021-08542-w.

Eyankware. M.O., Obasi, P.N., 2021. A holistic review of heavy metals in water and soil in Ebonyi SE. Nigeria; with emphasis on its effects on human, aquatic organisms and plants. World News of Natural Science 38, 1-19.

Eyankware, M.O., Ogwah, C., Umayah, O.S., 2021. Integrated geophysical and hydrogeochemical characterization and assessment of groundwater vulnerability in Adum West Area of Benue State, Nigeria. Journal of Geophysical Research 65, 6588128. https://doi.org/10.30564/jgr.v3i3.3197.

Eyankware, M.O., Akakuru, C.O., Ulakpa, R.O.E., Eyankware, E.O., 2022a. Hydrogeochemical approach in the assessment of coastal aquifer for domestic, industrial, and agricultural utilities in Port Harcourt urban, southern Nigeria. International Journal of Energy and Water Resources 7, 401-419. https://doi.org/10.1007/s42108-022-00184-2.

Eyankware. M.O., Akakuru, C.O., Eyankware, E.O., 2022b. Hydrogeophysical delineation of aquifer vulnerability in parts of Nkalagu areas of Abakaliki, SE. Nigeria. Sustainable Water Resources Management 8, 39. https://doi.org/10.1007/s40899-022-00603-6.

Eyankware, M.O., Akakuru, O.C., Inoni, O.E., Osisanya, W.O., Ukor, K.P., Umuokoro, G., 2025a. Interpretation of hydrochemical data in selected parts of Warri, Southern Nigeria using health risk assessment and heavy

metal index. Discovery Nature 2 (3), 1-34. https://doi.org/10.54905/disssi.v2i3.e6dn3107.

Eyankware, M.O., Mba-Otike, M.N., Odesa, G.E., Chukwusa, F. O., Osisanya, W.O., Eyankware-Ulakpa, R.O., Akakuru, O.C., Komolafe, N.P., 2025b. Saline intrusion in Niger Delta coastal aquifers, drivers, hydrogeological dynamics and mitigation strategies. Discover Geoscience, 3, 150. https://doi.org/10.1007/s44288-025-00264-w.

Eyankware, M.O., Emudiaga, O.E., Ukor, K.P., Okudibie, E.J., 2026. Water bearing unit, not everywhere; Resistivity study of shallow aquifer around Patani Milieu, Niger delta region of Nigeria. Discovery Nature 3 (5), e2dn3159.

Giao, P., Chung, S., Kim, D., Tanaka, H., 2003. Electric imaging and laboratory resistivity testing for geotechnical investigation of Pusan clay deposits. Journal of Applied Geophysics 52, 157-175.

Ghorbani, A., Revil, A., Bonelli, S., Barde-Cabusson, S., Girolami, L., Nicoleau, F., Vaudelet, P., 2024. Occurrence of sand boils landside of a river dike during flooding: A geophysical perspective. Engineering Geology 329, 107403.

Hossain, M.S., Maganti, D., Hossain, J., 2010. Assessment of geo-hazard potential and site investigations using Resistivity Imaging. International Journal of Environmental Technology and Management 13, 116-129. https://doi.org/10.1504/IJETM.2010.034297.

Kalinski, R., Kelly, W., 1993. Estimating water content of soils from electrical resistivity. Geotechnical Testing Journal 16, 323-329.

Islami, N. Taib, S. Yusoff, I. Ghani A.A., 2011. Time lapse chemical fertilizer monitoring in agriculture sandy soil. International Journal of Environmental Science & Technology 8 (4), 765-780.

Islami, N., Irianti, M., Fakhruddin, F., Azhar, A., Nor M., 2020. Application of geoelectrical resistivity method for the assessment of shallow aquifer quality in landfill areas. Environmental Monitoring and Assessment 192 (9), 606.

Jabrane, O., Martínez-Pagán, P., Martínez-Segura, M.A., Alcalá, F.J., El Azzab, D., Vásconez-Maza, M.D., Charroud, M., 2023. Integration of Electrical Resistivity Tomography and Seismic Refraction Tomography to Investigate Subsiding Sinkholes in Karst Areas. Water 15, 2192.

Mahvi, A.H., Nouri, J., Babaei, A.A., Nabizadeh, N., 2005. Agricultural activities impact on groundwater nitrate pollution. International Journal of Environmental Science & Technology 2, 41-47. https://doi.org/10.1007/BF03325856.

Martínez-Pagán, P., Gómez-Ortiz, D., Martín-Crespo, T., Manteca, J., Rosique, M., 2013. The electrical resistivity tomography method in the detection of shallow mining cavities. A case study on the Victoria Cave, Cartagena (SE Spain). Engineering Geology 156, 1-10.

McCarter, W.J., 1984. The electrical resistivity characteristics of compacted clays. Geotechnique 34, 263-267.

Obire, O., Douglas, S.I., Chuku J.I., 2021. Evaluation of the Impact of Anthropogenic Activities on the Microbiological Quality of Azumini Odumanya Stream, Port Harcourt, Nigeria. International Journal of Current Microbiology and Applied Sciences 10 (07), 143-153. https://doi.org/10.20546/ijcmas.2021.1007.017.

Odesa, G.E., Okanigbuan P.N., Eyankware, M.O., NgoziChika, C.S., Oghenetega, E., 2025. Health risk assessm,ent of water resources within the lignite series of Obomkpa and environs, southern Nigeria. Journal of Contaminant Hydrology. https://doi.org/10.1016/j.jconhyd.2025.104665.

Ogwah, C., Eyankware, M.O., 2020. Investigation of Hydrogeochemical processes in groundwater resources located around abandoned Okpara coal mine, Enugu SE. Nigeria. Journal Clean Was 4 (1), 12-16. http://doi.org/10.26480/cleanwas.01.2020.12.16.

Okolo, C.M., Obasi P.N., Akpa, C., Eyankware M.O., Onwe I.M., Edene E.N., Nweke O.M., Ani C.C., Alieze I.V., Omeokachie A.I., Nworie C.D., 2025. Assessment of the lower drainage basin aquifers for domestic, industrial, and agricultural uses in Onitsha commercial area, Southern Nigeria using hydrochemical approach. Environment, Development and Sustainability 2025. https://doi.org/10.1007/s10668-025-06741-z.

Omo-Irabor, O.O., Eyankware. M.O., Ogwah, C., 2018. Integration of hydrogeochemical analytical methods and irrigation parameters in the evaluation of groundwater quality at Ibinta, Southern Benue Trough Nigeria. Journal of Scientific and Industrial Research 2 (1), 38-49.

Onwe, I.M., Eyankware. M.O., Obasi, P.N., Ifeanyichukwu, K.A., 2022. Hydrochemical and statistical approaches in the evaluation of groundwater quality for drinking and irrigation uses around Ezzangbo–Ngbo area, Southeastern Nigeria. Modeling Earth Systems and Environment 9, 413-429. https://doi.org/10.1007/s40808-022-01503-6.

Onwe, I.A. Obasi, Eyankware, M.O., Uchenna, O.L., 2024. An integration of hydrochemical data and stable isotopes in groundwater evaluation in Ngboejogu, Southern Benue Trough, Nigeria. Modeling Earth Systems and Environment 10, 7207-7223. https://doi.org/10.1007/s40808-024-02166-1.

Oseji, O.T., Egbai, J.C., Emuobonuvie, I.A., 2020. Aquifer vulnerability using geophysical and physiochemical methods in parts of Ethiope West Local Government Area of Delta State, Nigeria. Advances 10, 085209. https://doi.org/10.1063/5.0015357.

Osisanya, W.O., Agbalagba, E.O., Ife-, I.O., Agho, O., Eyankware, M.O., Iduseri, O.M., 2025. An in-depth study of heavy metals in soils around selected waste dumpsites in parts of southern Nigeria using heavy metal indices and multivariate statistical analysis. Global Journal of Pure and Applied Sciences 31, 735-750.

Power, C. Gerhard, J.I. Karaoulis, M., Tsourlos, P., Giannopoulos, A., 2014. Evaluating four-dimensional time-lapse electrical resistivity tomography for monitoring DNAPL source zone remediation. Journal of Contaminant Hydrology 162-163, 27-46. https://doi.org/10.1016/j.jconhyd.2014.04.004.

Samouëlian, A., Cousin, I., Tabbagh, A., Bruand, A., Richard, G., 2005. Electrical Resistivity Survey in Soil Science: A Review. Soil and Tillage Research 83, 173-193. https://doi.org/10.1016/j.still.2004.10.004.

Sasaki, Y., 1992. Resolution of Resistivity Tomography Inferred from Numerical Simulation. Geophysical Prospecting 40, 453-464. https://doi.org/10.1111/j.1365-2478.1992.tb00536.x.

Sehgal, M., Garg, A., Suresh, R., Dagar, P.,(2012. HM contamination in the Delhi segment of Yamuna basin. Environmental Monitoring Assessment 184, 1181-1196. https://doi.org/10.1007/s10661-011-2031-9.

Singh, V.K., Singh, K.P., Mohan, D., 2005. Status of heavy metals in water and bed sediments of River Gomti—a tributary of the Ganga River, India. Environmental Monitoring Assessment 105, 43-67.

Short, K.C., Stauble, A.J., 1967. Outline of geology of Niger Delta. American Association of Petroleum Geologists Bulletin 51, 761-779.

Tabbagh, A., Dabas, M., Hesse, A., Panissod, C., 2000. Soil resistivity: A non-invasive tool to map soil structure horizonation. Geoderma 97, 393-404.

Udo, R.K., 1970. Geographical Regions of Nigeria. Heinemann Educational Books, London.

Umayah, O.S., Eyankware, M.O., 2022. Aquifer evaluation in southern parts of Nigeria fromgeo-electrical derived parameters. World News of Natural Science 42, 28-43.

WHO, 2011. Guidelines for drinking water quality, 4th edn. NLM classifcation: WA 675, World Health Organization, Geneva, Switzerland, pp 307-433.

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Published

2026-04-30

Issue

Vol. 8 No. 1 (2026): IJESKA

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Copyright (c) 2026 Anslem Ozobeme Azubike , Osisanya Olajuwon Wasiu , Airen Osariere John, Ibitoye Taiwo Abel, Saleh A. Saleh

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