GEOPHYSICS ELECTRICAL CHARACTERIZATION FOR IDENTIFICATION OF SEAWATER INTRUSION IN THE COASTAL AREA OF PAPAR, SABAH

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Hardianshah Saleh1, Siam Jia Quan2, Muhammad Jaya Padriyamzah Bin Abdul Hamid3 

 

1Faculty Science and Natural Resources, Universiti Malaysia Sabah.

2Faculty of Science and Computer Informatic, Universiti Teknologi PETRONAS.

3Wullesdorf Resources Sdn Bhd.

ABSTRACT. Seawater intrusion is known to be a major problem that influences the quality of groundwater within coastal regions globally. The groundwater table within the coastal area is usually close to the ground surface due to low topography or human development activities such as land reclamation and man-made drainage systems that keep the water table at constant low level. Electrical resistivity method is one of the geophysical methods that has been extensively used to investigate seawater intrusion due to the high electrical conductivity contrast produced by saline water. Papar, Sabah is located at the west coastal region of Sabah and is generally formed by Crocker formation and Quaternary alluvium. The sedimentary rock of Crocker Formation mainly consists of thick sandstone unit, interbedded sandstone, siltstone and shale unit and shale unit. A total of Five 2D electrical resistivity imaging (ERI) methods were carried to image and model the subsurface within the research area to investigate the possibility of seawater intrusion. The ERI results are also supported by four groundwater samples and detailed lithologies from the borehole. Interpretation of the results divided the research area into three main zones of seawater intrusion potentials. Zone 1 is considered the highest potential of seawater intrusion, Zone 2 interpreted as potential extended zone or mixing zones between seawater and fresh water and finally Zone 3 did not indicate any low resistivity or potential of seawater intrusion. The seawater intrusion map produced from this research initiated and divided the potential zones based on the occurrence of seawater in the subsurface.

KEYWORDS. Geophysics, seawater intrusion, groundwater.

 

REFERENCES

  • Adegoke, J.A., Egbeyele, G. & Akinyemi, O.D. 2016. Effect of CEC of clay on thermal conductivity. Malaysian Journal of Science, Vol. 35 (2), Pp. 107-116. 
  • Al-Ajmi, Hussain & Hinderer, Matthias & Keller, Martin & Rausch, Randolf & Blum, Philipp & Bohnsack, Daniel. 2010. The Role of Outcrop Analogue Studies for the Characterization of Aquifer Properties. International Journal of Water Resources and Arid Environments. 1(1): 48-54, 2011ISSN 2079-7079
  • Azfar Mohamed, Abdul Hadi Abd Rahman & Mohd Suhaili Ismail. 2016. Sedimentary Facies of the West Crocker Formation North Kota Kinabalu-Tuaran Area, Sabah, Malaysia. IOP Conf. Ser.: Earth Environ. Sci30 012004
  • Basri, Kasbi & Wahab, Norhaliza & Abu Talib, Mohd Khaidir & Zainorabidin, Adnan. (2019). Sub-surface Profiling Using Electrical Resistivity Tomography (ERT) with Complement from Peat Sampler. Civil Engineering and Architecture7. 7-18. 10.13189/cea.2019.071402.
  • Chafouq, D.; Mandour, A.E.; Elgettafi, M.; Himi, M.; Bengamra, S.; Lagfid, Y.; Casas, A. 2016. Assessing of saltwater intrusion in Ghiz-Nekor aquifer (North Morocco) using electrical resistivity tomography. Near Surf. Geosci, Pp.1–6
  • Carrera, J., Hidalgo, J. J., Slooten, L. J., & V zquez‐Su, E. 2010. Computational and conceptual issues in the calibration of seawater intrusion models. Hydrogeology Journal18: 131-145.
  • Collenette, P. 1958. The Geology and Mineral Resources of the Jesselton- Kota Kinabalu Area, North Borneo. W.J.Chater, Government Printer.
  • Duque, C., Calvache, M. L., Pedrera, A., Rosalees, W. M. & Chicano, M.L. 2008. Combined time domain electromagnetic soundings and gravimetry to determine marine intrusion in a detrital coastal aquifer (Southern Spain). Journal of Hydrology, 536-547.
  • EPA. 2014. Sediments. In Water: Pollution Prevention & Control. Retrieved from http://water.epa.gov/polwaste/sediments/).
  • Fitterman, D.V., Stewart. M.T. 1986. Transient electromagnetic sounding for groundwater. Geophysics51(4): 995-1005.
  • Giambastiani BMS, Macciocca VR, Molducci M, Antonellini M. Factors Affecting Water Drainage Long-Time Series in the Salinized Low-Lying Coastal Area of Ravenna (Italy). Water. 2020; 12(1):256. https://doi.org/10.3390/w12010256.
  • Green T.R. 2016. Linking Climate Change and Groundwater. In: Jakeman A.J., Barreteau O., Hunt R.J., Rinaudo JD., Ross A. (eds) Integrated Groundwater Management.
  • Griffiths, D. and R. Barker, 1993. Two-dimensional resistivity imaging and modelling in areas of complex geology. Journal of applied Geophysics, 1993. 29(3-4): p. 211-226.
  • Griggs, G. & Reguero, B.G. 2021. Coastal Adaptation to Climate Change and Sea-Level Rise. Water13, 2151. https://doi.org/10.3390/w13162151
  • Hardianshah, S. & Abdul Rahim, S. 2013. Geo-electrical resistivity characterization of sedimentary rocks in dent peninsular, lahad datu, sabah. Borneo Science32.
  • Hickin, E. J. (Ed.). 1995. River Geomorphology. Chichester: Wiley.
  • Jacobson, G. 1970. Gunong Kinabalu area, Sabah, Malaysia. Geological Survey Malaysia. Report 8.
  • Jain C.K. 2011. Salinity. In: Singh V.P., Singh P., Haritashya U.K. (eds) Encyclopedia of Snow, Ice and Glaciers. Encyclopedia of Earth Sciences Series. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-2642-2_461
  • Jiao, J., & Post, V. 2019. Impact of Land Reclamation on Coastal Groundwater Systems. In Coastal Hydrogeology (pp. 255-282). Cambridge: Cambridge University Press. doi:10.1017/9781139344142.009.
  • Kanagaraj G, Elango L, Sridhar SGD and Gowrisankar G. 2018. Environmental Science and Pollution Research25. 8989. 
  • Khublaryan, M.G., A.P. Frolov, and I.O. Yushmanov. 2008. Seawater intrusion into coastal aquifers. Water Resources35(3): 274–86.
  • Lam, Y., Winch, P.J., Nizame, F.A. Broaduss-Shea, E.T., Harun, M.G.D & Surkan, P.J. 2021. Salinity and food security in southwest coastal Bangladesh: impacts on household food production and strategies for adaptation. Food Sec2021https://doi.org/10.1007/s12571-021-01177-5.
  • Lambiase, J.J., Tzong, T.Y., William, A.G., Bidgood, M.D., Brenac, P., and Cullen, A.B., 2008, The West Crocker formation of northwest Borneo: A Paleogene accretionary prism, ln Draut, A.E., Clift, p.D., und Scholl, D.W., eds., Formation and Applications of the Sedimentary Record in Arc Collision Zones: Geological Society of America Special paper 436, p. l7 l-184, doi: 1 0.1 1 30/2008.2436(08). 
  • Lee, Jin-Yong & Song, Sung-Ho. 2007. Evaluation of groundwater quality in coastal areas: Implications for sustainable agriculture. Environmental Geology52. 1231-1242. 10.1007/s00254-006-0560-2.
  • Loke, M., 1992. Electrical imaging surveys for environmental and engineering studies. A practical guide to 2-D and 3-D surveys.
  • Long, M., Donohue, S., L’Heureux, J-S., Solberg, I-L., Rønning, J-S, Limacher, R., O’Connor, P., Sauvin, G., Rømoen, M. and Lecomte, I. 2012. Relationship between electrical resistivity and basic geotechnical parameters for marine clays. Canada Geotech. J. Vol. 49, Pp.1–11. 
  • Majeed Faisal, Shariff A.K. Omang & Sanudin HJ. Tahir. 1994. Geology of Kota Kinabalu and its implications to groundwater potential. Bulletin Geol. Soc. Malaysia38, 11-20.
  • McNeill J. D. 1980. Survey Interpretation Techniques. Geonics, Ltd., Misissauga, Canada, Technical Note TN-5.
  • Michael, H. A., Russoniello, C. J., & Byron, L. A. 2013. Global assessment of vulnerability to sea‐level rise in topography‐limited and recharge‐limited coastal groundwater systems. Water Resources Research49: 2228-2240. 
  • Miller, G.T. 2000. Living in the Environment, Brooks/Cole Publishing Company, Pacific Grove. Haines, Skyring, Stephens, Papworth (2001) Managing Lake Wollumboola’s Odour Problem. Proc. 11th NSW Coastal Conference, Newcastle 13-16 November 2001.
  • Mohd. Kamal. 2011. Kimanis power plant field subsurface exploration log. STL Geotechnical Engineering Sdn. Bhd. Unpublished report.
  • Moser, S. C., M. A. Davidson, P. Kirshen, P. Mulvaney, J. F. Murley, J. E. Neumann, L. Petes, and D. Reed, 2014: Ch. 25: Coastal Zone Development and Ecosystems. Climate Change Impacts in the United States: The Third National Climate As­sessment, J. M. Melillo, Terese (T.C.) Richmond, and G. W. Yohe, Eds., U.S. Global Change Research Program,579-618. Springer,Cham. 
  • Musta, B., Asat, M.A., Ling, S.Y. & Saleh, H. 2022. Geophysical Investigation and Geochemical Study of Sediment along the Coastal Area in Kota Belud Sabah, Malaysia. Journal of Physics: Conference Series2165 (1).
  • Nawal Alfarrah and Kristine Walraevens, 2017. Groundwater Overexploitation and Seawater Intrusion in Coastal Areas of Arid and Semi-Arid Regions. Water10, 143; doi:10.3390/w10020143.
  • Nassir, A.S.S. Loke, M.H. Lee, C.Y & Nawawi, M.N.M. 2000. Salt-water intrusion mapping by geoelectrical imaging surveys. Geophys. Prospect, Vol. 48, 647–661.
  • Norzaida Abas, Zalina Mohd Daud, Norazizi Mohamed & Syafrina Abdul Halim, 2017. Climate change impact on coastal communities in Malaysia. Journal of Advanced Research Design33. 1-7.
  • Ohrel, R. and Register, K. 2006. Volunteer Estuary Monitoring: A Methods Manual. U.S. Environmental Protection Agency (EPA), Office of Wetlands, Oceans and Watersheds, The Ocean Conservancy.
  • Radke, L.C. 2002. Water allocation and critical flows: potential ionic impacts on estuarine organisms. Proceedings of Coast to Coast 2002 – “Source to Sea”, Tweed Heads, pp. 367-370.
  • Song, S.H.; Lee, J.Y.; Park, N. 2007. Use of vertical electrical soundings to delineate seawater intrusion in a coastal area of Byunsan, Korea. Environ. Geol, Vol. 52, Pp. 1207–1219
  • Stewart. M.T. 1982. Evaluation of Electromagnetic Methods for Rapid Mapping of Salt-Water Interfaces in Coastal Aquifers. Groundwater20 (5): 538-545. 
  • Sudaryanto and Wilda Naily. 2018. Ratio of Major Ions in Groundwater to Determine Saltwater Intrusion in Coastal Areas. IOP Conf. Ser.: Earth Environ. Sci118 012021.
  • Tol, R.S.J. 2009. Economics of Sea Level Rise, Editor(s): John H. Steele, Encyclopedia of Ocean Sciences (Second Edition), Academic Press, Pages 197-200, ISBN 9780123744739, https://doi.org/10.1016/B978-012374473-9.00774-8.
  • Van Biersel, T.P., D.A. Carlson, and L.R. Milner. 2007. Impact of hurricane storm surges on the groundwater resources. Environ Geol, 53: 813–26. 
  • Zakiyah Ainul Kamal, Mohd Syakir Sulaiman, Muhammad Khairul Hakim, Thilageswaran, Anis Syahira, Zahidi Hamzah and Mohammad Muqtada Ali Khan. 2020. Investigation of Seawater Intrusion in Coastal Aquifers of Kelantan, Malaysia using Geophysical and Hydrochemical Techniques. IOP Conf. Ser.: Earth Environ. Sci. 549 012018.

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