Hydrochemical study of shallow ground water in Ikot Abasi Coastal Aquifer
Keywords:
Coastal aquifer, coastal plain sands, Groundwater, hydrochemical study, Ikot Abasi Coastal aquiferAbstract
Communication in Physical Sciences, 2021, 7(3):218-228
Authors: Usoro M. Etesin and Iniemem J. Inim
Received 14 April 2021/Accepted 27 September 2021
A hydrochemical study of shallow groundwater in Ikot Abasi coastal aquifer, Niger Delta, Nigeria, was undertaken, to assess the impact of incidences of oil bunkering, crude oil refining activities, burning of natural gas for power generation and aluminum smelting activities. Six groundwater samples were collected from existing boreholes at different stations, for dry and wet seasons respectively. The water samples were analyzed for temperature, pH, cations (Ca2+, Na+, K+ and Mg2+) , anions (chloride, sulphate, nitrate and bicarbonate ), total dissolved solids (TDS), electrical conductivity (EC), salinity, alkalinity and total hardness , bicarbonate (HCO3-) and alkalinity, using standard analytical procedures by American Public Health Association. To establish the water types in the study area, the test results acquired for exchangeable cations and nutrients were subjected to Piper Plot, Durov Plot, and Gandha Plot for two seasons. The Piper Plot developed from experimental data revealed that water facies in Ikot Abasi aquifer are confined to only two types, with the majority of the samples having 67 percent plotted in the Ca-Mg-Cl water type, while 23 percent of the samples showed Na –Cl water type, which suggests freshness of the water with minor contribution from saline contribution. However, the Chandha plot for the groundwater indicated that within the study area 66.6 percent of the samples plot are within subfields-5, representing Ca2+ - Mg2+ - HCO3- water type, while 33 percent were of the samples plot within subfield -4, which is an indication of the presence of a significant concentration of acidic ions over weak anions, signifying strong acidic anions in the water exceeding weak acidic anions. Also, the observed pattern for the results of the Durov plot reveals that 66 percent of the samples plot are in the reverse ion exchange zone and therefore suggest the occurrence of inverse /reverse ion exchange process occurring, due to due the direct exchange of calcium ion and magnesium ions from the aquifer matrix in addition to sodium and potassium ions from the groundwater. While 33 percent of samples plot along the dissolution or mixing line. Based on the Lloyd and Heathcoat classification, the result can be aligned to recent fresh recharged of the water characterized by simple dissolution or mixing without the domination of major ions, and can be attributed to fresh recent recharged water exhibiting simple dissolution or mixing with no dominant major anions and cations. In spite of the shallow depth of the aquifer in the study area, there is no observed contamination of the water. Although the aquifer in Ikot Abasi has shallow depths of between 1.8m to 8.4 m, the concentrations of lead, cadmium, mercury, arsenic, zinc, and manganese are below the permissible limits of 0.05 mg/L, except iron content which has values above the permissible limit of 0.3 mg/l. The waters have mean salinity of 0.01 %, indicating no saltwater intrusion even though the study area is coastal. The calculated mean pollution index also suggests the absence of contamination from anthropogenic activities. The distribution of major anions, cations, and occurrence of different hydrochemical facies suggest that the composition of the groundwater is significantly influenced by water-rock interactions.
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References
Adams, S., Titus, R., Pietersenb, K., Tredouxc, G. & Harris, C. (2001) Hydrochemical characteristics of aquifers near Sutherland in the Western Karoo. South African Journal of Hydrology, 241, pp. 91-103.
Olalekan, A., Bashir, A. & Kasimu A. (2015). Physio-chemical characteristics of borehole water qualitinGassol Taraba State, Nigeria. African Journal of Environmental Science and Technology. 9, 2, pp. 143-154.
Akankpo, A. O. & Igbokwe, M. U. (2011). Monitoring groundwater contamination using surface electrical resistivity and geochemical methods. Journals of Water Resources and Protection, 3, 5, pp. 318-324.
American Groundwater Trust. The ABC of
Aquifers.http//www.tafths.org/ourpages/anto/2012/1/19/46927603/abcofaquifers.
APHA, AWWA, WEF. (2005) Standard Methods for the Examination of Water and Waste Waters. 21st Edition. American Public Health Association. USA.
Atakpo E. (2009). Delineation of underlying aquifer formation in the oil-producing community of Uzere, Isoko South local government area Delta State Nigerian Journal of Science and Environment, 8, pp. 121-131, 2009.
Baswinkel K. A. (2000). Information Note. International groundwater resources Assessment Center (IGRAC). Netherlands Institute of Applied Geosciences. The Netherlands.
Bhattachanya, P., Chatterjee, D. & Jacks, G. (1997). Occurrence of Arsenic Contaminated ground Water in Alluvial Aquifers from Delta Plains, Eastern India; options for safe drinking water supply. International Journal of Water Resources Development. 13, 1, pp. 79-92.
Chen, J., Wang, Y. & Zhang, H. (2006). Overview on the studies of nitrate pollution in groundwater. Progress in Geography, 25, 1, pp. 34–44
Dahunsi S. O., Owamah, H. I., Ayandiran, T. A. & Oranusi, S. U. (2014). Drinking water quality and public health of selected Towns in Southwestern Nigeria. Water Quality Exposure and Health. Springer
Domènech, L. & Saurí, D. (2011). A comparative appraisal of the use of rainwater harvesting in single and multifamily buildings of the Metropolitan Area of Barcelona Spain): social experience, drinking water savings, and economic costs. Journal of Clean Production, 19, pp. 598–608.
Eddy, N. O., Udoh, C. O. & Ukpong, I. J. (2004). Heavy metals in the sediment of the Cross River Estuary at Oron, South Eastern Nigeria. African Journal of Environmental Pollution and Health, 3, 1, pp. 6-10.
Enemugwem, J. H. (2009). Oil pollution and Eastern Obolo Human Ecology, 1957-2007. African Research, Review, 3, 1, pp. 136-151.
Etesin, U., Udoinyang, E. & Harry, T. (2013). Seasonal variation of physicochemical parameters of water and sediments from Iko River, Nigeria. Journal of Environment and Earth Science, 3, 8, pp. 96-110.
Gulf of Maine Aquarium. August 17.1998. Aquifer: Sources of Pure Water. 6
Gundry, S., Conroy, R. & Wright, J. A (2003). Systematic Review of the health outcomes related to household water quality in developing countries. Journal of Water and Health. 2. 1-13.
Ikot Abasi, The Aluminum Town (1997). A Socio-Economic Transformation of a Nigerian Community. An ALSCON Publication.
Ituen, U., Atser, J. & Edem, S. N. (2016). Analysis and depiction of accessibility levels of water supply schemes in rural Akwa Ibom State, Nigeria. Iranian Journal of Health, Safety & Environment, 3, 2, pp. 518-527.
Igbemi, A. I., Nwaogazie, I. L., Akaranta, O. & Abu, G. O. (2019). Water quality assessment by pollution indices in Eastern Obolo Coastline Communities of Nigeria. American Journal of Water Resources, 7, 3, pp. 111-120.
Jain, C. K., Bandyopadhyay, A. & Bhadra, A (2009). Assessment of ground water quality for drinking purpose, District Nainital, Uttarakhand, India. Environmental Monitoring and Assessment, 166, pp. 663-676.
Khan, S., Shahnaz, M., Jehan, N., Rehman, S., Shah, M. T. & Din, I. (2012). Drinking water quality and human health risk in Charsadda district, Pakistan. Journal of Clean Production,. doi: 10.1016/j.jclepro.2012.02
Kumar Sajil P. J. (2013). Interpretation of ground water chemistry using Piper and Chadha diagrams. A comparative study from Perambalur Talnk. Elixir Geosciences, 54, pp. : 12208 – 12211
Lloyd, J. A. & Heathcote, J. A. (1985) Natural inorganic hydrochemistry in relation to groundwater: An introduction. Oxford Uni. Press, New York p: 296.
Igboekwe, M. U., Lucky, E. E. & Akankpo, A. O. (2012). Determination of aquifer characteristics in Eket, Akwa Ibom State, Nigeria, using the vertical electrical sounding method. International Journal of Water Resources and Engineering, 4, 1, pp. 1-7.
Mbonu, P. D. C. & Ebeniro, J. O. (1991). Geoelectric sounding for the determination of Aquifer characteristics in parts of Umuahia area of Nigeria. Geophysics, 56, pp. 284-291.
Benson, N. U., Anake, W. U.,Essien, J. P., Enyong, P. & Olajire, A. A. (2018). Distribution and risk assessment of trace metals in Leptodius exarata, surface water and sediments from Douglas Creek in Qua Iboe Estuary. Journal of Taibah University for Science. https //doi.org/10.1016/j.jtusci.2016.08.004
Okolie, E.C; Osemeikheian, JEA; Asokhia, M. B. (2005). Estimate of Ground Water in Parts of Niger Delta Area of Nigeria using Geoelectric Method. Journal of Applied Sciences and . Environmental. Management, 9, 1, pp. 31-37.
Okorafor, K. A., Agbo, B. E., Johnson, A. M. & Chiorhe, M. (2012). Physicochemical and bacteriological characteristics of selected streams and borehole in Akamkpa and Calabar municipality, Nigeria. Archives of Applied Science Research, 4, 3, pp. 2115-2121.
Owamah, H. I., Asiagwu, A. K,., Egboh, S. H. O. & Phil-Usiayo, S. (2013). Drinking water quality at Isoko North communities of the Niger Delta Region, Nigeria. Toxicology and Environmental Chemistry, https://doi. org/10.1080/02772248.2013.847939
Palma, P., Alvarenga, P., Palma, V. L., Fernandes, R. M., Soares, A. M. V. M,. & Barbosa, I. R. (2010). Assessment of anthropogenic sources of water pollution using multivariate statistical techniques: a case study of Alqueva’s reservoir, Portugal. Environmental Monitoring and Assessment, 165, pp. 539–552
Rizwan, R. & Singh, G. (2009) Physico-chemical analysis of groundwater in Angul–Talcher region of Orissa, India, Journal of American Sciences, 5, 5, pp. 53-58.
Sappa, G., Barbieri, M., Ergul, S. & Ferranti, F. (2012) Hydrogeological conceptual model of groundwater from carbonate aquifers using environmental isotopes (18O, 2H) and chemical tracers: a case study in southern Latium region, Central Italy. Journal of Water Resources and Protection, (JWARP) 4, 9, doi: 10.4236/jwarp.2012.49080
Singh K, Malik A, Mohan D, Sinha S (2004) Multivariate statistical techniques for the evaluation of spatial and temporal variations in water quality of Gomti River (India)—a case study. Water Res 38(18):3980–3992
Yasala, S., Oilver, H., Raj, A. S. & Chandrasekar N. (2014). Quality assessment and hydrogeochemical characteristics of groundwater in
Agastheeswaram taluk, Kanyakumari district, Tamil Nadu, India. Chinese Journal of Geochemistry, 33, pp. 221-235.
Standards Organization of Nigeria. (2007). Nigerian standard for drinking water quality. Lagos. Nigeria.
Udoh,. J., Ukpatu, J. & Otoh, A. (2013). Spatial variation of physicochemical parameters of Eastern Obolo estuary, Nigeria Delta, Nigeria. Journal Of Environment and Earth Science. 3, 12, pp. 161-171.
Ukpong, E. C. & Okon, B. B. (2013). Comparative analysis of public and private borehole water supply sources in Uruan Local Government Area of Akwa-Ibom State. International Journal of Applied Science and Technology, 3, 1, pp. 76-91.
US Geological Survey. Aquifers and Groundwater. http//water.usgs.gov/edu/earthgwaquifer.html.
WHO (2006). Meeting the MDG Drinking Water and Sanitation Target: The Urban and Rural Challenge of the decade Genera, Switzerland, World Health Organization
WHO. (2011). Guidelines for Drinking-water quality. Geneva, Switzerland. World Health Organization.
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