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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