Jolaosho Toheeb Lekan, Mustapha Adejuwon Ayomide, Hundeyin Samuel Todeyon
Department of Fisheries, Faculty of Science, Lagos State University, Ojo, Lagos State, Nigeria.
Department of Geography and Planning, Lagos State University, Ojo, Lagos State, Nigeria.
Heliyon. 2024 Sep 26;10(19):e38364. doi: 10.1016/j.heliyon.2024.e38364. eCollection 2024 Oct 15.
This study examines the hydrogeochemical and heavy metal parameters of groundwater in Ojo District to determine its suitability for use, potential sources, and human health implications. Ten groundwater samples were assessed, and hydrogeochemical modelling was performed via the Aquachem software. The chemical ions were in the following order: EC > (107.78-448.65 μS/cm) > TDS (182.02-320.77 mg/l) > TH (46.22-182.45 mg/l) > pH (5.55-6.35); HCO (64.13-125.82 mg/l) > Na (36.87-96.49 mg/l) > Ca (47.65-58.88 mg/l) > SO (19.94-53.67) > NO (15.55-44.25 mg/l) > Cl (20.43-27.16 mg/l) > Mg (11.09-16.87 mg/l) and K (2.55-7.86 mg/l). The concentrations of heavy metals in groundwater were in the range of: Fe (0.11-0.27 mg/l) > Mn (0.003-0.16 mg/l) > Ni (0.05-0.12 mg/l) > Zn (0.003-0.05 mg/l) > Pb (0.001-0.03 mg/l) > As (0.001-0.005 mg/l) > Cr (0.002-0.005 mg/l) > Cd (0.001-0.003 mg/l) and Cu (0.001-0.0002 mg/l), with Pb, Mn, and Ni exceeding their allowable limits. The Schoeller and Gibbs plots revealed that the major mechanisms controlling the aquifer groundwater in Ojo region are geological rock weathering and mineralization, with a minimal influence of saltwater intrusion. The piper trilinear diagram also revealed that none of the cation was dominant while the anions were strongly dominated by HCO (weak acids). The hydrogeochemical facies which describes the geochemical characteristics of the groundwater were classified into 3 types; "Ca-Mg-HCO (65 %)", "mixing zones (30 %)", and "Na-K-Cl-HCO (5 %)". The hydrogeochemical modelling revealed that the groundwater is characterized by forward cation exchange, while rock-water interactions (silicate dissolution) were heavily involved in the geochemical processes. The single pollution index showed that Pb, Ni, and Mn contributed significantly to contamination, and the multi-pollution indices showed that the groundwater was slightly-moderately polluted. The integrated groundwater quality index revealed that only 10 % were clean, 50 % were poor or moderately unclean, 30 % were highly unclean, and only 10 % were extremely unclean (unfit for utilization). The water pollution index showed that 70 % of the groundwater was good. The irrigation indices suggest that the groundwater would enhance soil quality and support plant growth. Multivariate analysis revealed that the groundwater is being influenced by geogenic factors and anthropogenic activities. The health risk assessment (Hazard Quotient and Hazard Index) showed that exposure of adults to the investigated groundwaters could result in noncarcinogenic adverse effects. The cancer risk values also exceeded the minimum limit (1.0 x 10) and thresholds (1.0 x 10) for adults, indicating the carcinogenic potential of the groundwater.
本研究考察了奥约区地下水的水文地球化学和重金属参数,以确定其使用适宜性、潜在来源及对人类健康的影响。评估了10个地下水样本,并通过Aquachem软件进行了水文地球化学建模。化学离子顺序如下:电导率(EC)>(107.78 - 448.65微西门子/厘米)>总溶解固体(TDS)(182.02 - 320.77毫克/升)>总硬度(TH)(46.22 - 182.45毫克/升)>pH值(5.55 - 6.35);碳酸氢根(HCO₃⁻)(64.13 - 125.82毫克/升)>钠离子(Na⁺)(36.87 - 96.49毫克/升)>钙离子(Ca²⁺)(47.65 - 58.88毫克/升)>硫酸根(SO₄²⁻)(19.94 - 53.67)>硝酸根(NO₃⁻)(15.55 - 44.25毫克/升)>氯离子(Cl⁻)(20.43 - 27.16毫克/升)>镁离子(Mg²⁺)(11.09 - 16.87毫克/升)和钾离子(K⁺)(2.55 - 7.86毫克/升)。地下水中重金属浓度范围为:铁(Fe)(0.11 - 0.27毫克/升)>锰(Mn)(0.003 - 0.16毫克/升)>镍(Ni)(0.05 - 0.12毫克/升)>锌(Zn)(0.003 - 0.05毫克/升)>铅(Pb)(0.001 - 0.03毫克/升)>砷(As)(0.001 - 0.005毫克/升)>铬(Cr)(0.002 - 0.005毫克/升)>镉(Cd)(0.001 - 0.003毫克/升)和铜(Cu)(0.001 - 0.0002毫克/升),其中铅、锰和镍超过了其允许限值。朔勒图和吉布斯图表明,控制奥约地区含水层地下水的主要机制是地质岩石风化和成矿作用,海水入侵影响极小。派珀三线图还表明,阳离子均不占主导地位,而阴离子则以碳酸氢根(弱酸)为主。描述地下水地球化学特征的水文地球化学相分为3种类型;“钙 - 镁 - 碳酸氢根(65%)”、“混合区(30%)”和“钠 - 钾 - 氯 - 碳酸氢根(5%)”。水文地球化学建模表明,地下水的特征是正向阳离子交换,而岩石 - 水相互作用(硅酸盐溶解)在地球化学过程中起重要作用。单污染指数表明,铅、镍和锰对污染有显著贡献,多污染指数表明地下水受到轻度至中度污染。综合地下水质量指数显示,只有10%的水清洁,50%的水质量差或中度不清洁,30%的水高度不清洁,只有10%的水极其不清洁(不适于利用)。水污染指数表明70%的地下水质量良好。灌溉指数表明,该地下水将改善土壤质量并支持植物生长。多变量分析表明,地下水受到地质成因因素和人为活动的影响。健康风险评估(危害商数和危害指数)表明,成年人接触所调查的地下水可能会导致非致癌性不良反应。癌症风险值也超过了成年人规定的最低限值(1.0×10⁻⁶)和阈值(1.0×10⁻⁴),表明该地下水具有致癌潜力。
