Hydrogeological Impact of Gold Mining, Contaminant Flow Patterns and Groundwater Quality Assessment in the Kambele Mining Area, Eastern Part of Cameroon
Gold mining activity is a source of income in many areas worldwide, especially in developing countries where it is often practiced illegally using unsafe techniques. In the Kambele area, artisanal and small-scale gold mining (ASGM) is widespread, and gold recovery relies on the use of toxic substances such as mercury (Hg), posing a threat to both the environment and human health. This study assesses aquifer flow directions and the impact of ASGM on the shallow aquifer in the Batouri gold district, specifically in the Kambele mining sites, where limited scientific studies have been carried out. Piezometric measurements were conducted on 36 wells, and 7 underground water samples were collected from the Kambele locality. Two trace elements (mercury and cyanide) and ten major ions were analyzed using the Atomic Absorption Spectrometer and Ion Chromatography techniques. The piezometric map revealed varying groundwater flow directions at different localities: Kambele 1 had a flow direction from west to east, while Kambele 2 and 3 had flows from east to west. Analysis showed that 72% of the samples had Hg concentrations ranging from 0.0010 mg/l to 0.0027 mg/l, and 57% of the samples had CN concentrations ranging from 0.0011 mg/l to 0.0025 mg/l. All samples had Hg and CN concentrations below the World Health Organization (WHO) guidelines for water quality, which are 0.006 mg/l for Hg and 0.007 mg/l for CN. Additionally, all major ions analyzed were within WHO guidelines. Hydrometric degree (hardness) and Sodium Adsorption Ratio (SAR) values indicated that the water is fresh and suitable for agricultural irrigation. This research highlights the importance of understanding groundwater flow patterns and contaminant transport pathways to mitigate the environmental impacts of ASGM and ensure water quality for human consumption and the environment.
References
[1]
Keesstra, S.D., Geissen, V., Mosse, K., Piiranen, S., Scudiero, E., Leistra, M., Van Schaik, L. (2012) Soil as a Filter for Groundwater Quality. Geoderma, 179-180, 41-52.
[2]
Chapagain, A.K. and Orr, S. (2009) An Improved Water Footprint Methodology Linking Global Consumption to Local Water Resources: A Case of Spanish Tomatoes. JournalofEnvironmentalManagement, 90, 1219-1228. https://doi.org/10.1016/j.jenvman.2008.06.006
[3]
Talabi, A.O. and Kayode, T.J. (2019) Groundwater Pollution and Remediation. JournalofWaterResourceandProtection, 11, 1-19. https://doi.org/10.4236/jwarp.2019.111001
[4]
Dallou, G.B., Ngoa, E.L., Ndjana, J.E., Saidou, Y.F., Tchuente Siaka, D. (2017) NORM Measurements and Radiological Hazard Assessment in the Gold Mining Areas of Eastern Cameroon. Journal of Environmental Radioactivity, 171, 53-63.
[5]
Ngatcha, R.B., Olugbenga, A.O., Cheo, E.S., Axel Hofmann, K.I. (2019) Petrochemical Characterization of Neoproterozoic Colomine Granitoids, SE Cameroon: Implications for Gold Mineralization. Journal of African Earth Sciences, 149, 345-357.
[6]
Wambo, J.D.T., Roy, A. Ganno, S. Fossi, D.H, Oliver, D.W., Nzenti, J.P. and Asimow, P.D. (2020) Single-Zircon UPb Geochronology and Petrogenesis of Pan-African Granitoids Associated with Gold-Bearing Quartz Veins in the Ngoura-Colomines area, Eastern. PrecambrianResearch, 371, Article 106624.
[7]
Leroy, M.N.L., Richard, M.J., Mouhamed, A.N., Sifeu, T.K., Yvan, A.S.R. and Said, R. (2020) Physicochemical Characterization of Mining Waste from the Betare-Oya Gold Area (East Cameroon) and an Adsorption Test by Sabga Smectite (North-West Cameroon). Environmental Earth Sciences, 79, Article ID: 6293819. https://doi.org/10.1155/2020/6293819
[8]
Fonshiynwa, M.M., Fuanya, C., Hoth, N., Ouabo, R.E., Tangko, T.E., Günther, J., et al. (2024) Environmental Impacts of Artisanal and Small-Scale Gold Mining within Kambele and Pater Gold Mining Sites, East Cameroon. GeoJournal, 89, Article No 100. https://doi.org/10.1007/s10708-024-11093-8
[9]
Commune de Batouri, Le Réseau d’Appui au Développement Communautaire (RADEC) (2009) Etude Socio-Economique en Vue de L’elaboration du Plan d’amenagement de La Foret Communale. RADEC, 120 p.
[10]
Jean-Claude, B., Rigobert, T., Joachim, E., Périclex, F.T. and Basile, D.M.G.G. (2019) Geological Context Mapping of Batouri Gold District (East Cameroon) from Remote Sensing Imagering, GIS Processing and Field Works. JournalofGeographicInformationSystem, 11, 766-783. https://doi.org/10.4236/jgis.2019.116046
[11]
Toteu, S.F., Penaye, J. and Djomani, Y.P. (2004) Geodynamic Evolution of the Pan-African Belt in Central Africa with Special Reference to Cameroon. CanadianJournalofEarthSciences, 41, 73-85. https://doi.org/10.1139/e03-079
[12]
Gazel, J. and Gérard, G. (1954) Carte géologique de reconnaissance du Cameroun au 1/500 000, feuille Batouri Est avec notice explicative. Memoir. Direction Mines Géologie.
[13]
Tchakounté, J., Eglinger, A., Toteu, S.F., Zeh, A., Nkoumbou, C., Mvondo-Ondoa, J., et al. (2017) The Adamawa-Yadé Domain, a Piece of Archaean Crust in the Neoproterozoic Central African Orogenic Belt (Bafia Area, Cameroon). PrecambrianResearch, 299, 210-229. https://doi.org/10.1016/j.precamres.2017.07.001
[14]
Assah, A.V. (2010) Lode Gold Mineralisation in the Neoproterozoic Granitoids of Batouri Southeastern Cameroon. Clausthal University of Technology, 202 p.
[15]
Asaah, A.V., Zoheir, B., Lehmann, B., Frei, D., Burgess, R. and Suh, C.E. (2015) Geochemistry and Geochronology of the ~620 Ma Gold-Associated Batouri Granitoids, Cameroon. InternationalGeologyReview, 57, 1485-1509. https://doi.org/10.1080/00206814.2014.951003
[16]
Milesi, J.P., Toteu, S.F., Deschamps, Y., Feybesse, J.L., Lerouge, C., Cocherie, A., et al. (2006) An Overview of the Geology and Major Ore Deposits of Central Africa: Explanatory Note for the 1:4,000,000 Map “Geology and Major Ore Deposits of Central Africa”. JournalofAfricanEarthSciences, 44, 571-595. https://doi.org/10.1016/j.jafrearsci.2005.10.016
[17]
Vishiti, A., Etame, J. and Suh, C.E. (2019) Features of Gold Bearing Quartz Veins in an Artisanal Mining-Dominated Terrain, Batouri Gold District, Eastern Region of Cameroon. Episodes, 42, 199-212. https://doi.org/10.1016/j.jafrearsci.2019.103542
[18]
Cooper-Jacob, E. (1950) Flow of Ground Water. In: Rouse, Ed., Engineering Hydraulics, John Wiley, New York, 321-386.
[19]
Koita, M. (2010) Caractérisation et modélisation du fonctionnement hydrodynamique d’un aquifère fracturé en zone de socle. Région de Dimbokro-Bongouanou (Centre Est de la Côte d’Ivoire). Thèse unique de doctorat, Université de Montpellier II, Montpellier.
[20]
Soro, G. (2010) Evaluation quantitative et qualitative des ressources en eaux souterraines dans la region des lacs (centre de la cote d’ivoire), hydrogeologie et hydrochimie des aquifères discontinus du district de Yamoussoukro et du departement de Tiebissou. Thèse de doctorat, Université Félix Houphouet Boigny, 254 p.
[21]
Femba, R. (2005) Hydrogeologie en zone de socle cristallin: Cas du bassin versant de l’Ekozoa, secteur Nord de la ville de Yaounde-Cameroun. Mem. DEA, Faculty of Sciences of the University of Yaoundé, 79.
[22]
Edet, A. and Richard, H.W. (2009) Monitoring of the Physical Parameters and Evaluation of the Chemical Composition of River and Groundwater in Calabar (Southeastern Nigeria). Environmental Monitoring and Assessment, 157, 243-258. https://doi.org/10.1007/s10661-008-0532-y
[23]
Eiriksson, D., Whitson, M. and Luce, C.H. (2013) Environmental Monitoring and Assessment, 150, 253-265.
[24]
Kouassi, A.M., Ahoussi K.E., Yao K.A., Ourega W.E.J.A., Yao, K.S.B. and Biemi, J. (2012) Analyse de la productivite des aquiferes fissures de la region du N’Zi-Comoe (centre-est de la Cote d’Ivoire). Larhyss Journal, No. 10, 57-74.
[25]
Tchapnga, D. (1987) Geology and Hydrogeology of a Sector of the Mobile Zone of Central Africa: Poli Region, North Cameroon. JournalofAfricanEarthSciences, 6, 491-503.
[26]
Harter, T. (2003) Ground Water Sampling and Monitoring. In: Wilderer, P., Ed., Treatise on Water Science, Vol. 2, Academic Press, 271-294.
[27]
American Public Health Association (APHA) (2017) Standard Methods for the Examination of Water and Wastewater. 23rd Edition, American Public Health Association.
[28]
Richards, L.A. (1954) Diagnosis and Improvement of Saline and Alkali Soils. Soil Science, 78, 154. https://doi.org/10.1097/00010694-195408000-00012
[29]
WHO (2022) Guidelines for Drinking-Water Quality: Fourth Edition Incorporating the First and Second Addenda. Licence CC BYNCSA 31 IGO.
[30]
WHO (2011) Guideline for Drinking-Water Quality. 4th Edition.
[31]
WHO (2005) Mercury in Drinking-Water. Background Document for Development of WHO Guidelines for Drinking-Water Quality.
