|تعداد مشاهده مقاله||111,731,063|
|تعداد دریافت فایل اصل مقاله||86,336,865|
Assessment of groundwater and surface water pollution by hazardous metals, using multivariate analysis and metal pollution index around the old Sidi Kamber mine, NE Algeria
|دوره 8، شماره 3، مرداد 2022، صفحه 889-903 اصل مقاله (1.03 M)|
|نوع مقاله: Original Research Paper|
|شناسه دیجیتال (DOI): 10.22059/poll.2022.335695.1294|
|malika khelfaoui* 1؛ Amina Benaissa2؛ Sihem Kherraf3؛ Mohamed Salah Madjram4؛ Ibtissem Bouras1؛ karima Mehri1|
|1Laboratory LGCES, Faculty of Technology, 20 Août 1955 University, El-Hadaeik Road, P.O. Box 26, Skikda 21000, Algeria|
|2Department of Process Engineering, Faculty of Technology, 20 Août 1955 University, P.O. Box 26, Skikda 21000, Algeria|
|3department of petrochemical, Faculty of Technology, 20 Août 1955 University, P.O. Box 26, Skikda 21000, Algeria.|
|4petrochemistry and process engineering faculty of technology university 20 August 1955 Skikda Algeria|
|In order to evaluate the impact on water quality of the abandoned Sidi Kamber mine in Skikda, NE Algeria, Pb, Zn, Cd, Fe, Cu, Mn and Ni metals were collected at surface water and groundwater, from twenty eight sites located near the mine. Conventional hydrochemical methods, heavy metal pollution index (HPI) and multivariate statistical analysis techniques: correlation matrix (CM), principal component analysis (PCA) and hierarchical cluster analysis (HCA) were used. Surface water results show that El-Souk River has a high level of pollution, but Guenitra dam water is less contaminated. Regarding the groundwater results, the wells and springs are not suitable for drinking. The overall quality estimated by HPI values of surface and groundwater are poor; they may pose a potential health risk to the local population. The PCA and HCA suggest that surface water and groundwater are contaminated by two sources: anthropogenic and natural. According to the obtained results, surface water and groundwater pollution state of this area raises serious concerns about health and environment.|
|groundwater؛ mine؛ multivariate statistical؛ pollution؛ surface water|
Álvarez-Valero, A. M., Pérez-López, R., Matos, J., Capitán, M. A., Nieto, J. M., Sáez, R., Delgado, J. and Caraballo, M. (2008). Potential environmental impact at São Domingos mining district (Iberian Pyrite Belt, SW Iberian Peninsula): evidence from a chemical and mineralogical characterization. Environmental Geology, 55(8), 1797-1809.
Armah, F. A., Obiri, S., Yawson, D. O., Onumah, E. E., Yengoh, G. T., Afrifa, E. K. and Odoi, J. O. (2010). Anthropogenic sources and environmentally relevant concentrations of heavy metals in surface water of a mining district in Ghana: a multivariate statistical approach. Journal of Environmental Science and Health Part A, 45(13), 1804-1813.
Asare-Donkor, N. K. and Adimado, A. A. (2020). Groundwater quality assessment in the Northern and Upper East Regions of Ghana. Environmental Earth Sciences, 79(10), 1-19.
Bhardwaj, R., Gupta, A. and Garg, J. K. (2017). Evaluation of heavy metal contamination using environmetrics and indexing approach for River Yamuna, Delhi stretch, India. Water Science, 31(1), 52-66.
Bhuiyan, M. A., Islam, M. A., Dampare, S. B., Parvez, L. and Suzuki, S. (2010). Evaluation of hazardous metal pollution in irrigation and drinking water systems in the vicinity of a coal mine area of northwestern Bangladesh. Journal of hazardous materials, 179(1-3), 1065-1077.
Boukhalfa, C. (2007). Heavy metals in the water and sediments of Oued Es-Souk, Algeria, a river receiving acid effluents from an abandoned mine. African Journal of Aquatic Science, 32(3), 245-249
Briz-Kishore, B. H. and Murali, G. (1992). Factor analysis for revealing hydrochemical characteristics of a watershed. Environmental Geology and Water Sciences, 19(1), 3-9.
Chen, K., Jiao, J. J., Huang, J. and Huang, R. (2007). Multivariate statistical evaluation of trace elements in groundwater in a coastal area in Shenzhen, China. Environmental Pollution, 147(3), 771-780.
Chidambaram, S., Srinivasamoorthy, K., Anandhan, P. and Selvam, S. (2015). A study on assessment of credible sources of heavy metal pollution vulnerability in groundwater of Thoothukudi districts, Tamilnadu, India. Water Quality, Exposure and Health, 7(4), 459-467.
Cidu, R., Biddau, R. and Fanfani, L. (2009). Impact of past mining activity on the quality of groundwater in SW Sardinia (Italy). Journal of Geochemical Exploration, 100(2-3), 125-132.
de León-Gómez, H., del Campo-Delgado, M. A. M., Esteller-Alberich, M. V., Velasco-Tapia, F., Alva-Niño, E. and Cruz-López, A. (2020). Assessment of nitrate and heavy metal contamination of groundwater using the heavy metal pollution index: case study of Linares, Mexico. Environmental Earth Sciences, 79(18), 1-19.
El Khalil, H., El Hamiani, O., Bitton, G., Ouazzani, N. and Boularbah, A. (2008). Heavy metal contamination from mining sites in South Morocco: monitoring metal content and toxicity of soil runoff and groundwater. Environmental monitoring and assessment, 136(1), 147-160.
Everitt, B. and Hothorn, T. (2011). An introduction to applied multivariate analysis with R. Springer Science & Business Media.
Favas, P. J. C., Sarkar, S. K., Rakshit, D., Venkatachalam, P. and Prasad, M. N. V. (2016). Acid mine drainages from abandoned mines: hydrochemistry, environmental impact, resource recovery, and prevention of pollution. In Environmental materials and waste (pp. 413-462). Academic Press.
Güler, C., Kurt, M. A., Alpaslan, M. and Akbulut, C. (2012). Assessment of the impact of anthropogenic activities on the groundwater hydrology and chemistry in Tarsus coastal plain (Mersin, SE Turkey) using fuzzy clustering, multivariate statistics and GIS techniques. Journal of Hydrology, 414, 435-451.
Güler, C., Thyne, G. D., McCray, J. E. and Turner, K. A. (2002). Evaluation of graphical and multivariate statistical methods for classification of water chemistry data. Hydrogeology journal, 10(4), 455-474.
Helena, B., Pardo, R., Vega, M., Barrado, E., Fernandez, J. M. and Fernandez, L. (2000). Temporal evolution of groundwater composition in an alluvial aquifer (Pisuerga River, Spain) by principal component analysis. Water research, 34(3), 807-816.
Huang, X., Deng, H., Zheng, C. and Cao, G. (2016). Hydrogeochemical signatures and evolution of groundwater impacted by the Bayan Obo tailing pond in northwest China. Science of the Total Environment, 543, 357-372.
Khelfaoui, M., Medjram, M. S., Kabir, A., Zouied, D., Mehri, K., Chikha, O. and Trabelsi, M. A. (2020). Chemical and mineralogical characterization of weathering products in mine wastes, soil, and sediment from the abandoned Pb/Zn mine in Skikda, Algeria. Environmental Earth Sciences, 79, 1-15.
Kumar, A. R. and Riyazuddin, P. (2008). Application of chemometric techniques in the assessment of groundwater pollution in a suburban area of Chennai city, India. Current Science, 1012-1022.
Kumar, M., Nagdev, R., Tripathi, R., Singh, V. B., Ranjan, P., Soheb, M. and Ramanathan, A. L. (2019). Geospatial and multivariate analysis of trace metals in tubewell water using for drinking purpose in the upper Gangetic basin, India: heavy metal pollution index. Groundwater for Sustainable Development, 8, 122-133.
Medjram, S. and Khalfaoui, M. (2014). Study and evaluation of risk related to waters contamination of dam of Guenitra, by heavy metals, from mine of Sidi Kamber. J Selcuk Univ Nat Appl Sci, 268-274.
Modoi, O. C., Roba, C., Török, Z. and Ozunu, A. (2014). Environmental risks due to heavy metal pollution of water resulted from mining wastes in NW Romania. Environmental Engineering & Management Journal (EEMJ), 13(9).
Mohan, S. V., Nithila, P. and Reddy, S. J. (1996). Estimation of heavy metals in drinking water and development of heavy metal pollution index. Journal of Environmental Science & Health Part A, 31(2), 283-289.
Moya, C. E., Raiber, M., Taulis, M. and Cox, M. E. (2015). Hydrochemical evolution and groundwater flow processes in the Galilee and Eromanga basins, Great Artesian Basin, Australia: a multivariate statistical approach. Science of the Total Environment, 508, 411-426.
Nasrabadi, T. (2015). An Index Approach to Metallic Pollution in River Waters. International Journal of Environmental Research, 9(1), 385-394.
Nasrabadi, T. and Maedeh, P. A. (2014). Groundwater quality assessment in southern parts of Tehran plain, Iran. Environmental earth sciences, 71(5), 2077-2086.
Ogwueleka, T. C. (2015). Use of multivariate statistical techniques for the evaluation of temporal and spatial variations in water quality of the Kaduna River, Nigeria. Environmental monitoring and assessment, 187(3), 1-17.
Oumedjbeur, A. (1986). Evaluation de la qualité physico-chimique des eaux du bassin versant du barrage de Guénitra (wilaya de Skikda). Doctorate thesis of 3rd cycle, University of Savoy.
Panda, U. C., Sundaray, S. K., Rath, P., Nayak, B. B. and Bhatta, D. (2006). Application of factor and cluster analysis for characterization of river and estuarine water systems–a case study: Mahanadi River (India). Journal of hydrology, 331(3-4), 434-445.
Prasad, B., Soni, A. K., Vishwakarma, A., Trivedi, R. and Singh, K. K. K. (2020). Evaluation of water quality near the Malanjhkhand copper mines, India, by use of multivariate analysis and a metal pollution index. Environmental Earth Sciences, 79, 1-23.
Rakotondrabe, F., Ngoupayou, J. R. N., Mfonka, Z., Rasolomanana, E. H., Abolo, A. J. N. and Ako, A. A. (2018). Water quality assessment in the Bétaré-Oya gold mining area (East-Cameroon): multivariate statistical analysis approach. Science of the Total Environment, 610, 831-844.
Rashed, M. N. (2010). Monitoring of contaminated toxic and heavy metals, from mine tailings through age accumulation, in soil and some wild plants at Southeast Egypt. Journal of hazardous materials, 178(1-3), 739-746.
Rösner, U. (1998). Effects of historical mining activities on surface water and groundwater-an example from northwest Arizona. Environmental Geology, 33(4), 224-230.
Rowe, R. K. and Hosney, M. S. (2013). Laboratory investigation of GCL performance for covering arsenic contaminated mine wastes. Geotextiles and Geomembranes, 39, 63-77.
Singh, A. K., Varma, N. P. and Mondal, G. C. (2016). Hydrogeochemical investigation and quality assessment of mine water resources in the Korba coalfield, India. Arabian Journal of Geosciences, 9(4), 278.
Tordoff, G. M., Baker, A. J. M. and Willis, A. J. (2000). Current approaches to the revegetation and reclamation of metalliferous mine wastes. Chemosphere, 41(1-2), 219-228.
Varol, S. and Davraz, A. (2015). Evaluation of the groundwater quality with WQI (Water Quality Index) and multivariate analysis: a case study of the Tefenni plain (Burdur/Turkey). Environmental Earth Sciences, 73(4), 1725-1744.
Uugwanga, M. N. and Kgabi, N. A. (2021). Heavy metal pollution index of surface and groundwater from around an abandoned mine site, Klein Aub. Physics and Chemistry of the Earth, Parts A/B/C, 124, 103067.
WHO (2011). Guidelines for Drinking-water Quality Recommandations. Fourth edition.
Younger, P. L., Banwart, S. A. and Hedin, R. S. (2002). Mine water: hydrology, pollution, remediation (Vol. 5). Springer Science & Business Media.
Zanuzzi, A., Arocena, J. M., Van Mourik, J. M. and Cano, A. F. (2009). Amendments with organic and industrial wastes stimulate soil formation in mine tailings as revealed by micromorphology. Geoderma, 154(1-2), 69-75.
Zhao, H., Xia, B., Qin, J. and Zhang, J. (2012). Hydrogeochemical and mineralogical characteristics related to heavy metal attenuation in a stream polluted by acid mine drainage: a case study in Dabaoshan Mine, China. Journal of Environmental Sciences, 24(6), 979-989.
Zhuang, P., McBride, M. B., Xia, H., Li, N. and Li, Z. (2009). Health risk from heavy metals via consumption of food crops in the vicinity of Dabaoshan mine, South China. Science of the total environment, 407(5), 1551-1561.
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