Abstract
This comprehensive research has been conducted to consider the distribution of PTEs in the surface sediments of a recently developed Dar-e-Allo copper mine in dependence on the potential ecological and human health risks. Field sampling was carried out discreetly at preselected sampling spots including the natural background, the streams around the mine, waste rock drainages, evaporative deposits, sediments containing Fe oxy-hydroxides and secondary phases. Distribution of target elements (Al, As, Cd, Co, Cr, Cu, Fe, Mn, Mo, Ni, Pb, S, Sb, Se, and Zn) showed high levels of crustal elements. As regards, Fe, Al, and S are identified to exist as the most copious elements in the earth's crust, so have the major portion of potentially toxic elements (PTEs) in the sediment concentrations. Evaluating environmental indices reflected that in general, Cu, S, and Mo have a higher quota of contamination in sedimentary systems. the pollution load index (PLI), modified contamination degree (mCd), Contamination factor (Cf), Sediment potential index (SPI), Geo-accumulation index (Igeo) and Contamination degree (Cd) confirm that sedimentary systems of mining area are heavily contaminated by PTEs and were not found within the guideline acceptable values. The potential ecological risk index (PERI) displayed a high or severe risk level for Cu with a peak in green–blue sediments containing secondary minerals. The results of total carcinogenic risk (TCRs) show that As has high toxicity level and carries a risk of carcinogenicity among children and adults. The TCRs for Cd, Cr, Ni, and Pb with carcinogenic potential are found only in children and they are classified as the prime concern elements that have serious dangers to children's public health. The results of contamination source presumed that the sources of PTEs contamination were principally geogenic along with the anthropogenic sources in the study area. Therefore, the present study has highlighted the implication of human health risks of PTEs in sedimentary systems of copper mining, also will grant advice for prime stakeholders, including mine managers, Environmental Protection Agency, the government and public organizations in connection to protecting the environment, aquatic biota and consumer’s health.
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Abdallah, R. I., Khalil, N. M., & Roushdy, M. I. (2016). Monitoring of pollution in sediments of the coasts in Egyptian Red Sea. Egyptian Journal of Petroleum, 25, 133–151.
Abrahim, G. M. S., & Parker, R. J. (2002). Heavy metal contaminants in Tamaki Estuary: Impact of city development and growth, Auckland, New Zealand. Environmental Geology, 42, 883–890.
Abrahim, G. M. S., & Parker, R. J. (2008). Assessment of heavy metal enrichment factors and the degree of contamination in marine sediments from Tamaki Estuary Auckland, New Zealand. Environment Monitoring and Assessment, 136, 227–238.
AliMohammadi, M., Alirezaei, S., Ghaderi, M., & Kentucky, D. (2015). Geochemistry, regeneration and tectonic location of volcanic and intrusive rocks in the area of porphyry copper deposits in Dar-e-allo and Sarmashk, south of the belt Kerman Copper, Iran. Earth Sciences, 98, 159–170.
Arienzo, M., Ferrara, L., Toscanesi, M., Giarra, A., Donadio, C., & Trifuoggi, M. (2020). Sediment contamination by heavy metals and ecological risk assessment: The case of Gulf of Pozzuoli, Naples Italy. Marine Pollution Bulletin, 155, 111149.
Atega, P. L. E., Vinches, M., Casiot, C., & Pistre, S. (2022). Development and implementation of a multi-criteria aggregation operator to estimate the contributions of the natural geochemical background and anthropogenic inputs in groundwater in former mining regions: An application to arsenic and antimony in the Gardon river watershed (southern France). Science of the Total Environment, 814, 151936.
Barbieri, M. (2016). The importance of enrichment factor (EF) and geoaccumulation index (Igeo) to evaluate the soil contamination. Geology & Geophysics, 5, 1000237.
Bavi, H. (2020). Assessment of drainage basin affected by copper mine Dar-e-Allo, (South Kerman) Sedimentology, Environmental Geochemistry and Hydrogeochemistry. Internal Report of National Iranian Copper Industries Complex, p. 310
Cao, L., Hong, G., & Liu, S. (2015). Metal elements in the bottom sediments of the Changjiang estuary and its adjacent continental shelf of the East China Sea. Marine Pollution Bulletin., 95, 458–468.
Chatta, A., Khan, M. N., Mirza, S. Z., & Ali, A. (2016). Heavy metal (Cadmium, lead, and chromium) contamination in farmed fish: A potential risk for consumers health. Turkish Journal of Zoology, 40, 1–9.
Cheng, Q., Wang, R., Huang, W., Wang, W., & Li, X. (2015). Assessment of heavy metal contamination in the sediments from the Yellow River Wetland National Nature Reserve (the Sanmenxia section), China. Environmental Science and Pollution Research. https://doi.org/10.1007/s11356-014-4041-y
Choudhury, T. R., Acter, T., Uddin, N., Kamal, M., Chowdhury, A. M. S., & Rahman, M. S. (2021). Heavy metals contamination of river water and sediments in the mangrove forest ecosystems in Bangladesh: A consequence of oil spill incident. Environmental Nanotechnology, Monitoring & Management, 16, 100484.
Chu, Z., Yang, Z., Wang, Y., Sun, L., Yang, W., Yang, L., & Gao, Y. (2019). Assessment of heavy metal contamination from penguins and anthropogenic activities on Fildes Peninsula and Ardley Island Antarctic. Science of The Total Environment, 646, 951–957.
Devanesan, E., Gandhi, M. S., Selvapandiyan, M., Senthilkumar, G., & Ravisankar, R. (2017). Heavy metal and potential ecological risk assessment in sediments collected from Poombuhar to Karaikal Coast of Tamilnadu using Energy Dispersive X-ray fluorescence (EDXRF) technique. Beni-Suef University Journal of Basic and Applied Sciences. https://doi.org/10.1016/j.bjbas.2017.04.011
Dhaliwal, S. S., Sharma, V., & Shukla, A. K. (2022). Chapter One - Impact of micronutrients in mitigation of abiotic stresses in soils and plants—A progressive step toward crop security and nutritional quality. Advances in Agronomy, 173, 1–78.
Diami, S. M., Kusin, F. M., & Madzin, Z. (2016). Potential ecological and human health risk of heavy metals in surface soils associated with iron ore mining in Pahang, Malaysia. Environmental Science and Pollution Research, 23, 21086–21097.
Douay, F., Pelfrêne, A., Planque, J., Fourrier, H., Richard, A., Roussel, H., & Girondelot, B. (2013). Assessment of potential health risk for inhabitants living near a former lead smelter, part 1: Metal concentrations in soils, agricultural crops, and homegrown vegetables. Environmental Monitoring and Assessment., 185, 3665–3680.
Doyle, J., Solberg, T., Tiefenthaler, J., O’Brien, G., Behnke, H. F., Poulson, H. D., Ela, J. P., & Willett, S. D. (2003). Consensus-based sediment quality guidelines: recommendations for use & application interim guidance (p. 40). WT: Wisconsin Department of natural resources.
Forstner, U., Ahlf, W., Calmano, W., & Kersten, M. (1990). Sediment criteria development–contributions from environmental geochemistry to water quality management. In D. Heling, P. Rothe, U. Forstner, & P. Stoffers (Eds.), Sediments and environmental geochemistry: Selected aspects and case studies (pp. 311–338). Berlin Heidelberg: Springer.
García-Valero, A., Martínez-Martínez, S., Faz, A., Rivera, J., & Acosta, J. A. (2020). Environmentally sustainable acid mine drainage remediation: Use of natural alkaline material. Water Process Engineering, 33, 101064.
Goodman, J., Prueitt, R., Thakali, S., & Oller, A. (2011). The nickel ion bioavailability model of the carcinogenic potential of nickel-containing substances in the lung. Inf. Healthc., 41, 142–174.
Guevara, R., Rizzo, A., & Sanchez, R. (2005). Heavy metal inputs in northern Patagonia lakes from short sediment core analysis. Journal of Radio Analytical and Nuclear Chemistry., 265, 481–493.
Guo, G., Wu, F., Xie, F., & Zhang, R. (2012). Spatial distribution and pollution assessment of heavy metals in urban soils from southwest China. International Journal of Environmental Science and Technology., 24, 410–418.
Hakanson, L. (1980). An ecological risk index for aquatic pollution control: A sedimentological approach. Water Research, 14(8), 975–1001.
Halim, N.A., Kusin, F.M., Mohamed, K.N., 2017. Heavy metal exposure from co-processing of hazardous wastes for cement production and associated human risk assessment. International Journal of Environmental Science and Technology, P. 1–10
Hernández, E., Obrist-Farner, J., Brenner, M., Kenney, W. F., Curtis, J. H., & Duarte, E. (2020). Natural and anthropogenic sources of lead, zinc, and nickel in sediments of Lake Izabal, Guatemala. Journal of Environmental Sciences, 96, 117–126.
Horowitz, A. J., & Elrick, K. A. (1987). The relation of stream sediment surface area, grain size and composition to trace element chemistry. Applied Geochemistry, 2, 437–451.
Houng, K. M., & Lin, S. (2003). Consequences and implication of heavy metal spatial variations in sediments of Keelung River drainage basin. Taiwan. Chemosphere, 53, 1113–1121.
Huang, X., Fu, Q., Wang, J., 2020. Distribution and pollution assessment by index of geoac-cumulation about the heavy metals in sediments of dexing copper mine rainwater net- work. In IOP Conference Series: Earth and Environmental Science, 455. IOP Publishing Ltd.
Hutchison, C. H. (2009). Mineral deposits. In C. H. Hutchison & D. N. K. Tan (Eds.), Geology of Peninsular Malaysia. Kuala Lumpur: University of Malaya and Geological Society of Malaysia.
Ikem, A., Egiebor, N. O., & Nyavor, K. (2003). Trace Elements in Water, Fish and Sediment from Tuskegee Lake, Southeastern USA. Water, Air, & Soil Pollution, 149, 51–75.
Iqbal, J., & Shah, M. H. (2014). Occurrence, risk assessment, and source apportionment of heavy metals in surface sediments from Khanpur Lake, Pakistan. Journal of Analytical Science and Technology, 5, 28–32.
Jahan, S., & Strezov, V. (2018). Comparison of pollution indices for the assessment of heavy metals in the sediments of seaports of NSW, Australia. Marine Pollution Bulletin, 128, 295–306.
Jaishankar, M., Tseten, T., Anbalagan, N., Mathew, B., & Beeregowda, K. (2014). Toxicity, mechanism and health effects of some heavy metals. Interdisciplinary Toxicology, 7, 60–72.
Johnson, D. B., & Hallberg, K. B. (2005). Acid mine drainage remediation options: A review. Science of the Total Environment, 338, 3–14.
Karim, Z., & Qureshi, B. A. (2014). Health risk assessment of heavy metals in urban soil of Karachi Pakistan. Human and Ecological Risk Assessment., 20, 658–667.
Kratzer, C. R. (1999). Transport of sediment-bound organocholrine pesticides to San Joaquin River California. American Water Resources Association, 35, 81–957.
Kusin, F. M., Azani, N. N. M., Sharifah, N. M. S. H., & Sulong, N. A. (2018). Distribution of heavy metals and metalloid in surface sediments of heavily mined area for bauxite ore in Pengerang, Malaysia and associated risk assessment. CATENA, 165, 454–464.
Kusin, F. M., Zahar, M. S. M., Muhammad, S. N., Mohamad, N. D., Madzin, Z., & Sharif, S. M. (2016). Hybrid off-river augmentation system as an alternative raw water resource: The hydrogeochemistry of abandoned mining pond. Environmental Earth Sciences., 75, 1–15.
Kutty, A. A., & Al-Mahaqeri, S. A. (2016). An investigation of the levels and distribution of selected heavy metals in sediments and plant species within the vicinity of ex-iron mine in Bukit Besi. Journal of Chemotherapy., 2016, 1–12.
Lai, T. M., Lee, W., Hur, J., Kim, Y., Huh, I. A., Shin, H. S., Kim, C. K., & Lee, J. H. (2013). Influence of sediment grain size and land use on the distribution of heavy metals in sediments of the Han River basin in Korea and assessment of anthropogenic pollution. Water, Air and Soil Pollution, 224, 12–1609.
Li, Z., Ma, Z., Kuijp, T. J., Yuan, Z., & Huang, L. (2014). A review of soil heavy metal pollution from mines in China: Pollution and health risk assessment. Science of the Total Environment., 15(486–469), 843–853.
Likuku, A. S., Mmolawa, K. B., & Gaboutloeloe, G. K. (2013). Assessment of heavy metal enrichment and degree of contamination around the copper-nickel mine in the Selebi Phikwe Region Eastern Botswana. Environment and Ecology Research., 1, 32–40.
Luo, X. S., Ding, J., Xu, B., Wang, Y. J., Li, H. B., & Yu, S. (2012). Incorporating bioaccessibility into human risk assessments of heavy metals in urban park soils. Science of the Total Environment., 424, 88–96.
Lyon, J. S., Hilliard, T. J., & Bethell, T. N. (1993). Burden of guilt: The legacy of environmental damage from abandoned mines and what America should do about it. Washington: Mineral Policy Center.
Macklin, M. G. (1996). Fluxes and storage of sediment-associated heavy metals in floodplain systems: Assessment and river basin management issues at a time of rapid environmental change. In M. G. Anderson, D. E. Walling, & P. D. Bates (Eds.), Floodplain processes (pp. 441–460). Chichester: Wiley.
Mafuyai, G. M., Kamoh, N. M., Kangpe, N. S., Ayuba, S. N., & Eneji, I. S. (2015). Heavy metal contamination in roadside dust along major traffic roads in JOS metropolitan Area Nigeria. Environmental Earth Sciences., 2, 2225–0948.
Mashiatullah, A., Chaudhary, M., Ahmad, N., Ahmad, N., Javed, T., & Ghaffar, A. (2015). Geochemical assessment of metal pollution and ecotoxicology in sediment cores along Karachi coast. Pakitstan. Environmental Monitoring and Assessment, 187(5), 1–16.
Masindi, V., & Muedi, L. (2018). Environmental contamination by heavy metals. In H. E. Salem & R. F. Aglan (Eds.), Heavy metals (pp. 115–133). Rijeka: IntechOpen.
McKnight, D. M., & Bencala, K. E. (1989). Reactive iron transport in an acidic mountain stream in Summit Country, Colorado: A hydrologic perspective. Geochimica Et Cosmochimica Acta, 53, 34–2225.
Menendez, R., Clauyton, J., Zurbuch, P., Sherlock, S., Rauch, H., & Renton, J. (2000). Sandsized limestone treatment of streams impacted by acid mine drainage. Water Air Soil Pollution, 124, 411–428.
Müller, G. (1969). Index of geoaccumulation in the sediments of the Rhine River. GeoJournal, 2, 108–118.
Nabholz, J. V. (1991). Environmental hazard and risk assessment under the United States toxic substances control. Science of the Total Environment., 109, 649–665.
National Iranian Copper Industries Company. (2011). Report of exploration Dar-e-allo Copper deposit. Exploration and Development Engineering Unit, p. 197
Ngole-Jeme, V. M., & Fantke, P. (2017). Ecological and human health risks associated with abandoned gold mine tailings contaminated soil. PLoS ONE. https://doi.org/10.1371/journal.pone.0172517
Penreath, R. J. (1994). The discharge of waters from active and abandoned mines. Issues in Environmental Science and TechnologyIn R. E. Hester & R. M. Harrison (Eds.), Mining and its environmental impact. (Vol. 1). Herts: Royal Society of Chemistry.
Perez-Vazquez, F. J., Flores-Ramirez, R., Ochoa-Martínez, A. C., Carrizales-Yáñez, L., Ilizaliturri-Hernández, A. C., Moctezuma-González, J., Pruneda-Álvarez, L. G., Ruiz-Vera, T., Orta-García, S. T., González-Palomo, A. K., & Pérez-Maldonado, I. N. (2016). Human health risks associated with heavy metals in soil in different areas of San Luis Potosi Mexico. Human and Ecological Risk Assessment., 22, 323–336.
RoyChowdhury, A., Sarkar, D., & Datta, R. (2015). Remediation of Acid Mine Drainage-Impacted Water. Current Pollution Reports, 1, 131–141.
Salomonas, W., & DeGoort, A. J. (1987). Pollution history of trace elements, as affected by the Rhine River. In W. E. Krumbein (Ed.), Environment Biochem (Vol. 1, pp. 62–149). Maine: Ann Arbor Science Publications.
Shen, F., Mao, L., Sun, R., Du, J., Tan, Z., & Ding, M. (2019). Contamination evaluation and source identification of heavy metals in the sediments from the Lishui River watershed Southern China. Environment Research Public Health. https://doi.org/10.3390/ijerph16030336
Singh, K. P., Mohan, M., Singh, V. K., & Malik, M. (2005). Studies on distribution and fractionation of heavy metals in Gomati river sediment—a tributary of the Ganges. India Journal of Hydrology, 312, 14–27.
Singh, M., Müller, G., & Singh, I. B. (2002). Heavy metals in freshly deposited stream sediments of rivers associated with urbanization of the Ganga Plain, India. Water, Air, & Soil Pollution, 141, 35–54.
Skousen, J.G., Ziemkiewicz, P. (2005). Performance of 116 passive treatment systems for acid mine drainage. In Proceedings america society of mining and reclamation, pp. 1100–1133
Tavakoly, S. S., Hashim, R., Rezayi, M., Salleh, A., & Safari, O. (2014). A review of strategies to monitor water and sediment quality for a sustainability assessment of marine environment. Environmental Science and Pollution Research., 21, 813–833.
Tomlinson, D., Wilson, J., Harris, C., & Jeffery, D. (1980). Problems in the assessment of heavy-metal levels in estuaries and the formation of a pollution index. Helgoland Marine Research, 33, 566–575.
US Environmental Protection Agency (USEPA). (2012). Integrated risk information system of the US environmental protection agency.
US Environmental Protection Agency (USEPA). (2002). Supplemental guidance for developing soil screening levels for superfund sites, OSWER 9355. Washington: Office of Emergency and Remedial Response.
Uugwanga, M. N., & Kgabi, N. A. (2020). Assessment of metals pollution in sediments and tailings of Klein Aub and Oamites mine sites Namibia. Environmental Advances, 2, 100006.
Viers, J., Dupré, B., & Gaillardet, J. (2009). Chemical composition of suspended sediments in world rivers: New insights from a new database. Science of the Total Environment., 407, 853–868.
Wang, F., & Chen, J. S. (2000). Relation of sediment characteristics to trace metal concentration: a statistical study. Water Research, 34, 694–698.
Wang, Y., Yang, L., Kong, L., Liu, E., Wang, L., & Zhu, J. (2014). Spatial distribution, ecological risk assessment and source identification for heavy metals in surface sediments from Dongping Lake, Shandong, East China. CATENA, 125, 200–205.
Wedepohl, K. H. (1995). The composition of the continental crust. Geochimica Et Cosmochimica Acta, 59(7), 1217–1232.
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The authors appreciate the financial support provided by the Research and Development Division of the Sarcheshmeh Copper Complex. We also wish to thank the management of Dar-e-Allo copper mine for cooperation in sampling and analysis.
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Supervision, AM and MT; Writing—original draft, HB; Writing—review and editing, MHMG, RMH, and HZM.
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Bavi, H., Gharaie, M.H.M., Moussavi-Harami, R. et al. Spatial dispersion hot spots of contamination and human health risk assessments of PTEs in surface sediments of streams around porphyry copper mine, Iran. Environ Geochem Health 45, 3907–3931 (2023). https://doi.org/10.1007/s10653-022-01471-x
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DOI: https://doi.org/10.1007/s10653-022-01471-x