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Impact of Mining Activity on Soils and Plants in the Vicinity of a Zn-Pb Mine (Draa Lasfar, Marrakech - Morocco) | ||
Pollution | ||
دوره 9، شماره 2، تیر 2023، صفحه 615-627 اصل مقاله (689.77 K) | ||
نوع مقاله: Original Research Paper | ||
شناسه دیجیتال (DOI): 10.22059/poll.2022.348075.1606 | ||
نویسندگان | ||
Elhaya Nassima1؛ Abdelaziz Ait Melloul2؛ Flata khadija* 2؛ El-Fadeli Sana3؛ Alain Pineau4؛ Yassir Barkouch1 | ||
1Laboratory of computer mathematics and modeling of complex systems , Higher School of Technology of Essaouira, Cadi Ayyad University, Km 9, Route of Agadir, Essaouira Aljadida BP.383, Essaouira, Morocco | ||
2Regional Laboratory for Epidemiological Diagnosis and Environmental Hygiene, Boulevard des Hôpitaux, Gueliz-Marrakesh, Morocco | ||
3Laboratory of Hydrobiology, Ecotoxicology and Sanitation, Department of Biology, Semlalia Faculty of Sciences, Prince My Abdellah Boulevard, BP: 2390, 40000-Marrakech, Morocco | ||
4UFR de Sciences Pharmaceutiques et Biologiques, Centre de Dosage des Eléments Minéraux (CDEM), 9 rue Bias, BP 53508, 44035 Nantes, France | ||
چکیده | ||
The pollution generated by metallic trace elements discharged by mines into the environment can become a very worrying source of contamination for soil, water and plants. The characterization of the chemical properties of metals in mine tailings and soils is of crucial importance to assess the risk of their potential mobility and therefore their bioavailability. In this paper, the bioavailability of metallic trace elements in agricultural soils in the vicinity of the Draa Lasfar mine in the northwest of Marrakech city (Morocco) was studied by determining the contents of Cd, Cu, Pb and Zn in soils and in two plants: wheat (main food for the human population) and couch grass (main food for livestock). The results showed that these metals move from agricultural land to plants. They also showed that couch grass seems to strongly absorb and accumulate metallic trace elements present in the soil; it removes considerable amounts of metallic trace elements from the soil with its deeply penetrating root system. | ||
کلیدواژهها | ||
Mine activity؛ metallic trace elements؛ tailings؛ pollution. Morocco | ||
مراجع | ||
Aikpokpodion, P.E., Lajide, L. and Aiyesanmi, A.F., (2013). Characterization of Heavy Metal Fractions in Agrizcultural Soils Using Sequential Extraction Technique. World. J. Agric. Sci, 9 (1), 45-52. Al-Heety ,L., Hasan, O., Salah Al-Heety, E. (2021). Assessment of heavy metal pollution of plants grown adjacent to power generators in Ramadi city. Earth and Environmental Science, 779 : 012023. Ashraf, M., Maah, M.J., Yusoff, I., (2011). Heavy metals accumulation in plants growing in ex tin mining catchment. International Journal of Environmental Science and Technology, 8 (2), 401-416. Avila, M., Perez, G., Esshaimi, M., Mandi, L., Ouazzani, N., Brianso, J.L. and Valiente, M., (2012), Heavy Metal Contamination and Mobility at the Mine Area of Draa Lasfar (Morocco). Open Environ Pollut Toxicol J, 3, (1), pp 2-12. Boularbah, A., Schwartz, C., Bitton, G., Aboudrar, W., Ouhammou, A., Morel, J., (2006). Heavy metal contamination from mining sites in South Morocco: 2. Assessment of metal accumulation and toxicity in plants. Chemosphere, 63, 811–817. Barkouch, Y. and Pineau. A., (2016), Evaluation of the Impact of Mine Activity on Surrounding Soils of Draa Lasfar Mine in Marrakech-Morocco. African J Environ Sci Tech, 10, pp 44-49. Barkouch, Y., El Fadeli, S., Khadiri, M, and Pineau, A., (2015A). Study of potential environmental risk of trace metallic elements in mine tailings: Case of Draa Lasfar functional mine in Marrakech – Morocco. African Journal of Agricultural Research, 10(33), pp 3246-3252. Barkouch, Y., Harrak, R., Lakmichi, H., Khadiri, M., Ait Melloul, A., Pineau A. (2015B). Study of speciation of four Heavy metals in Agricultural soils around the abandoned mine of Sidi Bou Othmane - Marrakech (Morocco).Research Journal of Chemical and Environmental Sciences, 3 (3), 36-43. Chen, C.Y., Stemberger, R, Bjorn, K., Blum, J., Pickhardt, P., Folt, C. (2020).Accumulation of heavy metals in food web components across a gradient of lakes, Limnology and Oceanography, 45(7), 1525–1536. Conesa, H. M., Faz, A., Arnaldos, R., (2006). Heavy metal accumulation and tolerance in plants from mine tailings of the semiarid Cartagena-La Union mining district. Science Total Environment, 366 (1), 1–11 Cuong, T.D. and Obbard, J.P. (2006). Metal speciation in coastal marine sediments from Singapore from Singapore using a modified BCR-sequential extraction procedure. Appl Geochem, 21, 1335-1346. Dawson, E.J. and Macklin, M.G. (1998). Speciation of heavy metals in floodplain and flood sediments: a reconnaissance survey of the Aire Valley, West Yorkshire, Great Britain Environ Geochem Health, 20, 67-76. De Matos, A.T., Fontes, M.P.F., Da Costa, L.M., Martínez, M.A., (2001). Mobility of heavy metals as related to soil chemical and mineralogical characteristics of Brazilian soils. Environ Pollut, 111: 429-35. Giacalone, A., Gianguzza, A., , Santino. O., Piazzese, D., Gaetano, D., Sciarrino, S. and Varrica, Daniela, (2005). Metals distribution in the organic and inorganic fractions of soil: a case study on soils from Sicily. Chem Speciat Bioavailab, 17(3), pp 83-93. Jihong ,D., Min, Y., Zhengfu, B., Yindi, Z., Wei, C., (2012). The safety study of heavy metal pollution in wheat planted in reclaimed soil of mining areas in Xuzhou, China. Environmental Earth Sciences, 66:673–682. Kemajl, B., Hazbije, S., Jeton, H., Mentor, B., Ilir, M. (2021). Effect of Mining Activity in Accumulation of Heavy Metals in Soil and Plant (Urtica dioica L). Journal of Ecologica Engineering, 22(1): 1-7. Main Uddin, M., Cassim, M., Zakeel, M., Zavahir J., Faiz M., Marikar, T. and Jahan, I. (2021). Heavy Metal Accumulation in Rice and Aquatic Plants Used as Human Food: A General Review, Toxics, 9 (360), 1-19 Maqbool, A., Xiao, X., Wang, H., Bian, Z. , Akram, M.W., (2019). Bioassessment of Heavy Metals in Wheat Crop from Soil and Dust in a Coal Mining Area. Pollution, 5(2): 323-337. Marcoux E., Belkabir A., Gibson H.L., Lentz D. and Ruffet G. (2008). Draa Sfar, Morocco: A Visean (331 Ma) pyrrhotite-rich, polymetallic volcanogenic massive sulphide deposit in a Hercynian sediment-dominant terrane. Ore Geology Reviews, 33, 307-328. Mullins, G.L. and Burmester, C.H. (1991). Cotton accumulates small amounts of copper, iron, manganese and zinc. Better Crops Plant Food 4, 6–8. Okogwu, O.I., Nwonumara, G.N., Okoh, F.A. (2019). Evaluating of metallic trace elements Pollution and Exposure Risk Through the Consumption of Four Commercially Important Fish Species and Water from Cross River Ecosystem, Nigeria. Bull. Environ. Contam. Toxicol., 102, 867–872. Rada, A., El Gharmali, A., El Meray, M., Morel, J.L. (1996). Bioavailability of Cd and Cu in two soils from the sewage from Marrakech city (Morocco) – Effect of earthworms. Agromedecine., 124 (4), 364-368. Rahimi G., Kolahchi Z., Charkhabi A. (2017). Uptake and translocation of some heavy metals by rice crop (Oryza Sativa) in paddy soils, Agriculture (Poľnohospodárstvo), 63 (4), 163−175. Rajeshkumar, S., Li, X. (2018). Bioaccumulation of heavy metals in fish species from the Meiliang Bay, Taihu Lake, China. Toxicol. Rep. 5, 288–295. Rehman, A.U., Nazir, S., Irshad, R., Tahir, K., Rehman, K.U., Islam, R.U., Wahab, Z. (2021). Toxicity of heavy metals in plants and animals and their uptake by magnetic iron oxide nanoparticles. J. Mol. Liq., 321, 114455. Sahuquillo, A., Rigol, A. and Rauret, G. (2003). Overview of the use of leaching/extraction tests for risk assessment of trace metals in contaminated soils and sediments, Trend. Anal. Chem., 22(3), 152-159. Santillan, L.F.J., Constantino, C.A.L., Rodriguez, G.A.V., Ubilla, N.M.C., Hernandez, R.I.B. (2010). Manganese accumulation in plants of the mining zone of Hidalgo, Mexico. Bioresearch and Technology, 101 (15): 5836-5841. Shah F.U.R., Ahmad N., Masood K.R., Jose P.V., Feroz U.A., (2010). Heavy metal toxicity in plants,” Plant Adaptation and Phytoremediation, pp. 71-97. Springer. Shepard, F.P., and Moore, D.G., (1954). Sedimentary environments differentiated by coarse fraction studies: Bull. Am. Assoc. Petrol. Geologists., 38, 1792-1802. Stadman, T.C., (2002). Discoveries of vitamin B12 and selenium enzymes. Ann. Rev. Biochem. 71, 1-16. Wang, C., Li, C.X., Ma, H.T., Qian, J., Zhai. J.B., (2006). Distribution of extractable fractions of heavy metals in sludge during the wastewater treatment process. J. Hazard. Mater 137:1277–1283. Wang-da C., Guo-ping Z., Hai-gen Y., Wei W., Min X. (2006). Genotypic and environmental variation in cadmium, chromium, arsenic, nickel, and lead concentrations in rice grains. In Journal of Zhejiang University Science B., 7(7), 565–571. Wahsha, M., Maleci, L., Bini C., (2019). The impact of former mining activity on soils and plants in the vicinity of an old mercury mine (Vallalta, Belluno, NE Italy). Geochemistry: Exploration, Environment, Analysis, 19 : 171–175. Watson, J.E., Pepper, I.L., Unger, M. and Fuller, W.H. (1985). Yields and leaf elemental composition of cotton grown on sludge amended soil. J. Environ. Qual. 14, 174– 177. Wu, C. Zhang, L. (2010). Heavy metal concentrations and their possible sources in paddy soils of a modern agricultural zone, southeastern China. Environ Earth Sci, vol. 60, 45–56. Yang, P. Mao, R. Shao, H. Gao, Y. (2009). An investigation on the distribution of eight hazardous heavy metals in the suburban farmland of China. J Hazard Mat, 167, 1246–1251. Yang, X., Feng, Y., He, Z., Stofella, P.J. (2005). Molecular mechanisms of heavy metal hyperaccumulation and phytoremediation. J. Trace Elem. Med. Biol. 18, 339–353. Yazdi, M., Narges, B., (2009A). Geochemical Contamination in Seyab river, Islam Shahr, Iran, Environmental Sciences Quarterly (ESQ), 6, 55-65. Yazdi, M., Narges, B., (2009B). Geochemical Contamination and distribution in the Park City of Islam Shahr SW of Tehran, Iran, The Open Environmental Pollution and Toxicology Journal (OEPTJ), 2,49- 53. Zhang, W., Cai, Y., Tu, C., Ma, L.Q. (2002). Arsenic speciation and distribution in an arsenic hyperaccumulating plant. Science Total Environment, 300 (1-3): 167–177. Zhu, G., Noman, A., Narale, D.D., Feng,W., Pujari, L., Sun, J. (2020). Evaluation of ecosystem health and potential human health hazards in the Hangzhou Bay and Qiantang Estuary region through multiple assessment approaches. Environ. Pollut., 264, 114791. | ||
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