Abstract
Continuous deposition from Khatoon Abad smelter stack particulates has resulted in trace elements contamination in soil. To investigate the regional distribution and fractionation of trace elements in soils, soil samples were collected and examined. The results demonstrate that the highest trace element concentrations in top soil are: >10000 mg Cu kg-1, 2000 mg Mo kg-1, >10000 mg Zn kg-1, 2694.2 mg As kg-1, 2006.2 mg Pb kg-1, 420.4 mg Sb kg-1, and 90.7 mg Cd kg-1. The concentrations of the trace elements are much higher than the normal concentrations in the uncontaminated soil and geochemical background. The most contaminated areas are located in the vicinity of smelter in the prevailing wind directions. Calculated geoaccumulation index and contamination load index indicate surface soil enrichment in potentially toxic metals (Cu, Mo, As, Sb, Cd, Zn, and Pb). Combined multivariate statistical and geostatistical methods successfully separate the contaminant metals (As, Cd, Cu, Pb, Sb, Mo, and Zn) from the uncontaminated ones (Al, Fe, Mn, and Cr). Furthermore, it was found that the As, Cd, Cu, Pb, Sb, Mo, and Zn mainly come from the copper smelter. The modified BCR three-step sequential extraction technique was applied to assess the four fractions (residual, acid, reducible and oxidizable) in smelter dust and surface soil samples. The results demonstrate that a high proportion of Cu, Mo, As, Pb, Sb, and Zn is extracted in the mobile fractions, indicating high mobility and probably hazardous environmental consequences.
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References
Baize, D. & Sterckeman, T. Of the necessity of knowledge of the natural pedo-geochemical background content in the evaluation of the contamination of soils by trace elements. Sci. Total Environ. 264, 127–139 (2001).
Diatta, J. B., Chudzinska, E. & Wirth, S. Assessment of heavy metal contamination of soils impacted by a zinc smelter activity. Elementol. 13, 5–16 (2008).
Martley, E., Gulson, B. L. & Pfeifer, H. R. Metal concentrations in soils around the copper smelter and surrounding industrial complex of Port Kembla, NSW, Australia. Sci. Total Environ. 325, 113–127 (2004).
Hu, N., Li, Z., Huang, P. & Tao, C. Distribution and mobility of metals in agricultural soils near a copper smelter in South China. Environ. Geochem. Hlth. 28, 19–26 (2006).
Cubukcu, A. & Tuysuz, N. Trace element concentrations of soils, plants, and waters caused by a copper smelting plant and other industries, Northeast Turkey. Environ. Geol. 52, 93–108 (2007).
Duan, L. Q. et al. Distribution, chemical speciation and source of trace elements in surface sediments of the Changjiang Estuary. Environ. Earth Sci. 72, 3193–3204 (2014).
Siegel, F. in Environmental geochemistry of potentially toxic metals (Springer Press, Amsterdam, 2002).
Barcan, V. Nature and origin of multicomponent aerial emissions of the copper-nickel smelter complex. Environ. Int. 28, 451–456 (2002).
Rawlins, B. G., Lark, R. M., Webster, R. & O’Donnell, K. E. The use of soil survey data to determine the magnitude and extent of historic metal deposition related to atmospheric smelter emissions across Humberside, UK. Environ. Pollut. 143, 416–426 (2006).
Parra, S. et al. Distribution of trace elements in particle size fractions for contaminated soils by a copper smelting from different zones of the Puchuncaví Valley (Chile). Chemosphere 111, 513–521 (2014).
Ding, Z. H. & Hu, X. Ecological and human health risks from metal(loid)s in peri-urban soil in Nanjing, China. Environ. Geochem. Hlth. 36, 399–408 (2014).
Selinus, O. et al. in Essentials of medical geology: impacts of the natural environment on public health (Elsevier Academic Press, Amsterdam, 2005).
Mico, C., Recatala, L., Peris, M. & Sanchez, J. Assessing heavy metal sources in agricultural soils of an European Mediterranean area by multivariate analysis. Chemosphere 56, 863–872 (2006).
Larner, B. L., Seen, A. J. & Townsend, A. T. Comparative study of optimized BCR sequential extraction scheme and acid leaching of elements in the certified reference material NIST 2711. Analytica. Chimica. Acta 556, 444–449 (2006).
Kabala, C. & Singh, B. R. Distribution and forms of Cadmium in soils near a copper smelter. Polish J. Environ. Stud. 15, 90–97 (2006).
Herreweghe, S. V., Swennen, R., Vandecasteele, C. & Cappuyns, V. Solid phase speciation of arsenic by sequential extraction in standard reference materials and industrially contaminated soil samples. Environ. Pollut. 122, 323–342 (2003).
Sulkowski, M. & Hirner, A. V. Element fractionation by sequential extraction in a soil with high carbonate content. Appl. Geochem. 21, 16–28 (2006).
Burt, R. et al. Trace element speciation in selected smelter-contaminated soils in Anaconda and Deer Lodge Valley, Montana, USA. Adv. Environ. Res. 8, 51–67 (2003).
Schramel, O., Michalke, B. & Kettrup, A. Study of the copper distribution in contaminated soils of hop fields by single and sequential extraction procedures. Sci. Total Environ. 263, 11–22 (2000).
Kaasalainen, M. & Yli-Halla, M. Use of sequential extraction to assess metal partitioning in soils. Environ. Pollut. 126, 225–233 (2003).
Anju, M. & Banerjee, D. K. Comparison of two sequential extraction procedures for heavy metal partitioning in mine tailings. Chemosphere 78, 1393–1402 (2010).
Pueyo, M. et al. Use of the modified BCR three-step sequential extraction procedure for the study of trace element dynamics in contaminated soils. Environ. Pollut. 152, 330–341 (2008).
Mozaffari, A. A., Derakhshanfar, A. & Salar-Amoli, J. Industrial Copper Intoxication of Iranian Fat-Tailed Sheep in Kerman Province, Iran. Turk. J. Vet. Anim. Sci. 33, 113–119 (2009).
Sakhaee, E., Behzadi, M. J. & Shahrad, E. Subclinical copper poisoning in asymptomatic people in residential area near copper smelting complex. Asian Pac. J. Trop. Dis. 2, 475–477 (2012).
Mäkinen, J. in Eco-efficient Solutions in the Finnish Metallurgical Industry; Challenges of Eco-efficiency (VTT Espoo Press, Finland, 2006).
Karimi, N., Vaghar, R., Tavakoli-Mohammadi, M. R. & Hashemi, S. A. Recovery of Copper from the Slag of Khatoonabad Flash Smelting Furnace by Flotation Method. J. Inst. Eng. India Ser. 94, 43–50 (2013).
Moradi, A., Abbaspour, K. C. & Afyuni, M. Modeling field-scale cadmium transport below the root zone of a sewage sludge amended soil in an arid region in Central Iran. J. Contam. Hydrol. 79, 187–206 (2005).
Kabata-Pendias, A. & Pendias, H. in Trace elements in soils and plants 3th Edn (CRC Press, Boca Raton, 2001).
Ure, A. M. & Berrow, M. L. in The elemental constituents of soils (eds Bowen, H. J. et al.) 94–204 (Royal Society of Chemistry, London, 1982).
Shepard, F. P. Nomenclature based on sand-silt-clay ratios. J. Sediment. Petrol. 24, 151–158 (1954).
McCauley, A. in Basic soil properties (Montana State University Press, United States, 2005).
Tomlinson, D. C., Wilson, J. G., Harris, C. R. & Jeffrey, D. W. Problems in the assessment of heavy-metal levels in estuaries and the formation of a pollution index. Helgoland. Mar. Res. 33, 566–575 (1980).
Barona, A., Aranguiz, I. & Elias, A. Assessment of metal extraction and contamination in surface soils by 3-step sequential extraction procedure. Chemosphere 39, 1911–1922 (1999).
Ma, H., Hua, L. & Ji, J. Speciation and phytoavailability of heavy metals in sediments in Nanjing section of Changjiang River. Environ. Earth Sci. 64, 185–192 (2011).
Fordyce, F. M., Zhang, G., Green, K. & Liu, X. Soil, grain and water chemistry in relation to human selenium responsive diseases in Enshi District, China. Appl. Geochem. 15, 117–132 (2000).
Muller, G. Die Schwermetallbelstang der sediment des Neckarars und seiner N ebenflusseeine estandsaufnahme. Chemical Zeitung 105, 157–164 (1981).
Shikazono, N. et al. Sources, spatial variation, and speciation of heavy metals in sediments of the Tamagawa River in Central Japan. Environ. Geochem. Hlth. 34, 13–26 (2012).
Gallego, J. L., Ordonez, A. & Loredo, J. Investigation of trace element sources from an industrialized area (Aviles, northern Spain) using multivariate statistical methods. Environ. Int. 27, 589–596 (2002).
Keshavarzi, B. et al. Quality of drinking water and high incidence rate of esophageal cancer in Golestan province of Iran: a probable link. Environ. Geochem. Hlth. 34, 15–26 (2011).
Breward, N. & Peachey, D. The development of a rapid scheme for the elucidation of the chemical speciation of the elements in sediments. Sci. Total Environ. 29, 155–162 (1983).
Rauret, G., Rubio, R. & Lopez-Sanchez, J. F. Optimization of Tessier procedure for metal solid speciation in river-sediments. Int. J. Environ. Anal. Chem. 36, 69–83 (1989).
Oughton, D. H. et al. Radionuclide mobility and bioavailability in Norwegian and Soviet soils. Analyst. 117, 481–486 (1992).
Hall, G. M., Vaive, J. E., Beer, R. & Hoashi, M. Selective leaches revisiited, with emphasis on the amorphous Fe oxyhydroxide phase extraction. J. Geochem. Explor. 56, 59–78 (1996).
Sutherland, R. A. Bed sediment-associated trace metals in an urban stream, Oahu, Hawaii. Environ. Geol. 39, 611–627 (2000).
Rauret, G. et al. Improvement of the BCR three step sequential extraction procedure prior to the certification of new sediment and soil reference materials. J. Environ. Monitor. 1, 57–61 (1999).
Cuong, D. & Obbard, J. P. Metal speciation in coastal marine sediments from Singapore using a modified BCR-sequential extraction procedure. Appl. Geochem. 21, 1335–1346 (2006).
Ettler, V. et al. Antimony mobility in lead smelter-polluted soils. Geoderma 155, 409–418 (2010).
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Keshavarzi, B., Moore, F. & Estahbanati, N.A. Soil trace elements contamination in the vicinity of Khatoon Abad copper smelter, Kerman province, Iran. Toxicol. Environ. Health Sci. 7, 195–204 (2015). https://doi.org/10.1007/s13530-015-0238-9
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DOI: https://doi.org/10.1007/s13530-015-0238-9