Abstract
Purpose
The present work concerns the distribution of ten heavy metals (Sb, As, Cd, Cr, Cu, Hg, Mn, Ni, Pb, and Zn) in the surrounding agricultural soils of the world largest antimony (Sb) mine in China. The objective is to explore the degree and spatial distribution of heavy metal pollution of the Sb mine-affected agricultural soils. The presented data were compared with metal concentrations in soils from mining and smelting sites in China and other countries.
Materials and methods
There were 29 environmental samples in all that were collected in the year 2008 for this study. Soil characteristic parameters such as pH, total organic carbon, and cation exchange capacity were determined. Metal contents were determined after digestion in a Teflon bomb with aqua regia. Cd, Cu, Ni, Pb, and Zn concentrations were determined by inductively coupled plasma–mass spectrometry. As, Sb, and Hg concentrations were determined by atomic fluorescence spectrometry (AFS-2202). Fe, Al, Cr, and Mn concentrations were determined by inductively coupled plasma–atomic emission spectrometry.
Results and discussion
Almost all of the ten heavy metals exhibited much higher concentrations compared with their respective natural background values, especially Sb, and they varied with sampling site. The enriched factor values show that Sb (235.8), Cd (51.8), Hg (13.8), As (3.13), Zn (2.91), Pb (2.46), and Cr (1.67) are significantly accumulated in the study area. All of the integrated pollution indexes (IPI > 3) calculated from pollution indexes show that the soils are severely contaminated by investigated heavy metals.
Principal component analysis, cluster analysis, and correlation analysis suggest that Cd, Cu, Pb, Zn, and Mn are derived from the sulfide mineralization paragenesis in Xikuangshan area. Cr, As, Hg, Al, and Sb are mainly due to the mining and smelting activities of this area and derived from organic matters, and Ni is mainly generated from agricultural activities. These metal concentrations in Xikuangshan agricultural topsoil are comparable or within the ranges of those in mine areas of other countries.
Conclusions
The heavy metal concentrations in the topsoil of Xikuangshan area are mostly higher than the background values, especially for Sb and As. Heavy metal pollution has spread in this mine area, both from mining activities and agricultural activities. Analysis of soil samples from 23 sampling locations of the area show significant spatial variation of the ten heavy metals.
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References
Adriano DC (1986) Trace elements in the terrestrial environment. Springer, New York
Bailey EA, Gray JE, Theodorakos PM (2002) Mercury in vegetation and soils at abandoned mercury mines in southwestern Alaska, USA. Geochem: Explor, Environ, Anal 2:275–285
Bak J, Jensen J, Larsen MM, Pritzl G, Scott-Fordsmand J (1997) A heavy metal monitoring-programme in Denmark. Sci Total Environ 207:179–186
Bech J, Poschenrieder C, Llugany M, Barceló J, Tume P, Tobias FJ, Barranzuela JL, Vásquez ER (1997) Arsenic and heavy metal contamination of soil and vegetation around a copper mine in Northern Peru. Sci Total Environ 203:83–91
Bhuiyan MAH, Parvez L, Islam MA, Dampare SB, Suzuki S (2010) Heavy metal pollution of coal mine-affected agricultural soils in the northern part of Bangladesh. J Hazard Mater 173(1–3):384–392
Blaser P, Zimmermann S, Luster J, Shotyk W (2000) Critical examination of trace element enrichments and depletions in soils: As, Cr, Cu, Ni, Pb, and Zn in Swiss forest soils. Sci Total Environ 249:257–280
Bowen HJM (1979) Environmental chemistry of the elements. Academic Press, New York
Chen M, Ma L-Q, Harris W-G (1999) Baseline concentrations of 15 trace elements in Florida surface soils. J Environ Qual 28:1173–1181
Chen T-B, Zheng Y-M, Lei M, Huang Z-C, Wu H-T, Chen H, Fan K-K, Yu K, Wu X, Tian Q-Z (2005) Assessment of heavy metal pollution in surface soils of urban parks in Beijing, China. Chemosphere 60:542–551
Chen TB, Wong JWC, Zhou HY, Wong MH (1997) Assessment of trace metal distribution and contamination in surface soils of Hong Kong. Environ Pollut 96:61–68
Dudka S, Ponce-Hernandez R, Hutchinson TC (1995) Current level of total element concentrations in the surface layer of Sudbury's soils. Sci Total Environ 162:161–171
Ettler V, Mihaljevic M, Sebek O, Nechutn Z (2007) Antimony availability in highly polluted soils and sediments—a comparison of single extractions. Chemosphere 68:455–463
Facchinelli A, Sacchi E, Mallen L (2001) Multivariate statistical and GIS-based approach to identify heavy metal sources in soils. Environ Pollut 114:313–324
Fan D, Zhang T, Ye J (2004) The Xikuangshan Sb deposit hosted by the Upper Devonian black shale series, Hunan, China. Ore Geol Rev 24:121–133
Fergusson JE (1990) The heavy elements: chemistry, environmental impact and health effects. Pergamon Press, Oxford
Flynn HC, Meharg AA, Bowyer PK, Paton GI (2003) Antimony bioavailability in mine soils. Environ Pollut 124:93–100
Gotelli NJ, Ellison AM (2004) A primer of ecological statistics. Sinauer Associates, Sunderland, p 492
Han Y, Du P, Cao J, Posmentier ES (2006) Multivariate analysis of heavy metal contamination in urban dusts of Xi'an, Central China. Sci Total Environ 355:176–186
He MC (2007) Distribution and phytoavailability of antimony at an antimony mining and smelting area, Hunan, China. Environ Geochem Health 29:209–219
He MC, Yang JR (1999) Effects of different forms of antimony on the rice during the period of germination and growth and antimony concentration in rice tissue. Sci Total Environ 243–244:189–196
Imperato M, Adamo P, Naimo D, Arienzo M, Stanzione D, Violante P (2003) Spatial distribution of heavy metals in urban soils of Naples city (Italy). Environ Pollut 124:247–256
Jiang D-Z, Teng E-J, Liu Y-L (1996) The contribution of difference on the element background values in soils and the analysis of variance of single factor on soil groups. Environ Monit China 2:21–24
Jung MC, Thornton I (1996) Heavy metal contamination of soils and plants in the vicinity of a lead–zinc mine, Korea. Appl Geochem 11:53–59
Kabata-Pendias A, Pendias H (1992) Trace elements in soils and plants. CRC Press, Boca Raton
Kennish MJ (1992) Ecology of estuaries: anthropogenic effects. CRC Press, Boca Raton, p 494
Klein DH (1972) Trace elements in soil of the metropolitan area of Grand Rapids, Michigan (USA). Environ Sci Technol 6:560–562
Lee BD, Carter BJ, Basta NT, Weaver B (1997) Factors influencing heavy metal distribution in six Oklahoma benchmark soils. Soil Sci Soc Am J 61:218–223
Lee CG, Chon H-T, Jung MC (2001) Heavy metal contamination in the vicinity of the Daduk Au–Ag–Pb–Zn mine in Korea. Appl Geochem 16:1377–1386
Li L, Liang L, Liu C, Zhang L, Jiang D, Li J (2007) Analysis and strategy of drinking water pollution accidents in recent 20 years in China. Acta Geographica Sinica 62:917–924 (in Chinese)
Li X, Thornton I (1993) Multi-element contamination of soils and plants in old mining areas, UK. Appl Geochem 8:51–56
Ma LQ, Tan F, Harris WG (1997) Concentrations and distributions of eleven elements in Florida soils. J Environ Qual 26:769–775
Mandal BK, Suzuki KT (2002) Arsenic round the world: a review. Talanta 58:201–235
Muller G (1969) Index of geoaccumulation in sediments of the Rhine River. Geojournal 2:108–118
Müller K, Daus B, Mattusch J, Stärk H-J, Wennrich R (2009) Simultaneous determination of inorganic and organic antimony species by using anion exchange phases for HPLC–ICP–MS and their application to plant extracts of Pteris vittata. Talanta 78:820–826
Murciego AM, Sánchez AGa, González MARg, Gil EP, Gordillo CT, Fernández JC, Triguero TB (2007) Antimony distribution and mobility in topsoils and plants (Cytisus striatus, Cistus ladanifer and Dittrichia viscosa) from polluted Sb-mining areas in Extremadura (Spain). Environ Pollut 145:15–21
Navarro MC, Pérez-Sirvent C, Martínez-Sánchez MJ, Vidal J, Tovar PJ, Bech J (2007) Abandoned mine sites as a source of contamination by heavy metals: a case study in a semi-arid zone. J Geochem Explor 96:183–193
Onishi H (1977) Arsenic. In: Wedepohl KH (ed) Handbook of geochemistry, Sect. 33d-2. Springer, Berlin
Peng C, Tang M (2001) Prevention of arsenic pollution and development and application of wood antiseptic containing arsenic. J Safe Environ 1:10–13 (in Chinese)
Pichtel J, Sawyerr HT, Czarnowska K (1997) Spatial and temporal distribution of metals in soils in Warsaw, Poland. Environ Pollut 98:169–174
Qiu G, Feng X, Wang S, Shang L (2006) Environmental contamination of mercury from Hg-mining areas in Wuchuan, northeastern Guizhou, China. Environ Pollut 142:549–558
Rodríguez L, Ruiz E, Alonso-Azcárate J, Rincón J (2009) Heavy metal distribution and chemical speciation in tailings and soils around a Pb–Zn mine in Spain. J Environ Manage 90:1106–1116
Senesil GS, Baldassarre G, Senesi N, Radina B (1999) Trace element inputs into soils by anthropogenic activities and implications for human health. Chemosphere 39:343–377
Shi M, Fu B, Jin X, Zhou X (1993) The antimony metallogeny in central part of Hunan province. Hunan Science and Technology Press, Changsha, in Chinese with English abstract
Smith E, Naidu R, Alston AM (2002) Heavy metals in the environment chemistry of inorganic arsenic in soils: II Effect of phosphorus, sodium, and calcium on arsenic sorption. J Environ Qual 31:557–563
Stevenson J, Welch L (1982) Humus chemistry: genesis, compositon, reactions. Wiley, New York
Sutherland RA (2000) Bed sediment-associated trace metals in an urban stream, Oahu, Hawaii. Environ Geol 39:611–627
Szefer P, Szefer K, Glasby G, Pempkowiak J (1996) Heavy-metal pollution in surficial sediments from the southern Baltic Sea off Poland. J Environ Sci Health 31A:2723–2754
Taylor SR (1964) Abundance of chemical elements in the continental crust: a new table. Geochimica et Cosmochimica Acta 28:1273–1285
Tomlinson DL, Wilson JG, Harris CR, Jeffrey DW (1980) Problems in the assessment of heavy-metal levels in estuaries and the formation of a pollution index. Helgoland Marine Res 33:566–575
Vink BW (1996) Stability relations of antimony and arsenic compounds in the light of revised and extended Eh-pH diagrams. Chem Geol 130:21–30
Wilson NJ, Craw D, Hunter K (2004) Antimony distribution and environmental mobility at an historic antimony smelter site, New Zealand. Environ Pollut 129:257–266
Zhang M, Cui L, Sheng L, Wang Y (2009) Distribution and enrichment of heavy metals among sediments, water body and plants in Hengshuihu Wetland of Northern China. Ecol Eng 35:563–569
Zhu J, Wu F-C, Deng Q-J, Shao S-X, Mo C-L, Pan X-L, Li W, Zhang R-Y (2009) Environmental characteristics of water near the Xikuangshan antimony mine. Acta Scientiae Circumstantiae 29:655–661 (in Chinese)
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This work was supported by the National Natural Science Foundation of China (40873077, 20777009)
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Responsible editor: Caixian Tang
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Wang, X., He, M., Xie, J. et al. Heavy metal pollution of the world largest antimony mine-affected agricultural soils in Hunan province (China). J Soils Sediments 10, 827–837 (2010). https://doi.org/10.1007/s11368-010-0196-4
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DOI: https://doi.org/10.1007/s11368-010-0196-4