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Ecological and health risks of heavy metal on farmland soils of mining areas around Tongling City, Anhui, China

  • Zhangjun ShenEmail author
  • Decong Xu
  • Lingling Li
  • Jingjing Wang
  • Xiaming Shi
Philippe Garrigues

Abstract

To investigate and assess heavy metal contamination on the farmland soils of a typical mining city, the concentrations of Cu, Cd, Zn, Pb, As, and Cr were analyzed from four mining areas (Tongguan District (TGD), Shunan Town (SAT), Tianmen Town (TMT), and Zhongmin Town (ZMT)) and two control areas (Xilian Township (XLT), Donglian Township (DLT)) in Tongling City, China. The total metal concentrations in the soils were in the following order: Cd ˂ As ≤ Pb ˂ Cu ˂ Cr ≤ Zn. Total metal concentrations in the soils of mining areas were significantly higher than those of the control areas (P < 0.05). According to the Chinese Environmental Quality Standard for Soils (GB 15618-1995) and geo-accumulation index (Igeo), Cd and As pollution in the farmland soils of the mining areas was the most severe, followed by Cu. The Igeo values of soil heavy metals of TGD and SAT were the most highest, followed by those of TMT and ZMT. The health risk quotient (HQ) of heavy metals in the soils showed as follows: HQAs ˃ HQPb ˃ HQCr ˃ HQCd ˃ HQCu ˃ HQZn, and the total average daily exposed dose (non-carcinogenic risk) of As was the highest except that of Cd. The contribution rate of carcinogenic risk index (CR) to total carcinogenic risk index (TCR) of As and Cd in the topsoil for adults was 99.91% and 0.09% respectively, and the value for children was 99.87% and 0.13%. The CR and TCR of As in the farmland of mining areas were greater than 10−4, which showed the carcinogenic risk is an intolerable range for both adults and children. According to the results of the present study, it can help the local people know the pollution of heavy metals in farmland and adopt the best suitable agriculture practices.

Keywords

Heavy metal Mining city Farmland soil Health risk 

Notes

Funding information

This work was supported by the Key Research and Development Project of Anhui Province, China (No.1804a07020121), the Natural Science Foundation of Anhui Province, China (No. 1808085MC80), and the Special Foundation for Young Scientists of Anhui Province, China (No. gxyqZD2016236).

References

  1. Anjos C, Magalhães MCF, Abreu MM (2012) Metal (Al, Mn, Pb and Zn) soils extractable reagents for available fraction assessment: comparison using plants, and dry and moist soils from the Braçal abandoned lead mine area, Portugal. J Geochem Explor 113:45–55CrossRefGoogle Scholar
  2. Bempah CK, Ewusi A (2016) Heavy metals contamination and human health risk assessment around Obuasi gold mine in Ghana. Environ Monit Assess 188:261CrossRefGoogle Scholar
  3. Bempah CK, Ewusi A, Obiri-Yeboah S, Asabere SA et al (2013) Distribution of arsenic and heavy metals from mine tailings dams at Obuasi Municipality of Ghana. Amer J Eng Res 2(5):61–70Google Scholar
  4. 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 173:384–392CrossRefGoogle Scholar
  5. Black A, McLaren RG, Reichman SM et al (2011) Evaluation of soil metal bioavailability estimates using two plant species (L. perenne and T. aestivum) grown in a range of agricultural soils treated with biosolids and metal salts. Environ Pollut 159:1523–1535CrossRefGoogle Scholar
  6. Elbana TA, Ramadan MA, Gaber HM, Bahnassy MH, Kishk FM, Selim HM (2013) Heavy metals accumulation and spatial distribution in long term wastewater irrigated soils. J Environ Chem Eng 1:925–933CrossRefGoogle Scholar
  7. Garcı’a-Lorenzo ML, Pe’rez-Sirvent C, Martı’nez-Sa´nchez MJ, Molina-Ruiz J (2012) Trace elements contamination in an abandoned mining site in a semiarid zone. J Geochem Explor 113:23–35CrossRefGoogle Scholar
  8. Hakanson L (1980) An ecological risk index for aquatic pollution control: a sedimentological approach. Water Res 14(8):975–1001CrossRefGoogle Scholar
  9. Halim MA, Majumder RK, Zaman MN (2015) Paddy soil heavy metal contamination and uptake in rice plants from the adjacent area of Barapukuria coal mine, northwest Bangladesh. Arab J Geosci 8:3391–3401CrossRefGoogle Scholar
  10. He BY, Ling L, Zhang LY, Li MR, Li QS, Mei XQ, Li H, Tan L (2015) Cultivar-specific differences in heavy metal (Cd, Cr, Cu, Pb, and Zn) concentrations in water spinach (Ipomoea aquatic ‘Forsk’) grown on metal-contaminated soil. Plant Soil 386:251–262CrossRefGoogle Scholar
  11. Ihedioha JN, Ukoha PO, Ekere NR (2017) Ecological and human health risk assessment of heavy metal contamination in soil of a municipal solid waste dump in Uyo, Nigeria. Environ Geochem Health 39:497–515CrossRefGoogle Scholar
  12. Jafaru HM, Dowuona GNN, Adjadeh TA, Nartey EK, Nude PM, Neina D (2015) Geochemical assessment of heavy metal pollution as impacted by municipal solid waste at Abloradjei waste dump site, Accra-Ghana. Res J Environ Earth Sci 7(3):50–59CrossRefGoogle Scholar
  13. Khan A, Khan S, Khan MA, Qamar Z, Waqas M (2015) The uptake and bioaccumulation of heavy metals by food plants, their effects on plants nutrients, and associated health risk: a review. Environ Sci Pollut Res 22:13772–13799CrossRefGoogle Scholar
  14. Kim JY, Kim KW, Ahn JS, Ko I, Lee CH (2005) Investigation and risk assessment modeling of As and other heavy metals contamination around five abandoned metal mines in Korea. Environ Geochem Health 27:193–203CrossRefGoogle Scholar
  15. Kluge B, Wessolek G (2012) Heavy metal pattern and solute concentration in soils along the oldest highway of the world—the AVUS autobahn. Environ Monit Assess 184:6469–6481CrossRefGoogle Scholar
  16. Li Z, Ma Z, van der Kuijp TJ et al (2014) A review of soil heavy metal pollution from mines in China: pollution and health risk assessment. Sci Total Environ 468–469:843–853.  https://doi.org/10.1016/j.scitotenv.2013.08.090 CrossRefGoogle Scholar
  17. Liang J, Liu JY, Yuan XZ, Zeng G, Lai X, Li X, Wu H, Yuan Y, Li F (2015) Spatial and temporal variation of heavy metal risk and source in sediments of Dongting Lake wetland, mid-south China. J Environ Sci Health, Part A: Tox Hazard Subst Environ Eng 50(1):100–108.  https://doi.org/10.1080/10934529.2015.964636 CrossRefGoogle Scholar
  18. Liu Q, Sun X, Hu AY, Zhang Y, Cao Z (2014) Characteristics of toxic metal accumulation in farmland in relation to long-term chicken manure application: a case study in the Yangtze River Delta Region, China. Bull Environ Contam Toxicol 92:279–284CrossRefGoogle Scholar
  19. Lu C, Wu YG, Hu SH, et al (2016a) Distribution and transport of residual lead and copper along soil profiles in a mining region of North China. Pedosphere 26: 848–860. DOI:  https://doi.org/10.1016/S1002-0160(15) 60090-X
  20. Lu C, Wu YG, Hu SH et al (2016b) Drying-wetting cycles facilitated mobilization and transport of metal-rich colloidal particles from exposed mine tailing into soil in a gold mining region along the Silk Road. Environ Earth Sci 75:1031.  https://doi.org/10.1007/s12665-016-5812-1 CrossRefGoogle Scholar
  21. McLaughlin MJ, Zarcinas BA, Stevens DP, Cook N (2000) Soil testing for heavy metals. Commun Soil Sci Plan 31:1661–1700CrossRefGoogle Scholar
  22. Moaref S, Sekhavatjou MS, Hosseini Alhashemi A (2014) Determination of trace elements concentration in wet and dry atmospheric deposition and surface soil in the largest industrial city, Southwest of Iran. Intern J Environ Res 8(2):335–346Google Scholar
  23. Muller G (1969) Index of geo-accumulation in sediments of the Rhine river. Geojournal 2:108–118Google Scholar
  24. Pan LB, Wang Y, Ma J, Hu Y, Su B, Fang G, Wang L, Xiang B (2018) A review of heavy metal pollution levels and health risk assessment of urban soils in Chinese cities. Environ Sci Pollut Res 25:1055–1069CrossRefGoogle Scholar
  25. Park JH, Chon HT (2016) Characterization of cadmium biosorption by Exiguobacterium sp. isolated from farmland soil near Cu-Pb-Zn mine. Environ Sci Pollut Res 23:11814–11822CrossRefGoogle Scholar
  26. Poggio L, Vrščaj B, Hepperle E, Schulin R, Marsan FA (2008) Introducing a method of human health risk evaluation for planning and soil quality management of heavy metal-polluted soils—an example from Grugliasco (Italy). Landsc Urban Plan 88(2–4):64–72CrossRefGoogle Scholar
  27. Qi YH (2006) Study on the spatial distribution and pollution assessment of heavy metal elements in soil of Tongling area based on GIS. Hefei: Hefei University of Technology, Master dissertation, 16–34 (in Chinese)Google Scholar
  28. Qiu ML, Li FB, Wang Q, Chen J, Yang G, Liu L (2015) Driving forces of heavy metal changes in agricultural soils in a typical manufacturing center. Environ Monit Assess 187:239CrossRefGoogle Scholar
  29. Quevauviller P, Rauret R, Rubio G et al (1997) Certified reference materials for the quality control of EDTA and acetic acid-extractable contents of trace elements in sewage sludge amended soils (CRMs 483 and 484). Fresenius J Anal Chem 357:611–618CrossRefGoogle Scholar
  30. Rahman MA, Rahman MM, Reichman SM, Lim RP, Naidu R (2014) Heavy metals in Australian grown and imported rice and vegetables on sale in Australia: health hazard. Ecotox Environ Safe 100:53–60CrossRefGoogle Scholar
  31. Ruiz F (2001) Trace metals in estuarine sediments from the southwestern Spanish, Coast. Mar Pollut Bull 42:482–490Google Scholar
  32. Shen ZJ, Sun QY, Liu M (2014) Soil carbon and nitrogen dynamics induced by tissue-litter decomposition of copper mine tailings from the Gramineae and Cryptogram communities, China. Anal Lett 47(5):885–899CrossRefGoogle Scholar
  33. Shen ZJ, Xu DC, Chen YS, Zhang Z (2017) Heavy metals translocation and accumulation from the rhizosphere soils to the edible parts of the medicinal plant Fengdan (Paeonia ostii) grown on a metal mining area, China. Ecotox Environ Safe 143:19–27CrossRefGoogle Scholar
  34. Skordas K, Kelepertsis A (2005) Soil contamination by toxic metals in the cultivated region of Agia, Thessaly, Greece, identification of sources of contamination. Environ Geol 48:615–624CrossRefGoogle Scholar
  35. Sun QY, An SQ, Yang LZ, Wang ZS (2004) Chemical properties of the upper tailings beneath biotic crusts. Ecol Eng 23:47–53CrossRefGoogle Scholar
  36. United States Environmental Protection Agency (US EPA) (1986) Superfund Public Health Evaluation Manual (EPA/540/1-86/060) [S]. Washington: Office of Emergency and Remedial Response, pp 1–52Google Scholar
  37. United States Environmental Protection Agency (US EPA) (1989) Risk Assessment Guidance for Superfund. Human Health Evaluation Manual Part A, vol.1 (EPA/540/1-89/002) [R]. Washington: Office of Emergency and Remedial Response, pp 1–100Google Scholar
  38. United States Environmental Protection Agency (US EPA) (2013) Electronic Code of Federal Regulations, Title 40-Protection of Environment, Part 423d Steam Electric Power Generating Point Source Category. Appendix A to Part 423e 126, Priority PollutantsGoogle Scholar
  39. Wu YG, Xu YN, Zhang JH et al (2010) Evaluation of ecological risk and primary empirical research on heavy metals in polluted soil over Xiaoqinling gold mining region, Shaanxi, China. Trans Nonferrous Metals Soc China 20(4):688–694.  https://doi.org/10.1016/S1003-6326(09)60199-0 CrossRefGoogle Scholar
  40. Wu YG, Xu YN, Zhang JH, Hu S, Liu K (2011) Heavy metals pollution and the identification of their sources in soil over Xiaoqinling gold-mining region, Shaanxi, China. Environ Earth Sci 64(6):1585–1592.  https://doi.org/10.1007/s12665-010-0833-7 CrossRefGoogle Scholar
  41. Xia JQ (1996) Detailed annotation on soil environmental quality standards [M]. China Environmental Science Press, Beijing, pp 7–15Google Scholar
  42. Xu DC, Zhou P, Zhan J, Gao Y, Dou C, Sun Q (2013) Assessment of trace metal bioavailability in garden soils and health risks via consumption of vegetables in the vicinity of Tongling mining area, China. Ecotox Environ Safe 90:103–111CrossRefGoogle Scholar
  43. Xu Y, Liang XF, Xu YM et al (2017) Remediation of heavy metal-polluted agricultural soils using clay minerals: a review. Pedosphere 27(2):193–204CrossRefGoogle Scholar
  44. Yang C, Tashpolat T, Hou YJ et al (2016) Assessment of heavy metals pollution and its health risk of atmospheric dust fall from east part of Junggar Basin in Xinjiang. Environ Sci 37(7):2453–2461 in ChineseGoogle Scholar
  45. Zhang NM (2001) Effects of air settlement on heavy metal accumulation in soil. Soil Environ Sci 10(2):91–93 in ChineseGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  1. 1.School of Life ScienceHefei Normal UniversityHefeiChina

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