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Environmental Earth Sciences

, 78:101 | Cite as

Ecological risk by heavy metal contents in sediments within the Wei River Basin, China

  • Tao YangEmail author
  • Jia Chen
  • Xiaoping Li
  • Ting Wu
  • Zhaojun Hu
  • Shuo Wang
Original Article
  • 20 Downloads

Abstract

The Wei River is the largest tributary of the Huang River, which is the second largest river in China. This study aimed to determine pollution and risk assessment of heavy metals, including chromium (Cr), lead (Pb), zinc (Zn), arsenic (As), mercury (Hg), and cadmium (Cd), in 12 selected stations of the Wei River Basin, Northwest China. Results indicated that the pollution and potential risk in Weijiabao are more severe than the other 11 cross sections. The concentrations and potential ecological risk of Pb and Hg and Cr, Pb, Zn, As, and Hg were observed in moderately contaminated and considerable risk levels given industrial wastewater discharge, correspondingly. For the single element, the relative contaminated status and potential risk levels for Cr, Pb, Zn, As, and Hg were Zn > Hg > Cr > Pb > As and Hg > Pb > As > Cr > Zn, respectively. The Cr in sediments may derive from agricultural activities given the utilization of chemical fertilizers, whereas Pb, Zn, and As may derive from industrial wastewater and sewage sludge. Metal melting wastewater in the upper reach and paper mill and textile process wastewater in the middle reach of the Wei River should be disposed of and should satisfy the corresponding criteria of the Integrated Wastewater Discharge Standard (GB8978-2002). Furthermore, a scientific application of chemical fertilizers in the Jing and Beiluo Rivers should be implemented in the reach.

Keywords

Wei River Basin Sediment Heavy metal Potential ecological risk 

Notes

Acknowledgements

This study was supported by the National Natural Science Foundation of China (41571512, 41471420), the Natural Science Foundation of Shaanxi Province (2015JM4124), and the Fundamental Research Funds for the Central Universities (GK201701010).

Author contributions

TY, JC, XL, and TW are the main contributors to this study. ZH and SW have contributed in the field investigation and experimentation.

Compliance with ethical standards

Conflict of interest

The authors declare no conflict of interest.

References

  1. Abrahim GMS, Parker RJ (2008) Assessment of heavy metal factors and degree of contamination in marine sediments from Tamaki Estuary, Auckland, New Zealand. Environ Monit Assess 136(1–3):227–238Google Scholar
  2. Akinci G, Guven DE, Ugurlu SK (2013) Assessing pollution in Izmir Bay from rivers in western Turkey: heavy metals. Environ Sci Process Impacts 15(12):2252–2262Google Scholar
  3. Bartoli G, Papa S, Sagnella E, Fioretto A (2012) Heavy metal content sediments along the Calore river: relationships with physical–chemical characteristics. J Environ Manag 95(2):9–14Google Scholar
  4. Bhuyan MS, Bakar MA (2017) Seasonal variation of heavy metals in water and sediment in the Halda River, Chittagong, Bangladesh. Environ Sci Pollut Res 24(35):27587–27600Google Scholar
  5. Bian B, Zhou Y, Fang BB (2016) Distribution of heavy metals and benthic macroinvertebrates: impacts from typical inflow river sediments in the Taihu Basin, China. Ecol Indic 69:348–359Google Scholar
  6. Cai Y, Zhang WG, Zhou MC, Jiang H, Xu DL, An SQ, Leng X (2015) Comprehensive assessment of heavy metal contamination in surface sediments from the inflow rivers of Taihu Basin. Clean Soil Air Water 43(12):1559–1692Google Scholar
  7. Cao QQ, Song Y, Zhang YR, Wang RQ, Liu J (2017) Risk analysis on heavy metal contamination in sediments of rivers flowing into Nansi Lake. Environ Sci Pollut Res 24(35):26910–26918Google Scholar
  8. Chabukdhara M, Nema AK (2012) Assessment of heavy metal contamination in Hindon River sediments: a chemometric and geochemical approach. Chemosphere 87(8):945–953Google Scholar
  9. Chen XY, Huang H, Sang HQ (2006) The application of the index of geoaccumulation to evaluate heavy metal pollution in sediments in the Huainan section of Huaihe River. J Anhui Sci Tec Unvi 20(2):35–38Google Scholar
  10. Cheng HX, Li M, Zhao CD, Yang K, Li K, Peng M, Yin ZF, Liu F, Liu YH, Bai RJ, Cui YJ, Huang ZF, Li LH, Liao QL, Luo JL, Jia SJ, Pang XG, Yang J, Yin GS (2015a) Concentrations of toxic metals and ecological risk assessment for sediments of major freshwater lakes in China. J Geochem Explor 157:15–26Google Scholar
  11. Cheng QL, Wang RL, Huang WH, Wang WL, Li XD (2015b) Assessment of heavy metal contamination in the sediments from the Yellow River Wetland National Nature Reserve (the Sanmenxia section), China. Environ Sci Pollut Res 22(11):8586–8593Google Scholar
  12. Fernandes HM (1997) Heavy metal distribution in sediments and ecological risk assessment: the role of diagenetic processes reducing metal toxicity in bottom sediments. Environ Pollut 97(3):317–325Google Scholar
  13. Fichet D, Boucher G, Radenac G, Miramand P (1999) Concentration and mobilisation of Cd, Cu, Pb and Zn by meiofauna populations living in harbour sediment: their role in the heavy metal flux from sediment to foodweb. Sci Total Environ 343–344:263–272Google Scholar
  14. Fu J, Hu X, Tao XC, Yu HX, Zhang XW (2013) Risk and toxicity assessments of heavy metals in sediments and fishes from the Yangtze River and Taihu Lake, China. Chemosphere 93(9):1887–1895Google Scholar
  15. Fu J, Zhao CP, Luo YP, Liu CS, Kyzas GZ, Luo Y, Zhao DY, An SQ, Zhu HL (2014) Heavy metals in surface sediments of the Jialu River, China: their relations to environmental factors. J Hazard Mater 270(3):102–109Google Scholar
  16. Guan QY, Cai A, Wang FF, Wang L, Wu T, Pan BT, Song N, Li FC, Lu M (2016) Heavy metals in the riverbed surface sediment of the Yellow River, China. Environ Sci Pollut Res 23(24):24768–24780Google Scholar
  17. Hakanson L (1980) An ecological risk index for aquatic pollution control: a sedimentological approach. Water Res 14(8):975–1001Google Scholar
  18. Han YM, Cao JJ, Wu F, Zhang BC, Zhan CL, Wei C, Zhao ZZ (2012) Geochemistry and environmental assessment of major and trace elements in the surface sediments of the Wei River, China. J Environ Monit 14(10):2762–2771Google Scholar
  19. Han C, Qin Y, Zheng B, Ma Y, Zhang L, CaoW (2014) Sediment quality assessment for heavy metal pollution in the Xiang-jiang River (China) with the equilibrium partitioning approach. Environ Earth Sci 72:5007–5018Google Scholar
  20. Han DM, Cheng JP, Hu XF, Jiang ZY, Mo L, Xu H, Ma YN (2017) Spatial distribution, risk assessment and source identification of heavy metals in sediments of the Yangtze River Estuary, China. Mar Pollut Bull 115(1–2):141–148Google Scholar
  21. Harikumar PS, Nasir UP, Rahman MPM (2009) Distribution of heavy metals in the core sediments of a tropical wetland system. Int J Environ Sci Technol 6(2):225–232Google Scholar
  22. Jung HS, Lim D, Xu ZK, Kang JH (2014) Quantitative compensation of grain-size effects in elemental concentration: a Korean coastal sediments case study. Estuar Coast Shelf Sci 151:69–77Google Scholar
  23. Ke X, Gui SF, Huang H, Zhang HJ, Wang CY, Guo W (2017) Ecological risk assessment and source identification for heavy metals in surface sediment from the Liaohe River protected area, China. Chemosphere 175:473–481Google Scholar
  24. Kristensen EA, Baattrup-Pedersen A, Thodsen H (2011) An evaluation of restoration practices in lowland streams: has the physical integrity been re-created? Ecol Eng 37:1654–1660Google Scholar
  25. Kumar RN, Solanki R, Nirmal Kumar JI (2013) Seasonal variation in heavy metal contamination in water and sediments of river Sabarmati and Kharicut canalat Ahmedabad, Gujarat. Environ Monit Assess 185(1):359–368Google Scholar
  26. Li XP, Feng LN (2012) Geostatistical analyses and fractionation of heavy metals in urban soil from industrial district in Weinan, China. Environ Earth Sci 67(7):2129–2140Google Scholar
  27. Li RY, Yang H, Zhou ZG, Lv JJ, Shao XH, Jin F (2007a) Fractionation of heavy metals in sediments from Dianchi Lake, China. Pedosphere 17(2):265–272Google Scholar
  28. Li Q, Wu Z, Chu B, Zhang N, Cai S, Fang J (2007b) Heavy metals in coastal wetland sediments of the Pearl River Estuary, China. Environ Pollut 149(2):158–164Google Scholar
  29. Li Q, Song JX, Wei AL, Zhang B (2013) Changes in major factors affecting the ecosystem health of the Weihe River in Shaanxi Province, China. Front Environ Sci Eng 7(6):875–885Google Scholar
  30. Li N, Tian Y, Zhang J, Zuo W, Zhan W, Zhang J (2017a) Heavy metal contamination status and source apportionment in sediments of Songhua River Harbin region, Northeast China. Environ Sci Pollut Res 24(4):3214–3225Google Scholar
  31. Li XP, Wu T, Bao HX, Liu XY, Xu CL, Zhao YN, Liu DY, Yu HT (2017b) Potential toxic trace element (PTE) contamination in Baoji urban soil (NW China): spatial distribution, mobility behavior, and health risk. Environ Sci Pollut Res 24(24):1–18Google Scholar
  32. Lin S, Hsieh I-J, Huang K-M, Wang C-H (2002) Influence of the Yangtze River and grain size on the spatial variations of heavy metals and organic carbon in the East China Sea continental shelf sediments. Chem Geol 182(2–4):377–394Google Scholar
  33. Liu JQ, Yin P, Chen B, Gao F, Song HY, Li MN (2016a) Distribution and contamination assessment of heavy metals in surface sediments of the Luanhe River Estuary, northwest of the Bohai Sea. Mar Pollut Bull 109(1):633–639Google Scholar
  34. Liu JL, Yang T, Chen QY, Liu F, Wang BB (2016b) Distribution and potential ecological risk of heavy metals in the typical eco-units of Haihe River Basin. Front Environ Sci Eng 10(1):103–113Google Scholar
  35. Liu JJ, Xu YZ, Cheng YX, Zhao YY, Pan YY, Fu GY, Dai YZ (2017) Occurrence and risk assessment of heavy metals in sediments of the Xiangjiang River, China. Environ Sci Pollut Res 24(3):2711–2723Google Scholar
  36. Lu XQ, Werner I, Young TM (2005) Geochemistry and bioavailability of metals in sediments from northern San Francisco Bay. Environ Int 31(4):593–602Google Scholar
  37. Müller G (1969) Index of geoaccumulation in sediments of the Rhine River. Geojournal 2(108):108–118Google Scholar
  38. Ning TT, Li Z, Liu WZ (2016) Separating the impacts of climate change and land surface alteration on runoff reduction in the Jing River catchment of China. Catena 147:80–86Google Scholar
  39. Niu Y, Niu Y, Pang Y, Yu H (2015) Assessment of Heavy Metal Pollution in Sediments of Inflow Rivers to Lake Taihu, China. Bull Environ Contam Toxicol 95(5):618–623Google Scholar
  40. Pandey M, Pandey AK, Mishra A, Tripathi BD (2015) Application of chemometric analysis and self organizing map-artificial neural network as source receptor modeling for metal speciation in river sediment. Environ Pollut 204:64–73Google Scholar
  41. Pempkowiak J, Sikora A, Biernacka E (1999) Speciationof heavy metalsin marine sediments vs their bioaccumulation by mussels. Chemosphere 39(2):313–321Google Scholar
  42. Qu XD, Ren Z, Zhang M, Liu XB, Peng WQ (2017) Sediment heavy metals and benthic diversities in Hun-Tai River, northeast of China. Environ Sci Pollut Res 24(11):10662–10673Google Scholar
  43. Shang Z, Ren J. Tao L, Wang X (2015) Assessment of heavy metals in surface sediments from Gansu section of Yellow River, China. Environ Monit Assess 187(3):79–89Google Scholar
  44. Song JX, Cheng DD, Li Q, He XJ, Long YQ, Zhang B (2015) An evaluation of river health for the Weihe River in Shaanxi Province, China. Adv Meteorol 2015(1):1–13Google Scholar
  45. Su QL, Zhou SL, Yi HM, Wang JX, Liu L, Zheng JJ (2016) A comparative study of different assessment methods of regional heavy metal pollution. J Environ Sci China 36(4):1309–1316 (in Chinese) Google Scholar
  46. Sun ZG, Mou XJ, Zhang DY, Sun WL, Hu XY, Tian LP (2017) Impacts of burial by sediment on decomposition and heavy metal concentrations of Suaeda salsa in intertidal zone of the Yellow River estuary, China. Mar Pollut Bull 116(1–2):103–112Google Scholar
  47. Tang WZ, Shan BQ, Zhang WQ, Zhang H, Wang LS, Ding YK (2014) Heavy metal pollution characteristics of surface sediments in different aquatic ecosystems in Eastern China: a comprehensive understanding. PLoS One 9(9):e108996–e108996Google Scholar
  48. Tang WZ, Zhang C, Zhao Y, Shan BQ, Song ZX (2017) Pollution, toxicity, and ecological risk of heavy metals in surface sediments of a large basin undergoing rapid economic development. Environ Toxicol Chem 36(5):1149–1155Google Scholar
  49. Tekin-Özan S (2008) Determination of heavy metal levels in water, sediment and tissues of tench (Tinca tinca L., 1758) from Beysehir Lake (Turkey). Environ Monit Assess 145(1–3):295–302Google Scholar
  50. US EPA (1998) Guidelines for ecological risk assessment. EPA/630/R-95/002F. Risk Assessment Forum, Environmental Protection Agency, Washington, DCGoogle Scholar
  51. Van Hook RI (1979) Potential health and environmental effects of trace elements and radio nuclides from increased coal utilization. Environ Health Perspect 33:227–247Google Scholar
  52. Varol M (2011) Assessment of heavy metal contamination in sediments of the Tigris River (Turkey) using pollution indices and multivariate statistical techniques. J Hazard Mater 195(1):355–364Google Scholar
  53. Wang C, Liu SL, Zhao QH, Deng L, Dong SK (2012) Spatial variation and contamination assessment of heavy metals in sediments in the Manwan Reservoir, Lancang River. Ecotoxicol Environ Saf 82(4):32–39Google Scholar
  54. Wang J, Liu R, Zhang P, Yu W, Shen Z, Feng C (2014a) Spatial variation, environmental assessment and source identification of heavy metals in sediments of the Yangtze River Estuary. Mar Pollut Bull 87(1–2):364–373Google Scholar
  55. Wang ZM, Chen LD, Zhang HP, Sun RH (2014b) Multivariate statistical analysis and risk assessment of heavy metals monitored in surface sediment of the Luan River and its tributaries, China. Hum Ecol Risk Assess Int J 20(6):1521–1537Google Scholar
  56. Wang J, Liu G, Lu L, Zhang J, Liu H (2015) Geochemical normalization and assessment of heavy metals (Cu, Pb, Zn, and Ni) in sediments from the Huaihe River, Anhui, China. Catena 129:30–38Google Scholar
  57. Wang Q, Chen QY, Yan D, Xin SG (2018) Distribution, ecological risk, and source analysis of heavy metals in sediments of Taizihe River, China. Environ Earth Sci 77(16):569–583Google Scholar
  58. Weis JS, Weis P (2004) Metal uptake, transport and release by wetland plants: implications for phytoremediation and restoration. Environ Int 30(5):685–700Google Scholar
  59. Wu W, Xu ZX, Yin XW, Zuo DP (2014) Assessment of ecosystem health based on fish assemblages in the Wei River basin, China. Environ Monit Assess 186(6):3701–3716Google Scholar
  60. Wu W, Xu ZX, Zhan CS, Yin XW, Yu SY (2015) A new framework to evaluate ecosystem health: a case study in the Wei River basin, China. Environ Monit Assess 187(7):460–475Google Scholar
  61. Wu W, Xu ZX, Kennard MJ, Yin XW, Zuo ZP (2016) Do human disturbance variables influence more on fish community structure and function than natural variables in the Wei River basin, China? Ecol Indic 61:438–446Google Scholar
  62. Wu PB, Yin AJ, Yang XH, Zhang H, Fan M, Gao C (2017) Distribution and source identification of heavy metals in the sediments of a river flowing an urbanization gradient, Eastern China. Environ Earth Sci 76(21):8963–8975Google Scholar
  63. Xiang Y, Miao QL, Feng JF (2006) Pollution of heavy metals in the bottom mud of Lake Taihu and its assessment of potential ecological risk. J Nanjing Inst Meteorol 29(5):700–705Google Scholar
  64. Xu YH, Sun QQ, Yi L, Yin XJ, Wang AJ, Li JH, Chen J (2014) The source of natural and anthropogenic heavy metals in the sediments of the Minjiang River Estuary (SE China):Implications for historical pollution. Sci Total Environ 493:729–736Google Scholar
  65. Yan CZ, Li QZ, Zhang X, Li GX (2010) Mobility and ecological risk assessment of heavy metals in surface sediments of Xiamen Bay and its adjacent areas, China. Environ Earth Sci 60(7):1469–1479Google Scholar
  66. Yang YQ, Chen FR, Zhang L, Liu JS, Wu SJ, Kang ML (2012) Comprehensive assessment of heavy metal contamination in sediment of the Pearl River Estuary and adjacent shelf. Mar Pollut Bull 64:1947–1955Google Scholar
  67. Yang T, Liu JL, Chen QY (2013) Assessment of plain river ecosystem function based on improved gray system model and analytic hierarchy process for the Fuyang River, Haihe River Basin, China. Ecol Model 268(5):37–47Google Scholar
  68. Yang Y, Liu Z, Chen F, Wu S, Zhang L, Kang M, Li J (2014) Assessment of trace element contamination in sediment cores from the Pearl River and estuary, South China: geochemical and multivariate analysis approaches. Environ Monit Assess 186(12):8089–8107Google Scholar
  69. Yang XF, Duan JM, Wang L, Li W, Guan JL, Beecham S, Mulcahy D (2015a) Heavy metal pollution and health risk assessment in the Wei River in China. Environ Monit Assess 187(3):111–122Google Scholar
  70. Yang XF, Duan JM, Wang L, Li W, Guan JL, Beecham S, Mulcahy D (2015b) Heavy metal pollution and health risk assessment in the Wei River in China. Environ Monit Assess 187(3):1–11Google Scholar
  71. Yang T, Li XP, Xu YF, Chen QY, Zhao XG, Zhou SJ (2017) Potential ecological risk and contamination of heavy metals in Feng River, China. Fresen Environ Bull 26(6):4039–4046Google Scholar
  72. Yang T, Wang S, Li XP, Wu T, Li L, Chen J (2018) River habitat assessment for ecological restoration of Wei River Basin, China. Environ Sci Pollut Res 25(17):1–14Google Scholar
  73. Zhang FY, Yan BX, Zhu LL (2010a) Speciation of heavy metals in sediment of the Songhua River, northeast of China. J Agro Environ Sci 29(1):163–167Google Scholar
  74. Zhang XJ, Li CY, Zhang S, Shi XH, Li WP (2010b) Distribution features and ecological risk assessment of heavy metals in superficial sediments of Hulun Lake. J Agro Environ Sci 29(1):157–162Google Scholar
  75. Zhang H, Jiang YH, Ding MJ, Xie ZL (2017) Level, source identification, and risk analysis of heavy metal in surface sediments from river-lake ecosystems in the Poyang Lake, China. Environ Sci Pollut Res 24(27):21902–21916Google Scholar
  76. Zhang PY, Qin CZ, Hong X, Kang GH, Qin MZ, Yang D, Pang B, Li YY, He JJ, Dick RP (2018) Risk assessment and source analysis of soil heavy metal pollution from lower reaches of Yellow River irrigation in China. Sci Total Environ 633:1136–1147Google Scholar
  77. Zhao YN, Li XP, Yang T, Sun XM, Liu DY, Wu T, Ai YW, Cai Y, Li L, Yu HT (2018) The spatial distribution characteristics, sources and health risks of trace elements in dust in typical energy development zones. J Environ Sci China 38(1):350–362 (in Chinese) Google Scholar
  78. Zheng GZ (2008) Investigation and assessment on heavy metal pollution of farming soil in the Jinghe River Basin. Arid Zone Res 5:620–630 (in Chinese) Google Scholar
  79. Zhu HB, He LJ (2009) A study on appropriate conditions in consistency test of normal distribution by single sample K-S check in SPSS. J Cap Instit Phys Educ 21(4):466–470 (in Chinese) Google Scholar
  80. Zuo DP, Xu ZX, Yang H, Liu XC (2012) Spatiotemporal variations and abrupt changes of potential evapotranspiration and its sensitivity to key meteorological variables in the Wei River basin, China. Hydrol Process 26(8):1149–1160Google Scholar
  81. Zuo DP, Xu ZX, Wu W, Zhao J, Zhao FF (2014) Identification of stream flow response to climate change and human activities in the Wei River Basin, China. Water Resour Manag 28(3):833–851Google Scholar

Copyright information

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

Authors and Affiliations

  • Tao Yang
    • 1
    • 2
    Email author
  • Jia Chen
    • 1
  • Xiaoping Li
    • 1
    • 2
  • Ting Wu
    • 1
  • Zhaojun Hu
    • 1
  • Shuo Wang
    • 1
  1. 1.School of Geography and TourismShaanxi Normal UniversityXi’anPeople’s Republic of China
  2. 2.International Joint Research Centre of Shaanxi Province for Pollutant Exposure and Eco-environmental HealthXi’anPeople’s Republic of China

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