Pollution and Potential Ecological Risk Assessment of Heavy Metals in Water Bodies in the Vicinity of Industrial Zones

Date Received: Jul 02, 2023

Date Accepted: Aug 28, 2024

Date Published: Sep 30, 2024

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NATURAL RESOURCES AND ENVIRONMENT

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Tu, N., Huy, T., Ha, N., Hung, L., & Hang, H. (2024). Pollution and Potential Ecological Risk Assessment of Heavy Metals in Water Bodies in the Vicinity of Industrial Zones. Vietnam Journal of Agricultural Sciences, 7(3), 2228–2238. https://doi.org/10.31817/vjas.2024.7.3.05

Pollution and Potential Ecological Risk Assessment of Heavy Metals in Water Bodies in the Vicinity of Industrial Zones

Nguyen Ngoc Tu (*) 1, 2 , Trinh Quang Huy 1 , Nguyen Thi Thu Ha 1 , Le Tien Hung 1   , Ho Thi Thuy Hang 1

  • Corresponding author: nguyenngoctu@vnua.edu.vn
  • 1 Faculty of Natural Resources and Environment, Vietnam National University of Agriculture, Hanoi 12400, Vietnam
  • 2 Environmental Analysis Laboratory, Center of Research Excellence and Innovation, Vietnam National University of Agriculture, Hanoi 12400, Vietnam
  • Keywords

    Ecological risk assessment, heavy metal, accumulation, sediment, industrial wastewater

    Abstract


    This research was undertaken to determine the concentrations of heavy metal ions in the surface water and sediment in water bodies that receive wastewater from the Dinh Tram and Pho Noi A industrial zones. The pollution status of the heavy metal ions and their potential ecological risks were evaluated by using the potential ecological risk index (RI) and risk assessment code (RAC). The results showed that some metal ions, namely Fe3+, Ni2+, and Pb2+, exceeded the allowed standards of QCVN 08:2023/BTNMT. The sediments were polluted by Zn2+, As2+, Cr6+, and Fe3+ at concentrations 2.4, 3.7, 1.9, and 2.0 times higher, respectively, than the QCVN 43:2017/BTNMT. The potential ecological risk indices for the heavy metal ions were in order as: (As2+) = 7.94 > (Cd2+) = 3.68 > (Cr6+) = 3.39 > (Pb2+) = 2.73 > (Cu2+) = 2.74 > (Zn2+) = 2.4 (T6 channel) and (As2+) = 11.1 > (Cd2+) = 7.74 > (Cu2+) = 2.64 > (Cr6+) = 2.31 > (Pb2+) = 1.9 > (Zn2+) = 0.87 (Bun River). The risk assessment code (RAC) ranged from 0.17 to 39.42 (T6 channel) and from 0.03 to 38.96 (Bun River). The RAC-based risk assessment results showed that both the T6 channel and Bun River presented a medium risk for Cd2+, a low risk for Mn2+, Zn2+, Cu2+, and Ni2+, and no risk for the remaining metals, Cr6+, Pb2+, As2+, and Fe3+. These results were caused by the differences in environmental quality assessments between using separate parameters versus biological risk assessments.

    References

    Allen H. E. & Hansen D. J. (1996). The importance of trace metal speciation to water quality criteria. Water Environment Research. 68(1): 42-54. DOI: 10.2175/106143096X127307.

    Bharti R. & Sharma R. (2022). Effect of heavy metals: An overview. Materials Today: Proceedings. 51: 880-885.

    Billon G., Ouddane B., Recourt P. & Boughriet A. (2002). Depth variability and some geochemical characteristics of Fe, Mn, Ca, Mg, Sr, S, P, Cd and Zn in anoxic sediments from Authie Bay (northern France). Estuarine, Coastal and Shelf Science. 55(2): 167-181. DOI: 10.1006/ecss.2001.0894.

    Duong Thi Tu Anh & Cao Van Hoang (2015). Study on the distribution of some heavy metals in sediment of Cau river. Journal of chemical, physical and biological analysis. 20(4): 36-43 (in Vietnamese).

    Guala S. D., Vega F. A. & Covelo E. F. (2010). The dynamics of heavy metals in plant–soil interactions. Ecological Modelling. 221(8): 1148-1152. DOI: 10.1016/j.ecolmodel.2010.01.003.

    Hakanson L. (1980). An ecological risk index for aquatic pollution control. A sedimentological approach. Water research. 14(8): 975-1001. DOI: 10.1016/0043-1354(80)90143-8.

    Le Thi Trinh, Kieu Thi Thu Trang, Nguyen Thanh Trung, Nguyen Khanh Linh & Trinh Thi Tham (2018). Heavy Metal Accumulation and Potential Ecological Risk Assessment of Surface Sediments from Day River Downstream VNU Journal of Science: Earth and Environmental Sciences. 34(4): 140-147. DOI: 10.25073/ 2588-1094/vnuees.4351 (in Vietnamese).

    Ministry of Natural Resources and Environment (2021). National Environmental Status Report, period 2016 - 2020. Dantri Publisher. Retrieved from: http://moit.gov.vn/upload/2005517/fck/files/20211108_Bao_cao_HTMT_2016-2020_F_a4980.pdf_on Aug 26, 2024) (in Vietnamese).

    Mohammed M. & Markert B. (2006). Toxicity of heavy metals on Scenedesmus quadricauda (Turp.) de Brébisson in Batch Cultures. Environmental Science and Pollution Research. 13: 98-104. DOI: 10.1065/ espr2005.07.274.

    Naimo T. J. (1995). A review of the effects of heavy metals on freshwater mussels. Ecotoxicology. 4: 341-362. DOI: 10.1007/BF00118870.

    Ngo H., Gerstmann S. & Frank H. (2009). Toxicity of cadmium to the green alga Parachlorella kessleri: Producing Cd-loaded algae for feeding experiments. Toxicological & Environ Chemistry. 91(2): 279-288.

    Ngo Thi Thuy Huong, Le Thu Ha, Bui Trong Tan & Nguyen Tran Hung (2016). Evaluation of the relationship between physico-chemical factors of water environment and bottom mud with accumulation and fluctuation of heavy metal content in bottom mud of Nhue-Day river basin. VNU Journal of Science: Natural Sciences and Technology. 32(2) (in Vietnamese).

    Nguyen Phuc Cam Tu (2023). Effect of acetic acid on heavy metal content and nutritional composition of blood cockle (Anadara granosa). Vietnam Journal of Science, Technology and Engineering. 65(2): 48-52 (in Vietnamese).

    Nguyen Thi Bich Ngoc, Nguyen Thi Mai Huong, Nguyen Bich Thuy, Vu Duy An, Duong Thi Thuy, Ho Tu Cuong & Tran Thi Bich Nga (2015). Initial investigation of heavy metal concentration in water of Red River. Vietnam Journal of Science and Technology. 53(1): 64-64 (in Vietnamese).

    Nguyen Thi Hieu (2013). Study on the accumulation of Cu, Pb, Zn in sediment of Nhue river. , Master thesis, Environmental Science, Vietnam National University.

    Perin G., Craboledda L., Lucchese M., Cirillo R., Dotta L., Zanette M. & Orio A. (1985). Heavy metal speciation in the sediments of northern Adriatic Sea. A new approach for environmental toxicity determination. Heavy metals in the environment. 2(1): 454-456.

    Pham Kim Dang, Bui Thi Bich & Vu Duc Loi (2015). Accumulation of some metals in carp (Cyprinus carpio) reared in aquaculture farm, Vietnam National University of Agriculture. Journal of Science and Development. 13(3): 394-405 (in Vietnamese).

    Rizzo L., Di Gennaro A., Gallo M. & Belgiorno V. (2008). Coagulation/chlorination of surface water: A comparison between chitosan and metal salts. Separation and Purification Technology. 62(1): 79-85.

    Singh K. P., Mohan D., Singh V. K. & Malik A. (2005). Studies on distribution and fractionation of heavy metals in Gomti river sediments - a tributary of the Ganges, India. Journal of hydrology. 312(1-4): 14-27. DOI: 10.1016/j.jhydrol.2005.01.021.

    Tessier A., Campbell P. G. & Bisson M. (1979). Sequential extraction procedure for the speciation of particulate trace metals. Analytical chemistry. 51(7): 844-851.