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Assess of Environmental and Ecological Risk of Heavy Metals Originated of Reverse Osmosis Desalination Plant Effluents to Coastal Areas in the Persian Gulf | ||
Journal of Health Sciences & Surveillance System | ||
دوره 10، شماره 2، تیر 2022، صفحه 203-209 اصل مقاله (567.21 K) | ||
نوع مقاله: Original Article | ||
شناسه دیجیتال (DOI): 10.30476/jhsss.2021.91717.1217 | ||
نویسندگان | ||
Leila Rezaei1؛ Vali Alipour2؛ Amir Hesam Hassani3؛ Mohsen Dehghani* 4 | ||
1Department of Environmental Sciences, Qeshm Branch, Islamic Azad University, Qeshm, Iran | ||
2Department of Environmental Health Engineering, School of Health, Hormozgan University of Medical Sciences, Iran | ||
3Department of Environmental Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran | ||
4Department of Natural Resources and Environmental Sciences, Islamic Azad University, Bandar Abbas Branch, Bandar Abbas, Iran | ||
چکیده | ||
Background: the Persian Gulf ecosystem is facing degradation, so further degradation must be prevented. The present study was conducted to assess the environmental pollution risk potential of the coastal ecosystem due to heavy metal content in desalination plant’s effluent. Methods: In this cross-sectional study, the researchers selected five stations in the west of Bandar Abbas beach, located at the outlet of desalination effluent canals to the shore, and two stations in the east shore (without effluent discharge) as case and control stations, respectively. The researchers collected 51 Sediment samples and measured heavy metal concentration, using an AA spectrophotometer, and assessed the potential ecological risk. They used SPSS software and the T-test to statistically analyze data. Results: The concentration means for sediments in case and control stations samples were: 40.63±16.79, 96.64±30.60, 159.74±50.65, 109.22±17.09, 205.35±86.96 mg.kg-1 and 40.15±17.21, 79.16±28.26, 152.43±90.07, 101.82±43.55, and 193.82±112.90 mg.kg-1, respectively for (Pb, Cu, Ni, Cd, and Zn). The ecological risk and Pollution Load Index were (31.72, 35.95, 3.30, 36.96, and 45.61) and (0.62, 0.63, 0.71, 0.68, and 0.9), respectively for metals mentioned order. Individual potential risk for all stations showed a low-risk degree. Conclusion: Although the heavy metals accumulated in coastal sediments due to the discharge of desalination plant effluents, severe ecological and environmental damage has not occurred. Therefore, there is still time to prevent an environmental catastrophe on the shores receiving desalination effluents. Therefore, it is recommended to all responsible persons to take the necessary measures to monitor and control the plan and reduce the discharge of effluents to the shores. | ||
کلیدواژهها | ||
Heavy metal؛ Ecosystem؛ Environmental pollution؛ Persian Gulf؛ Pollution | ||
مراجع | ||
1. Boelee E, Janse J, Le Gal A, Kok M, Alkemade R, Ligtvoet W. Overcoming water challenges through nature-based solutions. Water Policy. 2017;19(5):820-36. 2. Ghernaout D, Gabes Z. Desalination in the Context of Water Scarcity Crisis: Dares & Perspectives. Open Access Library Journal. 2020;7(11):1. 3. Manchanda H, Kumar M. Study of water desalination techniques and a review on active solar distillation methods. Environmental Progress & Sustainable Energy. 2018;37(1):444-64. 4. Rezaei L, Dehghani M, Hassani AH, Alipour V. Seawater reverse osmosis membrane fouling causes in a full scale desalination plant; through the analysis of environmental issues: raw water quality. Environmental Health Engineering and Management Journal. 2020;7(2):119–26. 5. Mehrgan M, Mahdiraji H, Binaee S, Alipour V, Agha SRH. Modeling of environmental aspects related to reverse osmosis desalination supply chain. Environmental Health Engineering and Management Journal. 2020;7(1): 31–40. 6. Darre NC, Toor GS. Desalination of water: a review. Current Pollution Reports. 2018;4(2):104-11. 7. Thimmaraju M, Sreepada D, Babu GS, Dasari BK, Velpula SK, Vallepu N. Desalination of water. Desalination and Water Treatment. 2018:333-47. 8. Missimer T, Maliva R. Environmental issues in seawater reverse osmosis desalination: intakes and outfalls Desalination 2018;434:198-215. 9. Caldera U, Breyer C. Learning curve for seawater reverse osmosis desalination plants: capital cost trend of the past, present, and future. Water Resour Res. 2017;53(12):10523-38. 10. Petersen KL, Frank H, Paytan A, Bar-Zeev E. Impacts of seawater desalination on coastal environments. Sustainable desalination handbook: Elsevier; 2018. p. 437-63. 11. Saadati M, Soleimani M, Sadeghsaba M, Hemami MR. Bioaccumulation of heavy metals (Hg, Cd and Ni) by sentinel crab (Macrophthalmus depressus) from sediments of Mousa Bay, Persian Gulf. Ecotoxicology and environmental safety. 2020;191:109986. 12. Kabir MH, Islam MS, Hoq ME, Tusher TR, Islam MS. Appraisal of heavy metal contamination in sediments of the Shitalakhya River in Bangladesh using pollution indices, geo-spatial, and multivariate statistical analysis. Arabian Journal of Geosciences. 2020;13(21):1-13. 13. Joksimović D, Perošević A, Castelli A, Pestorić B, Šuković D, Đurović D. Assessment of heavy metal pollution in surface sediments of the Montenegrin coast: a 10-year review. Journal of Soils and Sediments. 2020;20(6):2598-607. 14. Pourang N, Bahrami A, Nasrolahzadeh Saravi H. Shells of Bufonaria echinata as biomonitoring materials of heavy metals (Cd, Ni and Pb) pollution in the Persian Gulf: with emphasis on the annual growth sections. Iranian Journal of Fisheries Sciences. 2019;18(2):256-71. 15. Sharifinia M, Taherizadeh M, Namin JI, Kamrani E. Ecological risk assessment of trace metals in the surface sediments of the Persian Gulf and Gulf of Oman: evidence from subtropical estuaries of the Iranian coastal waters. Chemosphere. 2018;191:485-93. 16. Rezaei M, Kafaei R, Mahmoodi M, Sanati AM, Vakilabadi DR, Arfaeinia H, et al. Heavy metals concentration in mangrove tissues and associated sediments and seawater from the north coast of Persian Gulf, Iran: Ecological and health risk assessment. Environmental Nanotechnology, Monitoring & Management. 2021;15:100456. 17. Tian K, Wu Q, Liu P, Hu W, Huang B, Shi B, et al. Ecological risk assessment of heavy metals in sediments and water from the coastal areas of the Bohai Sea and the Yellow Sea. Environment international. 2020;136:105512. 18. Ahmadov M, Humbatov F, Mammadzada S, Balayev V, Ibadov N, Ibrahimov Q. Assessment of heavy metal pollution in coastal sediments of the western Caspian Sea. Environmental Monitoring and Assessment. 2020;192(8):1-18. 19. Rodríguez-Espinosa P, Shruti V, Jonathan M, Martinez-Tavera E. Metal concentrations and their potential ecological risks in fluvial sediments of Atoyac River basin, Central Mexico: Volcanic and anthropogenic influences. Ecotoxicology and Environmental Safety. 2018;148:1020-33. 20. Ogundele LT, Ayeku PO, Adebayo AS, Olufemi AP, Adejoro IA. Pollution Indices and Potential Ecological Risks of Heavy Metals in the Soil: A Case Study of Municipal Wastes Site in Ondo State, Southwestern, Nigeria. Polytechnica. 2020:1-9. 21. Tokatli C. Sediment quality of Ergene River Basin: bio–ecological risk assessment of toxic metals. Environmental monitoring and assessment. 2019;191(11):1-12. 22. Xu Y, Wu Y, Han J, Li P. The current status of heavy metal in lake sediments from China: Pollution and ecological risk assessment. Ecology and evolution. 2017;7(14):5454-66. 23. Liu J-J, Ni Z-X, Diao Z-H, Hu Y-X, Xu X-R. Contamination level, chemical fraction and ecological risk of heavy metals in sediments from Daya Bay, South China Sea. Marine pollution bulletin. 2018;128:132-9. 24. Asheghi R, Hosseini SA, Saneie M, Shahri AA. Updating the neural network sediment load models using different sensitivity analysis methods: a regional application. Journal of Hydroinformatics. 2020;22(3):562-77. 25. Bastami KD, Afkhami M, Mohammadizadeh M, Ehsanpour M, Chambari S, Aghaei S, et al. Bioaccumulation and ecological risk assessment of heavy metals in the sediments and mullet Liza klunzingeri in the northern part of the Persian Gulf. Marine pollution bulletin. 2015;94(1-2):329-34. 26. Janadeleh H, Jahangiri S, Kameli MA. Assessment of heavy metal pollution and ecological risk in marine sediments (A case study: Persian Gulf). Human and Ecological Risk Assessment: An International Journal. 2018;24(8):2265-74. 27. Arfaeinia H, Dobaradaran S, Moradi M, Pasalari H, Mehrizi EA, Taghizadeh F, et al. The effect of land use configurations on concentration, spatial distribution, and ecological risk of heavy metals in coastal sediments of northern part along the Persian Gulf. Science of the Total Environment. 2019;653:783-91. 28. Mirzaei M, Hatamimanesh M, Haghshenas A, Moghaddam SM, Ozunu A, Azadi H. Spatial-seasonal variations and ecological risk of heavy metals in Persian gulf coastal region: case study of Iran. Journal of Environmental Health Science and Engineering. 2020:1-15. 29. Roberts D, Johnston E, Knott N. Impacts of desalination plant discharges on the marine environment: a critical review of published studies. Water Res 2010;44(18):5117-28. 30. Sola I, Yolanda F-T, Aitor F, Carlos V, Yoana dP-R, M. G-CJe, et al. Sustainable desalination: Long-term monitoring of brine discharge in the marine environment. Marine Pollution Bulletin. 2020;161 31. Obiri-Nyarko F, Duah AA, Karikari AY, Agyekum WA, Manu E, Tagoe R. Assessment of heavy metal contamination in soils at the Kpone landfill site, Ghana: Implication for ecological and health risk assessment. Chemosphere. 2021:131007. 32. Barbieri M. The importance of enrichment factor (EF) and geoaccumulation index (Igeo) to evaluate the soil contamination. J Geol Geophys. 2016;5(1):1-4. 33. Müller G. Die Schwermetallbelastung der sedimente des Neckars und seiner Nebenflusse: eine Bestandsaufnahme. . Chem Ztg. 1981;105:157-64. 34. Rabee AM, Al-Fatlawy YF, Nameer M. Using Pollution Load Index (PLI) and geoaccumulation index (I-Geo) for the assessment of heavy metals pollution in Tigris river sediment in Baghdad Region. Al-Nahrain Journal of Science. 2011;14(4):108-14. 35. Waheshi YAA, El-Gammal MI, Ibrahim MS, Okbah M. Distribution and assessment of heavy metal levels using geoaccumulation index and pollution load index in Lake Edku sediments, Egypt. Egypt IJEMA. 2017;5:1-8. 36. Singh A, Sharma RK, Agrawal M, Marshall FM. Health risk assessment of heavy metals via dietary intake of foodstuffs from the wastewater irrigated site of a dry tropical area of India. Food and chemical toxicology. 2010;48(2):611-9. 37. Shirani M, Afzali KN, Jahan S, Strezov V, Soleimani-Sardo M. Pollution and contamination assessment of heavy metals in the sediments of Jazmurian playa in southeast Iran. Scientific reports. 2020;10(1):1-11. 38. Ammour F, Chekroud R, Houli S, Kettab A. Performance Evaluation of SWRO Desalination Plant at Skikda (Algeria). Exergy for A Better Environment and Improved Sustainability 2: Springer; 2018. p. 1131-8. 39. Aziz M, Kasongo G. Scaling prevention of thin film composite polyamide Reverse Osmosis membranes by Zn ions. Desalination. 2019;464:76-83. 40. Ghasemzade F, Moussavi Harami R, Pourkerman M, Amjadi S, Alizade Ketek Lahijani H. The Study of Pollution and Environmental Impact of Heavy Metals, and Chemical and Physical Variables Associated with the Distribution of These Elements in Continental Shelf Sedimentsof the Gulf of Oman, Chabahar Area. Journal of Oceanography. 2012;3(10):27-35. | ||
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