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A Simulation to Assess the Probability of the Spread of Radioactive Materials from the Zaporizhzhia Nuclear Power Plant using the HYSPLIT Model | ||
| Pollution | ||
| دوره 10، شماره 1، فروردین 2024، صفحه 595-605 اصل مقاله (1.69 M) | ||
| نوع مقاله: Original Research Paper | ||
| شناسه دیجیتال (DOI): 10.22059/poll.2024.367237.2115 | ||
| نویسندگان | ||
| Behshad Valizadeh* 1؛ Yassin Heydarizade2؛ Javad Tayebi2؛ Mohammad Reza Rezaie2 | ||
| 1Department of Radiation Application, Shahid Beheshti University, Tehran, Iran | ||
| 2Department of Nuclear Engineering, Faculty of Sciences and Modern Technologies, Graduate University of Advanced Technology, Kerman, Iran | ||
| چکیده | ||
| Today, world pollution is increasing, and many pollutants such as radioactive elements enter to environment through human activity contaminants play an essential role in human life and health. Therefore, the examination of models for dispersion caused by radioactive substances is an important issue. This article is a simulation study of the hypothetical scenario of the Zaporizhzhia Nuclear Power Plant (ZNPP) in Ukraine, which is one of the NPPs in Europe. This scenario includes the occurrence of an accident in the power plant that entry of pollutants to environment and creates an environmental disaster. The simulation of this scenario was done using the Hyspli4 )Hybrid Single-Particle Lagrangian Integrated Trajectory) model and NOAA website data of ZNPP (include the wind information, temperature, humidity, and atmospheric pressure in different spatial and temporal scales) to predict and deal with pollutants. The simulation was conducted in the first week of April 2023 for 131 I and 137Cs elements, which are important elements that come out of the power plant and cause many problems. The results show the highest annual dose and concentration are 4.6 mSv/year and 2.7E+06 Bq.s/m3 respectively. It also shows that in the event of pollution, the entry of contaminated materials into the Dnieper River and the western edge of the blackened sea will bring a great disaster. Also, the eastern and northeastern regions of Ukraine, especially Kharkiv and the western borders of Russia, lead to pollution that causes radiation hazard, so the news should be shared with everyone before an actual incident occurs. | ||
| کلیدواژهها | ||
| Ukraine؛ Pollution؛ Accident؛ Reactor؛ Dosimetry | ||
| مراجع | ||
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Abdullah, A. G., Shafii, M. A., Pramuditya, S., Setiadipura, T., & Anzhar, K. (2023). Multi-criteria decision making for nuclear power plant selection using fuzzy AHP: Evidence from Indonesia. Energy and AI, 14, 100263. Ahn, J., Bae, J., Min, B. J., & Lee, S. J. (2022). Operation validation system to prevent human errors in nuclear power plants. Nuclear Engineering and Design, 397, 111949. Bagher, A. M., Vahid, M., & Mohsen, M. (2014). Introduction to radioactive materials. Int. J. Renew. Sustain. Energy, 3(3), 59-67. Bandyopadhyay, A., Rej, S., Villanthenkodath, M. A., & Mahalik, M. K. (2022). The role of nuclear energy consumption in abatement of ecological footprint: Novel insights from quantile-on-quantile regression. Journal of Cleaner Production, 358, 132052. Basem, A., Moawed, M., Abbood, M. H., & El-Maghlany, W. M. (2022). The energy and exergy analysis of a combined parabolic solar dish–steam power plant. Renewable Energy Focus, 41, 55-68. Bezhenar, R., & Kovalets, I. (2022, November). Modeling of radioactive contamination of the Black Sea and its impact on humans due to hypothetical heavy accident at the Zaporizhzhia NPP. In International scientific-practical conference (pp. 3-14). Cham: Springer Nature Switzerland. Brooks, A. L., Conca, J., Glines, W. M., & Waltar, A. E. (2023). How the science of radiation biology can help reduce the crippling fear of low-level radiation. Health Physics, 124(5), 407-424. Burke, A. (2022). Attacks on Ukrainian nuclear-power plants challenge treaties. Nature, 611(7935), 232-235. Choi, Y., Kanaya, Y., Park, S. M., Matsuki, A., Sadanaga, Y., Kim, S. W., & Jung, D. H. (2020). Regional variability in black carbon and carbon monoxide ratio from long-term observations over East Asia: assessment of representativeness for black carbon (BC) and carbon monoxide (CO) emission inventories. Atmospheric Chemistry and Physics, 20(1), 83-98. Grechishnikov-Oskoma, Y., Polukarov, Y., Zemlyanska, O., & Kachynska, N. (2022). Risk of emergency situations at nuclear power plants in Ukraine in the conditions of full-scale russian aggression. 3rd International Scientific and Practical Internet Conference of Students and Young Scientists, Beketova, Kharkiv, 65-67 Imamura, N., Katata, G., Kajino, M., Kobayashi, M., Itoh, Y., & Akama, A. (2020). Fogwater deposition of radiocesium in the forested mountains of East Japan during the Fukushima Daiichi Nuclear Power Plant accident: A key process in regional radioactive contamination. Atmospheric Environment, 224, 117339. Iqbal, J., Howari, F. M., Mohamed, A. M. O., & Paleologos, E. K. (2021). Assessment of radiation pollution from nuclear power plants. In Pollution Assessment for Sustainable Practices in Applied Sciences and Engineering (pp. 1027-1053). Butterworth-Heinemann. Jasmer, K. J., Gilman, K. E., Muñoz Forti, K., Weisman, G. A., & Limesand, K. H. (2020). Radiation-induced salivary gland dysfunction: mechanisms, therapeutics and future directions. Journal of clinical medicine, 9(12), 4095. Kaviani, F., Memarian, M. H., & Eslami-Kalantari, M. (2021). Radioactive impact on Iran and the world from a postulated accident at Bushehr Nuclear Power Plant. Progress in Nuclear Energy, 142, 103991. Kiomarsi, F., Shojaei, A. A., & Soltani, S. (2020). Choosing an optimal connecting place of a nuclear power plant to a power system using Monte Carlo and LHS methods. Nuclear Engineering and Technology, 52(7), 1587-1596. Kubo, K., Jang, S., Takata, T., & Yamaguchi, A. (2023). Dynamic probabilistic risk assessment of seismic-induced flooding in pressurized water reactor by seismic, flooding, and thermal-hydraulics simulations. Journal of Nuclear Science and Technology, 60(4), 359-373. Lichiheb, N., Hicks, B., Ngan, F., & Myles, L. (2022, December). Improving the atmospheric dispersion forecasts over Washington, DC using DCNet observations: A study with HYSPLIT model. In AGU Fall Meeting Abstracts (Vol. 2022, pp. A34D-07). Lorenz, W., & Nowak, Z. Russia Attempts Blackmail with Occupation of the Zaporizhzhia Nuclear Power Plant. Lumniczky, K., Impens, N., Armengol, G., Candéias, S., Georgakilas, A. G., Hornhardt, S., & Schaue, D. (2021). Low dose ionizing radiation effects on the immune system. Environment international, 149, 106212. Marzo, G. A. (2014). Atmospheric transport and deposition of radionuclides released after the Fukushima Dai-chi accident and resulting effective dose. Atmospheric Environment, 94, 709-722. Mathew, M. D. (2022). Nuclear energy: A pathway towards mitigation of global warming. Progress in Nuclear Energy, 143, 104080. Molhem, A. (2023). Possible Accidents Scenarios in Zaporizhzhia Nuclear Power Plant. Open Access Library Journal, 10(2), 1-19. Murshed, M., Khan, A. M., Khan, U., Khan, M. S., & Parvin, R. A. (2023). Can utilising renewable and nuclear energy harness the environmental sustainability agenda of the G7 countries? The importance of undergoing clean energy transition. International Journal of Ambient Energy, 44(1), 958-972. Nematchoua, M. K., & Orosa, J. A. (2022). Life cycle assessment of radioactive materials from a residential neighbourhood. Sustainable Materials and Technologies, 33, 00468. Obaidurrahman, K., Arul, A. J., Ramakrishnan, M., & Singh, O. P. (2021). Nuclear reactor safety. In Physics of Nuclear Reactors (pp. 449-510). Academic Press. Okano, I., Rosenberg, A., Dworkin, M., Murthy, V., Jayaraman, S., & Takabe, K. (2022). Direct and indirect health effects of the nuclear power plant disasters: a review for health care professionals. IJS Global Health, 5(5), 71. Pereira, P., Bašić, F., Bogunovic, I., & Barcelo, D. (2022). Russian-Ukrainian war impacts the total environment. Science of The Total Environment, 837, 155865. Saber, A. N., Somjunyakul, P., Ok, J., & Watanabe, H. (2019). Rainfall-runoff simulation of radioactive cesium transport by using a small-scale portable rainfall simulator. Water, Air, & Soil Pollution, 230, 1-15. Shchipalkina, A., & Smirnova, E. (2023). Disposal methods for radioactive waste from nuclear power plants and environmental radiation monitoring methods. In E3S Web of Conferences (Vol. 431, p. 04002). EDP Sciences. Singh, G., Bhadange, S., Bhawna, F., Shewale, P., Dahiya, R., Aggarwal, A., & Arya, S. K. (2023). Phytoremediation of radioactive elements, possibilities and challenges: special focus on agricultural aspects. International Journal of Phytoremediation, 25(1), 1-8. Siraz, M. M., Roy, D., Dewan, M. J., Alam, M. S., AM, J., Rashid, M. B., & Yeasmin, S. (2023). Vertical distributions of radionuclides along the tourist-attractive Marayon Tong Hill in the Bandarban district of Bangladesh. Environmental monitoring and assessment, 195(3), 382. Solovian, V. (2023). UKRAINIAN NUCLEAR PLANTS IN THE FOCUS OF RUSSIAN INFORMATION WARFARE. Ukraine Analytica, (01 (30)), 37-45. Tsuboi, M., Sawano, T., Nonaka, S., Hori, A., Ozaki, A., Nishikawa, Y., & Tsubokura, M. (2022). Disaster-related deaths after the Fukushima Daiichi nuclear power plant accident-definition of the term and lessons learned. Environmental Advances, 8, 100248. Xu, D., Peng, M., Zhang, Z., Dong, G., Zhang, Y., & Yu, H. (2012). Study of damage to red blood cells exposed to different doses of γ-ray irradiation. Blood Transfusion, 10(3), 321. Yamashita, S., & Suzuki, S. (2013). Risk of thyroid cancer after the Fukushima nuclear power plant accident. Respiratory investigation, 51(3), 128-133. Zadfathollah, R., Balgehshiri, S. K. M., Paydar, A. Z., Moghaddam, M. J., & Zohuri, B. (2023). Implosion Plasma Driven Fusion Pellet of Inertial Confinement (A Short Memorandum). Journal of Energy and Power Engineering, 17, 15-26. Zheng, K., Zhu, X., Guo, S., & Zhang, X. (2023). Gamma-ray-responsive drug delivery systems for radiation protection. Chemical Engineering Journal, 463, 142522. Abbasi, A., Zakaly, H. M., & Almousa, N. (2023). Radiotoxic fission products and radiological effects in the Mediterranean Sea biota from a hypothetical accident in Akkuyu Nuclear Power Plant. Marine Pollution Bulletin, 193, 115166. Vali, R., Adelikhah, M. E., Feghhi, S. A. H., Noorikalkhoran, O., & Ahangari, R. (2019). Simulation of radionuclide atmospheric dispersion and dose assessment for inhabitants of Tehran province after a hypothetical accident of the Tehran Research Reactor. Radiation and Environmental Biophysics, 58, 119-128. Kurando, M. (2023). Nuclear Security in Conflict Zones: The Dangerous Case of Zaporizhzhia. International Journal of Nuclear Security, 8(2), 10. | ||
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