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Assessment of the Potential Radiation Hazard of the Adrasman Tailing Dump (Tajikistan) for the Population Living Around It

Received: 17 May 2022     Accepted: 6 June 2022     Published: 30 June 2022
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Abstract

The article features the outcomes of radiation monitoring in the territory of the Adrasman tailing dump and around it. Radiation monitoring was carried out by dividing the study area into several parts using the PackEye FHT1377 radiation detection kit. Some local points with increased values of ambient dose rate of gamma radiation were discovered. This is due to the transfer of radioactive material from the body of the tailing dump through atmospheric precipitation waters. Mudflows after heavy rains, flowing over the surface of the tailing dump, destroy its coating on the edges and carry the tailing material down the relief, polluting the environment. It has been established that at the destroyed boundary of the radioactive Adrasman tailing dump, the ambient dose rate reaches 3.7 µSv/h. Within the populated part of the Adrasman settlement, the ambient dose rate ranges from 0.10 to 0.30 µSv/h. The situation is aggravated by the fact that the contaminated area is used by residents of nearby houses for agricultural production and livestock grazing, as well as the use of tailing material in the construction of residential buildings. These circumstances negatively affect the radiation situation in this area. The study results demonstrated that the values of annual radiation doses are in the range from 3.15 to 21.47 mSv/year. The most significant contribution to exposure is made by: external gamma radiation; radon emitted from the surface of the tailing dump (if people stay on its surface); radon emitted from the structures of houses in the construction of which tailing materials were used. The given estimate of the dose up to 21.47 mSv/year is quite high and unacceptable in comparison with the accepted safe dose limit for the population of 1 mSv/year over the natural background. Based on the results of the radioecological monitoring carried out, it is proposed: to stabilize the radiation situation and to prevent the tailing material from being washed away, to build a drainage channel; in the future, aimed at actually improving the radiation situation, to carry out a set of reclamation measures in the area of the radioactive Adrasman tailing dump.

Published in Journal of Health and Environmental Research (Volume 8, Issue 2)
DOI 10.11648/j.jher.20220802.20
Page(s) 151-158
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2022. Published by Science Publishing Group

Keywords

Adrasman, Tailing Dump, Radiation, Monitoring, Dosimeter, Radiometer of Radon, Dose, Assessment

References
[1] Khakimov N., Nazarov Kh. M., Mirsaidov I. U. (2012). Physico-chemical and manufacturing basis for uranium concentrates production from wastes of hydrometallurgical plants and technical waters. Dushanbe: Mavlavi, 210.
[2] Lespukh, E., Stegnar, P., Yunusov, M., Tilloboev, H., Zyazev, G., Kayukov, P., Hosseini, A., Strømman, G., Salbu B. (2013). Assessment radiological impact of gamma and radon dose rates at former U mining sites in Tajikistan. Journal of Environmental Radioactivity, 126, 147-155.
[3] Official site Thermo Fisher Scientific. PackEye Radiation Detection Backpack. URL: https://www.thermofisher.com/order/catalog/product/FHT1377
[4] Method for the rapid measurement of the radon flux density from the earth’s surface using a RRA-type radon radiometer. – Moscow: TsNII GP «VNIIFTRI», 2006, 20 (in Russian).
[5] Ermatov, K. A., Nazarov, Kh. M., Salomov, J., Bahronov, S. M., Mirsaidov, U. (2018). Assessment of potential radiation hazard of the former uranium facilities for the population of the Istiqlol city of the Republic of Tajikistan. Radiation hygiene, 11 (2), 83-90 (in Russian).
[6] Sources and Effects of Ionizing Radiation. (2000). UNSCEAR 2000 Report to the General Assembly, with Scientific Annexes. Volume I: Sources. Annex B: Exposures from natural radiation sources. New York, United Nations, 76.
[7] Ionizing Radiation Effects (2009). UNSCEAR 2006 Report to the General Assembly with Scientific Annexes. Volume II: Scientific Annexes C, D and E. Annex E: Sources-to-effects assessment for radon in homes and workplaces. New York, United Nations, 142.
[8] WHO handbook on indoor radon: a public health perspective. (2009). Geneva: WHO Press, 110.
[9] Karpov Yu. A., Savostin A. P. (2015). Sampling and sample preparation methods. 3rd ed. (E). Moscow: BINOM. Knowledge laboratory, 246 (in Russian).
[10] Interstate standard GOST 17.4.3.01-2017. (2019). Environmental protection. Soils. General requirements for sampling. URL: http://docs.cntd.ru (In Russian).
[11] Nisar Ahmad [et al.]. (2017). An overview of radon concentration in Malaysia. Journal of Radiation Research and Applied Sciences, 10 (4), 327-330.
[12] Ciotoli G. [et al.]. (2017). Geographically weighted regression and geostatistical techniques to construct the geogenic radon potential map of the Lazio region: A methodological proposal for the European Atlas of Natural Radiation. Journal of Environmental Radioactivity, 166 (2), 355-375.
[13] Baeza А. [et al.]. (2018). Influence of architectural style on indoor radon concentration in a radon prone area: A case study. Science of the total environment, 610-611, 258-266.
[14] Al-Khateeb H. M. [et al.]. (2017). Seasonal variation of indoor radon concentration in a desert climate. Applied Radiation and isotopes, 130, 49-53.
[15] Mirsaidov U. M., Nazarov Kh. M., Shosafarova Sh. G., Makhmudova M. M. (2020). Radon monitoring in the territory of Northern Tajikistan. Radiation hygiene, 13 (1), 68-73 (in Russian).
[16] Radiation safety standards (NRB-06 SP 2.6.1. 001-06), (2006). Dushanbe, Ministry of Justice of the Republic of Tajikistan, 172 (in Russian).
[17] Chen J., Rahman N. M., Atiya I. A. (2010). Radon exhalation from building for decorative use. Journal of Environ. Radioact, 101 (4), 317-322.
[18] Radiological Protection against Radon Exposure. (2014). ICRP Publication 126. Ann. ICRP, 43 (3), 73.
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    Ulmas Mirsaidov, Kholmurod Maripovich Nazarov, Boboev Begmurot Dustovich, Rahimberdiev Shukurjon Akhmatkulovich, Mukhamedova Svetlana Galievna, et al. (2022). Assessment of the Potential Radiation Hazard of the Adrasman Tailing Dump (Tajikistan) for the Population Living Around It. Journal of Health and Environmental Research, 8(2), 151-158. https://doi.org/10.11648/j.jher.20220802.20

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    ACS Style

    Ulmas Mirsaidov; Kholmurod Maripovich Nazarov; Boboev Begmurot Dustovich; Rahimberdiev Shukurjon Akhmatkulovich; Mukhamedova Svetlana Galievna, et al. Assessment of the Potential Radiation Hazard of the Adrasman Tailing Dump (Tajikistan) for the Population Living Around It. J. Health Environ. Res. 2022, 8(2), 151-158. doi: 10.11648/j.jher.20220802.20

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    AMA Style

    Ulmas Mirsaidov, Kholmurod Maripovich Nazarov, Boboev Begmurot Dustovich, Rahimberdiev Shukurjon Akhmatkulovich, Mukhamedova Svetlana Galievna, et al. Assessment of the Potential Radiation Hazard of the Adrasman Tailing Dump (Tajikistan) for the Population Living Around It. J Health Environ Res. 2022;8(2):151-158. doi: 10.11648/j.jher.20220802.20

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  • @article{10.11648/j.jher.20220802.20,
      author = {Ulmas Mirsaidov and Kholmurod Maripovich Nazarov and Boboev Begmurot Dustovich and Rahimberdiev Shukurjon Akhmatkulovich and Mukhamedova Svetlana Galievna and Matin Zafarjonovich Akhmedov},
      title = {Assessment of the Potential Radiation Hazard of the Adrasman Tailing Dump (Tajikistan) for the Population Living Around It},
      journal = {Journal of Health and Environmental Research},
      volume = {8},
      number = {2},
      pages = {151-158},
      doi = {10.11648/j.jher.20220802.20},
      url = {https://doi.org/10.11648/j.jher.20220802.20},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jher.20220802.20},
      abstract = {The article features the outcomes of radiation monitoring in the territory of the Adrasman tailing dump and around it. Radiation monitoring was carried out by dividing the study area into several parts using the PackEye FHT1377 radiation detection kit. Some local points with increased values of ambient dose rate of gamma radiation were discovered. This is due to the transfer of radioactive material from the body of the tailing dump through atmospheric precipitation waters. Mudflows after heavy rains, flowing over the surface of the tailing dump, destroy its coating on the edges and carry the tailing material down the relief, polluting the environment. It has been established that at the destroyed boundary of the radioactive Adrasman tailing dump, the ambient dose rate reaches 3.7 µSv/h. Within the populated part of the Adrasman settlement, the ambient dose rate ranges from 0.10 to 0.30 µSv/h. The situation is aggravated by the fact that the contaminated area is used by residents of nearby houses for agricultural production and livestock grazing, as well as the use of tailing material in the construction of residential buildings. These circumstances negatively affect the radiation situation in this area. The study results demonstrated that the values of annual radiation doses are in the range from 3.15 to 21.47 mSv/year. The most significant contribution to exposure is made by: external gamma radiation; radon emitted from the surface of the tailing dump (if people stay on its surface); radon emitted from the structures of houses in the construction of which tailing materials were used. The given estimate of the dose up to 21.47 mSv/year is quite high and unacceptable in comparison with the accepted safe dose limit for the population of 1 mSv/year over the natural background. Based on the results of the radioecological monitoring carried out, it is proposed: to stabilize the radiation situation and to prevent the tailing material from being washed away, to build a drainage channel; in the future, aimed at actually improving the radiation situation, to carry out a set of reclamation measures in the area of the radioactive Adrasman tailing dump.},
     year = {2022}
    }
    

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  • TY  - JOUR
    T1  - Assessment of the Potential Radiation Hazard of the Adrasman Tailing Dump (Tajikistan) for the Population Living Around It
    AU  - Ulmas Mirsaidov
    AU  - Kholmurod Maripovich Nazarov
    AU  - Boboev Begmurot Dustovich
    AU  - Rahimberdiev Shukurjon Akhmatkulovich
    AU  - Mukhamedova Svetlana Galievna
    AU  - Matin Zafarjonovich Akhmedov
    Y1  - 2022/06/30
    PY  - 2022
    N1  - https://doi.org/10.11648/j.jher.20220802.20
    DO  - 10.11648/j.jher.20220802.20
    T2  - Journal of Health and Environmental Research
    JF  - Journal of Health and Environmental Research
    JO  - Journal of Health and Environmental Research
    SP  - 151
    EP  - 158
    PB  - Science Publishing Group
    SN  - 2472-3592
    UR  - https://doi.org/10.11648/j.jher.20220802.20
    AB  - The article features the outcomes of radiation monitoring in the territory of the Adrasman tailing dump and around it. Radiation monitoring was carried out by dividing the study area into several parts using the PackEye FHT1377 radiation detection kit. Some local points with increased values of ambient dose rate of gamma radiation were discovered. This is due to the transfer of radioactive material from the body of the tailing dump through atmospheric precipitation waters. Mudflows after heavy rains, flowing over the surface of the tailing dump, destroy its coating on the edges and carry the tailing material down the relief, polluting the environment. It has been established that at the destroyed boundary of the radioactive Adrasman tailing dump, the ambient dose rate reaches 3.7 µSv/h. Within the populated part of the Adrasman settlement, the ambient dose rate ranges from 0.10 to 0.30 µSv/h. The situation is aggravated by the fact that the contaminated area is used by residents of nearby houses for agricultural production and livestock grazing, as well as the use of tailing material in the construction of residential buildings. These circumstances negatively affect the radiation situation in this area. The study results demonstrated that the values of annual radiation doses are in the range from 3.15 to 21.47 mSv/year. The most significant contribution to exposure is made by: external gamma radiation; radon emitted from the surface of the tailing dump (if people stay on its surface); radon emitted from the structures of houses in the construction of which tailing materials were used. The given estimate of the dose up to 21.47 mSv/year is quite high and unacceptable in comparison with the accepted safe dose limit for the population of 1 mSv/year over the natural background. Based on the results of the radioecological monitoring carried out, it is proposed: to stabilize the radiation situation and to prevent the tailing material from being washed away, to build a drainage channel; in the future, aimed at actually improving the radiation situation, to carry out a set of reclamation measures in the area of the radioactive Adrasman tailing dump.
    VL  - 8
    IS  - 2
    ER  - 

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Author Information
  • Chemical, Biological, Radiological and Nuclear Safety and Security Agency, National Academy of Sciences of Tajikistan, Dushanbe, Tajikistan

  • Chemical, Biological, Radiological and Nuclear Safety and Security Agency, National Academy of Sciences of Tajikistan, Dushanbe, Tajikistan

  • Chemical, Biological, Radiological and Nuclear Safety and Security Agency, National Academy of Sciences of Tajikistan, Dushanbe, Tajikistan

  • Chemical, Biological, Radiological and Nuclear Safety and Security Agency, National Academy of Sciences of Tajikistan, Dushanbe, Tajikistan

  • Department of Histology, Cytology and Embryology, First Moscow State Medical University Named After I. M. Sechenov, Ministry of Health of the Russian Federation, Moscow, Russian Federation

  • Chemical, Biological, Radiological and Nuclear Safety and Security Agency, National Academy of Sciences of Tajikistan, Dushanbe, Tajikistan

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