Medical Radiology and Radiation Safety. 2021. Vol. 66. № 4. P. 113–121

Radiation and Environmental Aspects of Advanced Nuclear Energy

I.I. Linge, S.S. Utkin

Nuclear Safety Institute, Moscow, Russia

Contact person: Utkin Sergey S: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

The article focuses on the role of radiation criteria and its evolution in the structure of arguments underlying the establishment, operation and development of nuclear energy. It demonstrates that the dominant role of radiation criteria should be reconsidered to allow broader consideration of environmental and other factors associated with sustainable development.

Based on in-depth analysis of certain aspects relevant for the mutual development of nuclear energy and radiation and environmental safety requirements, the paper shows that fully-fledged regulatory and technological systems have been deployed to date to ensure the radiation safety of workers and the public: these systems cover all the tasks required to be addressed to limit the technogenic exposure under normal operation. At the same time, an unprecedented gap was noticed between the actual role of radiation factor across human health risks and its perception by the overwhelming part of society.

In the near future (some hundred years), urgent tasks in the field of radiation safety will be driven, on the one hand, by the need to ensure the internal consistency of the national security system addressing health risks in general, and on the other, by global processes in the world economy associated with slow growth in energy demand, rapid reduction in the share of fossil fuels in almost all sectors of the economy among the developed countries, including transport, growing general environmental trends towards material recycling and decarbonization. The study shows what should be the attitude to radiation risks so that the nuclear energy could successfully meet the requirements arising from these trends. In this regard, the paper also provides some rational interpretation of the principle suggesting that no undue burden should be imposed on future generations.

Key words: nuclear energy, radiation safety, environmental safety, sustainable development, energy efficiency, decarbonization, future generations

For citation:  Linge II, Utkin SS.  Radiation and Environmental Aspects of Advanced Nuclear Energy. Medical Radiology and Radiation Safety. 2021;66(5):113-121.

DOI: 10.12737/1024-6177-2021-66-5-113-121

References

1. Europen Commission Joint Research Centre. JRS Science for Policy Report. Technical Assessment of Nuclear Energy with Respect to the ‘Do No Significant Harm’ Criteria of Regulation (EU) 2020/852 (‘Taxonomy Regulation’). JRC124193. Petten. 2021. 383 p.

2. World Nuclear Association. Climate Change - The Science. 2020 May. (сited 2021 May 24). Available from: https://www.world-nuclear.org/focus/climate-change-and-nuclear-energy/climate-change-the-science.aspx. 

3. Rosatom. Nuclear Power for Sustainable Development: How Nuclear Power Can Contribute to Sustainable Development Goals in the age of Climate Change Challenge. 2019 (cited 2021 May 24). Available from: https://www.rosatom.ru/upload /iblock/d68/d687667b600aca117dc06560562ea503.pdf 

4. Adamov EO, Bolshov LA, Ganev IKh, Zrodnikov AV, Kuznetsov AK, Lopatkin AV, et al. White Paper of Nuclear Power. Moscow: GUP NIKIET; 2001. 269 p. (In Russian).

5. Bolshov LA, Linge II. Development Strategy of Nuclear Energy in Russia and Environmental Issues. Atomic Energy. 2019;127;6:303-9. (In Russian).

6. Velikhov EP, Goltsev AO, Davidenko VD, Elshin AV, Kovalishin AA, Rodionova EV, et al. Acceptability of Closing the Fuel Cycle of Nuclear Energy. VANT. Ser. Thermonuclear Fusion, 2021;44;1:5-12. (In Russian).

7. Kuryndin AV, Polyakov RM, Ponizov AV, Felitsyn MA, Shapovalov AS, Sharafutdinov RB, et al. Comprehensive Comparative Analysis of The Safety of The Implementation of Open and Closed Nuclear Fuel Cycles in the Russian Federation. Methodology and results. Proceedings of the Scientific and Technical Center for Nuclear and Radiation Safety. Moscow: STC NRS Publ., 2021. 59 p. (In Russian).

8. Abalkina IL, Bolshov LA, Linge II, Utkin SS, Saveleva EA, Svitelman VS, Utkin SS. Radioactive Waste and Spent Nuclear Fuel Deep Geological Disposal Long-Term Safety Assessment For 10 000 Years and Over: Methodology and the Current State. IBRAE Preprint No. IBRAE-2019-03. 2019. 40 p. (In Russian).

9. White Paper of Nuclear Power. Closed Nuclear Fuel Cycle with Fast Reactors. Ed. Adamov EO.Moscow, NIKIET Publ., 2020. 496 p. (In Russian).

10. Nuclear Energy Agency Organization for Economic Co-Operation and Development. Nuclear Energy Data 2020. OECD NEA. 2021. No.7556. 28 p.

11. Decommissioning. Vol. 3. Problems of Nuclear Legacy and Ways to Solve Them. Ed. Bolshov LA, Laverov NP, Linge II. Moscow Publ., 2015. 316 p. (In Russian).

12. State Corporation "Rosatom". Strategy for the Development of Nuclear Power in Russia Until 2050 and Prospects for the Period up to 2100. Moscow Publ., 2018. 62 p. (In Russian).

13. Nuclear Energy Agency Organization for Economic Co-Operation and Development. Radiological Impacts of Spent Nuclear Fuel Management Options: A Comparative Study. NEA OECD. 2000. 124 p.

14. Adamov EO, Aleksakhin RM, Bolshov LA, Dedul A.V., Orlov V.V., Pershukov V.A., et al. Breakthrough Project – Technological Basement for Large-Scale Nuclear Energy. News of the Russian Academy of Sciences. Energy. 2015;1:5-13. (In Russian).

15. Ignatiev VV, Kormilitsyn MV, Kormilitsyna LA, Semchenkov YuM, Fedorov YuS, Fainberg ОС, et al. Liquid Salt Reactor for Closing the Nuclear Fuel Cycle for All Actinides. Atomnaya Energiya. 2018;125;5:251-5. (In Russian).

16. Nevstrueva MA, Ramzaev PV, Moiseev AA, Troitskaya MN, Bel'tsev DI, Ibatullin MS, et al. Dynamics of Pollution Levels in the Chain Lichens - Deer - Reindeer Herders Cs-137 and Sr-90 for 1961-1964. Selected Materials of the Bulletin of Radiation Medicine. Ed. Ilyin LA, Samoilov AS. Moscow: FMBC FMBA of Russia Publ., 2016. p.70-77. (In Russian).

17. Special Radioactive Waste. Ed. Linge II. Moscow, Sam Polygraphist Publ., 2015. 240 p. (In Russian).

18. Antipov SV, Arutyunyan RV, Akhunov VD, Bogatov SA et al. Strategic Planning During Decommissioning of Nuclear and Radiation Hazardous Facilities of the Nuclear Fleet in the North-West of Russia. Ed. Sarkisov AA. Moscow, Nauka Publ., 2011. 346 p. (In Russian).

19. Utkin SS. Strategies for Transferring the Techensky Cascade of Water Bodies of FSUE PA Mayak to a Radiation-Safe State. Izvestiya RAN. Energy. 2016;5:132-9. (In Russian).

20. Major Radiation Accidents: Consequences and Protective Measures. Ed. Ilyin LA, Gubanov VA. Moscow, IzdAT Publ., 2001.752 p.

21. IAEA International Chernobyl Project: Technical Report. Assessment of Radiological Consequences and Protective Measures. Report of the International Advisory Committee. Vienna; 1992. 740 p.

22. Barkovsky AN, Bratilova AA, Kormanovskaya TA, Akhmatdinov RR. Dynamics of Exposure Doses to the Population of the Russian Federation for the Period From 2003 to 2018. Radiation Hygiene. 2019;12;4:96-122. (In Russian).

23. Panfilov AP. Historical Aspects of Creation and Development of the Main Objects of the Atomic Industry of the Country. Radiation Impact on Personnel in Different Periods of Time. ANRI. 2020;3:3–25. (In Russian).

24. Sources and Effects of Ionizing Radiation. Report of the UN Scientific Committee on the Effects of Atomic Radiation 2000 to the UN General Assembly with scientific annexes. Volume II: Effects (Part 3). Translation from English. Ed. Ilyin LA, Yarmonenko SP. Moscow: RADEKON Publ., 2002. 352 p. (In Russian).

25. Publication 103 of the International Commission on Radiation Protection (ICRP): Translation from English. Ed Kiselyov MF, Shandala NK. Moscow, Alana Publ., 2009. 344 p. (In Russian).

26. Radiation Protection and Safety of Radiation Sources: International Basic Safety Standards - IAEA Safety Standards No GSR Part 3. Vienna: International Atomic Energy Agency, 2014. 471p.

27. Consequences of Exposure to Human Health as a Result of the Chernobyl Accident. Scientific Annex D to the 2008 UNSCEAR Report to the General Assembly. New York. 2012. 182 p.

28. Joint Convention on the Safety of Spent Fuel Management and on the Safety of Radioactive Waste Management. INFCIRC. 602. Rev 5. 2014. 14 p.

29. Ilyin LA, Knizhnikov VA, Knyazhev VA, Korenkov IP, Komleva VA, Novikova Mya, et al. Oncological Price of Thermal and Nuclear Power. Ed. Ilyin LA, Korenkov IP. 2001. 240 p. (In Russian).

30. Hirschberg, S., Burgherr P., Hunt A. Accident Risks in the Energy Sector: Comparison of Damage Indicators and External Costs. Probabilistic Safety Assessment and Management. 2004:2314-19. DOI: 10.1007 / 978-0-85729-410-4_372.

31. Novikov SM, Shashina TA, Dodina NS, Kislitsin VA, Skovronskaya SA, Matsyuk AV, et al. Practical Research Experience on the Comparative Assessment of Radiation and Chemical Risks to Public Health from the Impact of Environmental Factors. Hygiene and sanitation. 2019; 98;12:1425–31. (In Russian).

32. Burgherr P., Hirschberg S. Comparative Risk Assessment of Severe Accidents in the Energy Sector. Energy Policy. 2014;74:45-56. DOI: 10.1016/j.enpol .2014.01.035. 

33. Onishchenko GG, Novikov SM, Rakhmanin YuA, Avaliani SL, Bushtueva KA. Fundamentals of Risk Assessment for Public Health when Exposed to Chemicals that Pollute the Environment. Ed. Rachmanin YuA, Onishchenko GG. Moscow: NII ECH and GOS Publ., 2002. 408 p. (In Russian).

34. Russian National Report: 35 years of the Chernobyl accident. Results and Prospects of Overcoming its Consequences in Russia. 1986-2021. Ed. Bolshov LA. Moscow, Akadem-Print Publ., 2021. 104 p. (In Russian).

35. Tsebakovskaya NS, Utkin SS, Ivanov AYu, Sakharov VK, Polunin KE. Best Foreign Practices for Decommissioning Nuclear Installations and Remediation of Contaminated Areas. Ed. Linge II, Abramov AA. Moscow, Komtekhprint Publ., 2017. Vol. 1 and 2. (In Russian).

36. State Corporation "Rosatom". Strategy for Creating a Deep Disposal Site for Radioactive Waste. Radioactive waste. Moscow. 2018;2;3:114-20. (In Russian).

37. Federal Law on the Sanitary and Epidemiological Welfare of the Population Dated March 30, 1999 No 52-FZ. (In Russian).

38. Vedernikova MV, Linge II, Panchenko SV, Strizhova SV, Supotaeva ОА, Utkin SS, et al. Topical Issues of Amendments to the Federal Law of January 9, 1996 No. 3-FZ On radiation safety of the population. IBRAE RAN Preprint, No. IBRAE-2020-03. Moscow: IBRAE RAN Publ., 2020. 22 p. (In Russian).

39. Shinkarev SM, Kochetkov OA, Klochkov VN, Barchukov VG. Discussion on amendments to the federal law dated 09.01.1996 No. 3-FZ On the radiation safety of the population. Med. radiology and radiation safety. 2020;65;3:77-78. DOI: 10.12737 / 1024-6177-2020-65-3-77-78. (In Russian).

40. Abramov AA, Dorofeev AN, Deryabin SA. Development of the USS RW in the Framework of the Federal Target Program for Ensuring Nuclear and Radiation Safety. Radioactive Waste. 2019;1;6:8-24. (In Russian).

41. Ivanov EA, Sharov DA, Demyanenko MV, Sharafutdinov RB, Kuryndin AV. On Some Problems of Handling Industrial Waste Containing Technogenic Radionuclides. Nuclear and Radiation Safety. 2019;3;93:3-13. (In Russian).

42. Abramov AA, Bolshov LA, Gavrilov PM, Dorofeev AN, Igin IM, Linge II, et al. On the Ideas of Expanding the System of Radioactive Waste Management to Industrial Waste Containing Technogenic Radionuclides. Radioactive Waste. 2019;4;9:6-13. DOI: 10.25283 / 2587-9707-2019-4-6-13 (In Russian).

43. Tukov AR, Prokhorova ON, Orlov YuV, Talalaeva TG, et al. Health Assessment of Liquidators of the Consequences of the Accident at the Chernobyl Nuclear Power Plant - Workers of the Nuclear Industry in Russia And Residents of the Moscow Region. Med. Radiology and Radiation Safety. 2020;65;1:17-21. (In Russian).

44. IAEA. INPRO Publications. Methodology. Available from: https://www.iaea.org /sites/default/files/20/05/inpro-publications-methodology.pdf (cited 2021 May 24).

45. Ivanov VK, Chekin SYu, Menyailo AN, Maksyutov MA, Kasheeva PV, Lovachev SS, et al. Levels of Radiological Protection of the Population in the Implementation of the Principle of Radiation Equivalence: A Risk-Oriented Approach. Radiation and Risk. 2018;3. Available from: https://cyberleninka.ru/article/n/urovni-radiologicheskoy-zaschity-naseleniya-pri-realizatsii-printsipa-radiatsionnoy-ekvivalentnosti-risk-orientirovannyy-podhod (cited 2021 May 24). (In Russian).

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Conflict of interest. The authors declare no conflict of interest.

Financing. The study had no sponsorship.

Contribution. Article was prepared with equal participation of the authors.

Article received: 23.12.2020. 

Accepted for publication: 20.01.2021.