Current status of reference location in the basic model for assessment of external radiation doses to the population living in radioactively contaminated areas after the Chernobyl accident

An open plot of virgin land is the reference location in the basic model used to date to estimate the effective dose of external exposure to the population living in a radioactively contaminated area. As our field observations in the Bryansk region of Russia have shown, at present it is very difficult to find truly reference plots of virgin land due to the fact that many virgin meadows were plowed or reclaimed for more than 30 years after the Chernobyl accident. Without special instrumental survey, such disturbed meadow areas can easily be confused with areas of virgin soil. Therefore, the situation with the use of open areas of virgin soil as the reference location has changed dramatically since the first years after the Chernobyl accident. It requires a change in the approach to choosing such a location for the model and/or some revision of the structure of the model itself. Firstly, we propose and justify the use of a permanently cultivated kitchengarden plot as the reference location. The second way to resolve the current difficult situation with the presence of a sufficient number of the virgin soil sites could be excluding the very concept of “reference location” from the model. In this case, when calculating the effective dose of external radiation, it is proposed to directly use the values of the gamma radiation dose rate in the air normalized to the 137Cs contamination density of soil. The values of the normalized dose rate should be experimentally determined in the required time period for each of the locations taken into account in the model.

1. Golikov VYu, Balonov MI, Jacob P. External exposure of the population living in areas of Russia contaminated due to the Chernobyl accident. Radiation and Environmental Biophysics. 2002;41(10): 185–193.

2. Golikov VYu. Dosimetry of external population exposure: a comparison of the Chernobyl and Fukushima accidents. Radiatsionnaya Gygiena = Radiation Hygiene. 2020;13(1): 27–37. (In Russian).

3. Ramzaev VP, Barkovsky AN. Dynamics of decrease of the gamma dose rate in air in rural settlements of the Bryansk region (Russia) in the remote period after the Chernobyl accident. Radiatsionnaya Gygiena = Radiation Hygiene. 2020;13(1): 38–46. (In Russian).

4. Ramzaev VP, Barkovsky AN. Method for identifying areas of virgin soils using a portable gamma-spectrometer-dosimeter. Radiatsionnaya Gygiena = Radiation Hygiene. 2020;13(2): 123–128. (In Russian).

5. Ramzaev V, Bernhardsson C, Dvornik A, Barkovsky A, Vodovatov A, Jönsson M, et al. Calculation of the effective external dose rate to a person staying in the resettlement zone of the Vetka district of the Gomel region of Belarus based on in situ and ex situ assessments in 2016–2018. Journal of Environmental Radioactivity. 2020;214–215: 106168.

6. Ramzaev V, Yonehara H, Hille R, Barkovsky A, Mishine A, Sahoo SK, et al. Gamma-dose rates from terrestrial and Chernobyl radionuclides inside and outside settlements in the Bryansk Region, Russia in 1996–2003. Journal of Environmental Radioactivity. 2006;85: 205–227.

7. Ramzaev VP, Barkovsky AN. Correlation between calculated and measured values of gamma dose rate in air in forests contaminated with 137Cs: the remote period after the Chernobyl accident. Radiatsionnaya Gygiena = Radiation Hygiene. 2019;12(4): 37–46. (In Russian).

8. Ramzaev VP, Barkovsky AN, Bratilova AA. Validation of a method for in situ determination of 137Cs soil contamination density in kitchen gardens using the portable spectrometer-dosimeter MKS AT6101D. Radiatsionnaya Gygiena = Radiation Hygiene. 2021;14(2): 56–65. (In Russian).

9. Ramzaev VP, Barkovsky AN, Bratilova AA. Ambient dose equivalent rate and soil contamination density with 137Cs in kitchen gardens in settlements of the Bryansk region, Russia in 2020–2021. Radiatsionnaya Gygiena = Radiation Hygiene. 2021;14(4): 85–95. (In Russian).

10. Ramzaev VP, Golikov VYu. A comparison of measured and calculated values of air kerma rates from 137Cs in soil. Radiatsionnaya Gygiena = Radiation Hygiene. 2015;8(4): 42–51. (In Russian).

11. Vlasova NG. Assessment of the average annual effective external exposure doses of the settlements of the Republic of Belarus for territory zoning. Mediko-Biologicheskiye Problemy Zhiznedeyatel’nosti = Medical and Biological Problems of Life Activity. 2018; 20(2): 25–30. (In Russian).

12. Eventova LN, Mataras AN, Batyan AN, Vlasova NG, Visenberg YuV. Exposure doses to the population of Belarus from the Chernobyl accident in 2021–2025. Zhurnal Belorusskogo Gosudarstvennogo Universiteta. Ekologiya = Journal of the Belarusian State University. Ecology. 2022;(4): 70–78. (In Russian).

13. Isaksson M, Tondel M, Wålinder R, Rääf C. Modelling the effective dose to a population from fallout after a nuclear power plant accident—A scenario-based study with mitigating actions. PLoS ONE. 2019;14(4): e0215081.

14. UNSCEAR–United Nations Scientific Committee on the Effects of Atomic Radiation. UNSCEAR 2020/2021 Report. Volume II. Scientific Annex B: Levels and effects of radiation exposure due to the accident at the Fukushima Daiichi Nuclear Power Station: implications of information published since the UNSCEAR 2013 Report. United Nations. New York; 2022.

15. Golikov VYu. Verification of model of external population exposure in Japan after the accident at the “Fukushima-1” NPP. Radiatsionnaya Gygiena = Radiation Hygiene. 2020;13(2): 31–40. (In Russian).