Науковий вісник НГУ

Radiation hazard research at the Base-S industrial site using modeling

• 
• 

User Rating:  / 0

PoorBest 

Details

Category: Content №1 2026

Last Updated on 27 February 2026

Published on 30 November -0001

Hits: 2101

Authors:

O. V. Pylypenko, orcid.org/0009-0007-2987-7905, Ukrainian State University of Science and Technologies ERI “Prydniprovska State Academy of Civil Engineering and Architecture”, Dnipro, Ukraine, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

A. S. Belikov, orcid.org/0000-0001-5822-9682, Ukrainian State University of Science and Technologies ERI “Prydniprovska State Academy of Civil Engineering and Architecture”, Dnipro, Ukraine

V. A. Shalomov*, orcid.org/0000-0002-6880-932X, Ukrainian State University of Science and Technologies ERI “Prydniprovska State Academy of Civil Engineering and Architecture”, Dnipro, Ukraine

T. A. Kovtun-Horbachova, orcid.org/0000-0002-0948-1299, Ukrainian State University of Science and Technologies ERI “Prydniprovska State Academy of Civil Engineering and Architecture”, Dnipro, Ukraine

V. V. Harchenko, orcid.org/0000-0002-7653-3001, Dnipropetrovsk Scientific Research Forensic Center of the Ministry of Internal Affairs, Dnipro, Ukraine

* Corresponding author e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

повний текст / full article

Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 2026, (1): 100 - 109

https://doi.org/10.33271/nvngu/2026-1/100

Abstract:

Purpose. To conduct comprehensive experimental studies at the industrial site of the former uranium production facility of the Prydniprovsky Chemical Plant and determine the value of the equivalent gamma dose rate to predict the dynamics of changes in radiation contamination at the “Base-S” industrial site.

Methodology. The theoretical, statistical, analytical and graphical modelling methods were used in the study with the use of 2D/3D models at nuclear fuel complex facilities, which include radiation-hazardous areas, burial sites, tailing pits and industrial sites with radioactive substances, materials or waste.

Findings. On the basis of the conducted research, the indicators of radiation contamination for the period 2009–2019 were determined. We developed and implemented 2D and 3D models for presenting the results obtained, with geolocation reference to each measurement point. Annual maps of radiation contamination were constructed, which allows forecasting the situation in the future. The maximum, minimum and average values for each section of the outfit path along which the facility personnel walk were determined, the dynamics of fluctuations in the equivalent dose rate was determined, additional studies were conducted on the required number of measurements to obtain the optimal time spent on the perimeter, and maps of radiation contamination of the industrial site were constructed.

Originality. For the first time, based on the data obtained, statistical and analytical processing of the results was carried out, taking into account the specifics of the developed two-dimensional or three-dimensional model, determining the data in clear space by approximating the linear function. The developed models implement the principle of adaptation of the obtained field measurement results and allow for a more accurate determination of the boundaries of radiation contamination zones at the industrial site through their visualization using 2D/3D models. Radiation risk parameters for the ‘Base-S’ industrial site were identified, and their temporal patterns and variations were analyzed, enabling a comprehensive approach to the implementation of radiation safety measures. For the first time, the developed 2D/3D models were applied, which correspond to the exact location of certain exposure zones. For greater visual perception of the model, it is proposed to represent different zones with four colours (from green to red), which allows determining the location and time of being in a certain location, on a given segment or in a certain zone of the “Base-S” industrial site.

Practical value. On the basis of the obtained experimental research, methodological recommendations for the implementation of new developments have been developed, improvement of the existing approaches of walking and remote sensing and implementation of modelling possible situations at radiation-contaminated sites. The built 2D/3D models allow us to assess the real situation at the industrial site over time and reduce the risk of additional exposure of personnel of the radiation-hazardous facility, the former uranium production facility of PChP located in the Dnipro region.

Keywords: radiation hazard, dose, tailing dump perimeter, 2D/3D model, industrial site

References.

1. Verkhovna Rada of Ukraine (2000). On licensing activities in the field of nuclear energy use. The Official Bulletin of the Verkhovna Rada of Ukraine (BVR), 2000, No. 9, Art. 68. Retrieved from https://zakon.rada.gov.ua/laws/show/1370-14#Text

2. Verkhovna Rada of Ukraine (1997). On the Enactment of the State Hygiene Standards “Radiation Safety Standards of Ukraine (NRBU-97)”. Document v0062282-97. Retrieved from https://zakon.rada.gov.ua/rada/show/v0062282-97#Text

3. Verkhovna Rada of Ukraine (2005). On Approval of the State Sanitary Rules “Basic Sanitary Rules for Ensuring Radiation Safety of Ukraine”. Document z0552-05 (Ukraine). Retrieved from https://zakon.rada.gov.ua/laws/show/z0552-05#Text

4. International Atomic Energy Agency (IAEA), Vienna (2020, September). Climate change and nuclear power 2020. Retrieved from https://www.iaea.org/publications/14725/climate-change-and-nuclear-power-2020

5. Masson-Delmotte, V., Zhai, P., Pörtner, H.-O., Roberts, D., Skea J., Shukla, P. R., Pirani, A., …, & Waterfield, T. (2018). Global Warming of 1.5 °C. Cambridge CB2 8BS: University Printing House, United Kingdom. Retrieved from https://www.cambridge.org/core/services/aop-cambridge-core/content/view/D7455D42B4C820E706A03A169B1893FA/9781009157957AR.pdf/Global_Warming_of_1_5_C.pdf?event-type=FTLA

6. Verkhovna Rada of Ukraine (2017). On approval of the Energy Strategy of Ukraine for the period up to 2035 “Security, Energy Efficiency, Competitiveness”. Document 605-2017-р. Retrieved from https://zakon.rada.gov.ua/laws/show/605-2017-%D1%80#Text

7. Verkhovna Rada of Ukraine (2023). On approval of the Energy Stra­te­gy of Ukraine for the period up to 2050. Document 373-2023-р. Retrieved from https://zakon.rada.gov.ua/laws/show/373-2023-%D1%80#Text

8. Government portal (2003). On Approval of the State Programme for bringing hazardous facilities of the Prydniprovsky Chemical Plant into an environmentally safe state and ensuring protection of the population from the harmful effects of ionising radiation. Resolution of the Cabinet of Ministers of Ukraine No. 1846. Retrieved from https://www.kmu.gov.ua/npas/3599908

9. Verkhovna Rada of Ukraine (2019). On Approval of the State Target Environmental Programme for Priority Measures to Bring the Facilities and Site of the Former Uranium Production of the Prydniprovsky Chemical Plant to a Safe Condition for 2019-2023. Document 756-2019-п. Retrieved from https://zakon.rada.gov.ua/laws/show/756-2019-%D0%BF#Text

10.      International Atomic Energy Agency (IAEA), Paris (2024, September). The World Nuclear Industry Status Report 2024. Retrieved from https://www.worldnuclearreport.org/IMG/pdf/ wnisr2024-v4.pdf

11.      National Commission for Radiation Protection of the Population of Ukraine (2018). Analytical review of the state of industrial and natural safety in Ukraine in 2018. Retrieved from https://nkrzu.gov.ua/res/bib

12.      International Atomic Energy Agency (IAEA), Vienna (2020, April). Occupational radiation protection in the uranium mining and processing industry Safety reports series No. 100. Retrieved from
https://www-pub.iaea.org/MTCD/Publications/PDF/PUB1890_web.pdf

13.      Ota, M., Takahara, S., Yoshimura, K., Nagakubo, A., Hirouchi, J., Hayashi, Naho., Abe, T., Funaki, H., & Nagai, H. (2023). Soil dust and bioaerosols as potential sources for resuspended 137Cs occurring near the Fukushima Dai-ichi nuclear power plant. Journal of Environmental Radioactivity, 264, 107198. https://doi.org/10.1016/j.jenvrad.2023.107198

14.      Hoffman, I., Mekarski, P., Botti, A., Yi, J., Malo, A., Cochrane, C., Khotylev, V., …, & Ungar, K. (2024). Determination of the source location of anthropogenic radionuclides collected in Finland and Sweden in June 2020 using a multi-technology analysis. Journal of Environmental Radioactivity, 278, 107508-107198. https://doi.org/10.1016/j.jenvrad.2024.107508

15.      Nkoulou, J. E. N., Engola, L. N., Dallou, G. B., Saïdou Bongue, D., Hosoda, M., …, & Tokonami, S. (2023). Public Exposure to Natural Radiation and the Associated Increased Risk of Lung Cancer in the Betare-Oya Gold Mining Areas, Eastern Cameroon. Journal of Radiation Protection and Research, 48(2), 59-67. https://doi.org/10.14407/jrpr.2021.00388

16.      Ghazal, A. A., Alakash, R., Aljumaili, Z., El-Sayed, A., & Abdel-Rahman, H. (2023). Enhancing Gamma-Neutron Shielding Effectiveness of Polyvinylidene Fluoride for Potent Applications in Nuclear Industries: A Study on the Impact of Tungsten Carbide, Trioxide, and Disulfide Using EpiXS, Phy-X/PSD, and MCNP5 Code. Journal of Radiation Protection and Research, 48(4), 184-196. https://doi.org/10.14407/jrpr.2023.00213

17.      Lee, Y., Choi, J. W., Braunstein, L., Lee, C., & Yeom, Y. S. (2024). Investigation on Individual Variation of Organ Doses for Photon External Exposures: A Monte Carlo Simulation Study. Journal of Radiation Protection and Research, 49(1), 50-64. https://doi.org/10.14407/ jrpr.2023.00661

18.      Poorbaygi, H., Salimi, S. M., Torkzadeh, F., Hamidi, S., & Sheibani, S. (2023). Determination of Exposure during Handling of 125I Seed Using Thermoluminescent Dosimeter and Monte Carlo Method Based on Computational Phantom. Journal of Radiation Protection and Research, 48(4), 197-203. https://doi.org/10.14407/jrpr.2023.00255

19.      Smith, J. T., Levchuk, S. E., Bugai, D. A., Beresford, N. A., Wood, M. D., Khomutinin, Y. V., Laptev, G.V., & Kashparov V. A. (2025). A protocol for the radiological assessment for agricultural use of land in Ukraine abandoned after the Chornobyl accident. Journal of Environmental Radioactivity, 286, 107698. https://doi.org/10.1016/j.jenvrad. 2025.107698

20.      Pylypenko, O., Zelensky, A., Rybalka, K., Kolokhov, V., & Nazha, P. (2025). Express method for determining power of equivalent dose in radiation-contaminated territories of radioactive tailings storage facilities. Chemical engineering: Ecology and environmental technology. Technology Audit and Production Reserves, 3(3(83)), 48-55. https://doi.org/10.15587/2706-5448.2025.331755

21.      Pylypenko, O. V., Zhelezniak, H. S., Sankov, P. M., Rybalka, K. A., & Tymofieiev, V. V. (2025). Application of research methods for determination and modelling of radiation parameters at industrial sites and tailing pits. In E. Pluzhnik, (Ed.). Development of higher education: trends and prospects, 87-99. Retrieved from https://isg-konf.com/development-of-higher-education-trends-and-prospects/

22.      Ecotest (2025). Search gamma-beta radiation dosimeter-radiometer MKS-07 “Search”. Retrieved from https://ecotest.ua/products/mks-07/

23.      Pylypenko, O. V. (2024). Dynamics of determination of actual and predicted values of equivalent dose rate at the “Sukhachivske” tailing dump, section II. In E. Pluzhnik (Ed). International Science Group, 115-125. Retrieved from https://isg-konf.com/innovative-scientific-research-theory-methodology-practice/

24.      Pylypenko, O. V., Sankov, P. M., Rahimov, S. Yu., Rybalka, K. A., & Karasjov, H. H. (2023). Analysis of the characteristics of large remotely controlled ground vehicles for conducting monitoring studies at tailings ponds of the former uranium production facility VO ‘PChP’ 2023. In E. Pluzhnik (Ed). International Science Group, 545-557. Retrieved from https://isg-konf.com/information-activity-as-a-component-of-science-development/

25.      Pylypenko, O. V., Sankov, P. M., Nazha, P. M., Palamarchuk, V. M., & Rudenko, V. P. (2025) Remotely piloted aerial vehicles for radiation surveys. In E. Pluzhnik (Ed). Proceedings of the XIV International Scientific and Practical Conference, (pp.118-128). Retrieved from https://isg-konf.com/transformations-of-the-individual-and-society-challenges-of-the-future/

• < Prev
• Next >