Earticle

초록

영어

Background: An important lesson learned from the Fukushima accident is that the transition to the mid- and long-term phases from the emergency-response phase requires less than a year, which is not very long. It is necessary to know how much radioactive material has been deposited in an urban area to establish mid- and long-term countermeasures after a radioactive accident. Therefore, an urban deposition model that can indicate the site-specific characteristics must be developed. Materials and Methods: In this study, the generalized urban deposition velocity and the subsequent variation in radionuclide contamination were estimated based on the characteristics of the Korean urban environment. Furthermore, the application of the obtained generalized deposition velocity in a hypothetical scenario was investigated. Results and Discussion: The generalized deposition velocities of 137Cs, 106Ru, and 131I for each residence type were obtained using three-dimensional (3D) modeling. For all residence types, the deposition velocities of 131I are greater than those of 106Ru and 137Cs. In addition, we calculated the generalized deposition velocities for each residential types. Iodine was the most deposited nuclide during initial deposition. However, the concentration of iodine in urban environment drastically decreases owing to its relatively shorter half-life than 106Ru and 137Cs. Furthermore, the amount of radioactive material deposited in nonresidential areas, especially in parks and schools, is more than that deposited in residential areas. Conclusion: In this study, the generalized urban deposition velocities and the subsequent deposition changes were estimated for the Korean urban environment. The 3D modeling was performed for each type of urban residential area, and the average deposition velocity was obtained and applied to a hypothetical accident. Based on the estimated deposition velocities, the decision- making systems can be improved for responding to radioactive contamination in urban areas. Furthermore, this study can be useful to predict the radiological dose in case of large-scale urban contamination and can support decision-making for long-term measurement after nuclear accident.

목차

ABSTRACT
Introduction
Materials and Methods
1. Deposition Velocities on Urban Surfaces
2. Modeling of Urban Residential Area
Results and Discussion
1. Generalized Urban Deposition Velocity and Weathering Effect
2. Hypothetical Nuclear Facility Accident Scenario
3. Radioactive Source and Geographic Information
Conclusion
Conflict of Interest
Acknowledgements
References

키워드

저자

• Joeun Lee [ Environmental Safety Assessment Research Division, Korea Atomic Energy Research Institute, Daejeon, Korea ] Corresponding author
• Moon Hee Han [ Environmental Safety Assessment Research Division, Korea Atomic Energy Research Institute, Daejeon, Korea ]
• Eun Han Kim [ Environmental Safety Assessment Research Division, Korea Atomic Energy Research Institute, Daejeon, Korea ]
• Cheol Woo Lee [ Environmental Safety Assessment Research Division, Korea Atomic Energy Research Institute, Daejeon, Korea ]
• Hae Sun Jeong [ Environmental Safety Assessment Research Division, Korea Atomic Energy Research Institute, Daejeon, Korea ]

참고문헌

발행기관

간행물

표지보기 관심저널 등록

• 간행물명

  방사선방어학회지 [Journal of Radiation Protection and Research]

• 간기

  계간

• pISSN

  2508-1888

• 수록기간

  1976~2026

• 등재여부

  KCI 등재,SCOPUS

• 십진분류

  KDC 559 DDC 629