Prior to dismantling a nuclear facility, full site characterization should be carried out to identify basic data for various stages of decommissioning, such as deregulation of sites and structures, selection of decontamination technology, decommissioning methods, and waste management and disposal. Radiological characterization is implemented through information collection, on-site measurement, sampling and analysis, and theoretical calculations and proven codes for radioactive material at the time of decommissioning of the nuclear facility. There are issues in that it takes a lot of time and money to collect and analyze samples for characterization of contaminated sites and radioactive structures. Therefore, in the entire process of decommissioning a nuclear facility, a technology that can quickly measure the radiological characteristics of various decommissioning objects and wastes on site is required. In this project, the utilization of gamma cameras that can be analyzed in the field for quick and accurate characteristic evaluation at the dismantling site was studied. A gamma camera, iPIX from Canberra (Now it became Mirion Technology), was tested in this study. It is a unique gamma imager, which have a CdTe sensor with TIMEPIX chip and a coded aperture collimator, quickly locates and identifies low to high level radioactive sources from a distance while estimating the dose rate at the measurement point in real time. It also can be combined with CZT sensor which called iPIX-NID (nuclide Identification) provides users with clear understanding of radionuclides presence with no need of any spectroscopic knowledge. iPIX with iPIX-NID convert the gamma camera into a hot-spot detector with radionuclide information. To verify the applicability of a gamma camera in Nuclear power plant, it was implemented to Kori unit-1 which was permanently shut down from 2017. Various Systems were observed at restricted area including reactor cooling system, boron recovery system, residual heat removal system, containment spray system, and etc. The locations of hot spots were clearly revealed by iPIX and these results can be used for selecting the locations of destructive samples and help to decide the conservative decision making. Condensate water systems in turbine building were also observed by a gamma camera and showed no nuclide. Based on this preliminary gamma camera applications, further investigation and tests will be carried out to Kori Unit-1.

확산형 콜리메이터는 촬영 대상을 축소 촬영하거나 넓은 관심영역을 작은 감마카메라를 사용하여 검출 하기 위해서 사용한다. 확산형 콜리메이터와 블록형 섬광체 및 픽셀형 섬광체 배열을 사용하는 감마카메라 에서 방사선원이 관심영역 주변에 위치할 때 섬광체 표면에 감마선이 대각선으로 입사하게 되면, 섬광체 깊이 방향으로 대각선으로 검출되기 때문에 공간 분해능이 저하된다. 본 연구에서는 이러한 관심영역 외곽에서의 공간 분해능을 향상하기 위한 새로운 시스템을 설계하였다. 사다리꼴 픽셀형 섬광체를 사용하여 각 섬광 픽셀을 콜리메이터 구멍의 각도와 크기에 맞게 일치하도록 구성하면, 감마선이 섬광체의 여러 깊이에서 반응하더라도, 하나의 섬광 픽셀 위치로 영상화 할 수 있다. 즉, 대각선 방향의 여러 지점에서 검출되더라도, 감마선은 하나의 섬광 픽셀과 상호 작용하기 때문에 공간 분해능의 저하가 발생하지 않는다. Geant4 Application for Tomographic Emission (GATE) 시뮬레이션을 통해 블록형 섬광체를 사용한 감마카메라와 사다리꼴 픽셀형 섬광체를 사용한 감마카메라를 설계하여 공간 분해능을 비교 평가하였다. 관심영역 외곽에서 발생한 감마선을 통해 획득한 영상에서 공간 분해능은 블록형 섬광체를 사용한 감마카메라에서는 4.05 mm였고, 사다리꼴 픽셀형 섬광체를 사용한 감마카메라에서는 2.97 mm의 공간 분해능을 보였다. 사다리꼴 픽셀형 섬광체를 사용한 시스템에서 26.67% 공간 분해능이 향상됨을 확인할 수 있었다.