It has been studied on the disposal area reduction for the used nuclear fuel by the management of high decay-heat nuclides, long-lived nuclides, and highly mobile nuclides. It was investigated on the management of the nuclides in KAERI. Strontium-90 is a high heat-generating nuclide in spent nuclear fuel. It is needed to separate the salt from the salt solution for the recovery of strontium after the chlorination of the strontium oxide in molten salt. Vacuum distillation was used for the separation of strontium from the molten salt. Potassium carbonate was chosen as a reactive distillation reagent for SrCl2 – LiCl – KCl system by the thermodynamic calculation. Reactive distillation experiments were carried out. The residual was mainly SrCO3 in the XRD analysis. It could be concluded that K2CO3 could be one of the suitable reagents for the reactive distillation. The salt in the long–lived nuclide powders should be removed to prepare the block for disposal. Experiments were carried out using W powders (surrogate) and U3O8 powders to develop a process for the removal of the residual salt from UOx powders. The salts were successfully removed from the W and U3O8 powders by distillation.

용융탄산염 연료전지는 650˚C의 부식성이 강한 용융탄산염내에서 작동되므로, 분리판 재료로 사용되고 있는 316L 스테인레스강의 부식은 용융탄산염 연료전지의 수명을 단축시키는 주요한 원인이다. 특히 분리판 wet-seal부의 부식은 보다 심각한 것으로 알려져 있다. 이를 해결하기 위하여 AI계 합금이 피복재료로 사용되어 왔지만, 본 연구에서는 보다 우수한 분리판 wet-seal부의 내식 피복재료 개발을 위하여 피복재료인 NiAI 합금에 산화 활성화 원소인 yttrium을 최고 1.5 at%까지 첨가하였다. 650˚C의 용융탄산염내에서 yttium 함량에 따른 NiAI/Y 합금의 침지부식실험 및 분극실험을 통하여 내식성을 평가하고 부식 억제를 위해 가장 적절한 NiAI/Y 피복 재료의조성을 결정한 결과 최소의 yttrium 조성은 0.7 at% 임을 알 수 있었다.

To prevent climate change which is thought to be caused by the carbon dioxide emitted from industrial facilities by human activities, the efforts to reduce the concentrations of carbon dioxide in the atmosphere have been widely made. One of the method is to capture carbon dioxide by liquid absorbent. In this method, flue gas containing carbon dioxide is introduced to the absorber where the absorbent captures carbon dioxide selectively. After capturing, carbon dioxide is separated by heat at desorber and separated CO2 is transprted to storage site such as deep ocean or underground. However, stored CO2 is not permanently stable and these can be problematic that can cause ecosystem destruction due to low pH of the gas. By applying metal cation supplying unit after the capture process, carbon dioxide can be converted to metal carbonate salt in solid phase which can be stored stably or can be utilized or reused for industrial application. In this research, the mechanisms of carbon dioxide conversion were suggested and basic properties and conditions of the system were introduced.