For decontamination and quantification of trace amount of tritium in water, an efficient separation technology capable of enriching tritium in water is required. Electrolysis is a key technology for tritium enichment as it has a high H/T and D/T separation factors. To separate tritium, it is important to develop a proton exchange membrane (PEM) electrolyzer having high hydrogen isotope separation factor as well as high electrolyzer cell efficiency. However, there has not been sufficient research on the separation factor and cell efficiency according to the composition and manufacturing method of the membrane electrode assembly (MEA) Therefore, it is necessary to study the optimal composition and manufacturing method of the MEA in PEM electrolyzer. In this study, the H/D separation factor and water electrolysis cell efficiency of PEM electrolyzer were analyzed by changing the anode and cathode materials and electrode deposition method of the MEA. After the water electrolysis experiment using deionized water, the D/H ratio in water and hydrogen gas was measured using a cavity ring down spectrometer and a mass spectrometer, respectively, and the separation factor was calculated. To calculate the cell efficiency of water electrolysis, a polarization curves were obtained by measuring the voltage changes while increasing the current density. As a result of the study, the water electrolyzer cell efficiency of the MEA fabricated with different anode/cathode configurations and electrode formation methods was higher than that of commercial MEA. On the other hand, the difference in H/D separation factor was not significant depending on the MEA fabrication methods. Therefore, using a cell with high cell efficiency when the separation factor is the same will help construct a more efficient water electrolysis system by lowering the voltage required for water electrolysis.

본 연구에서는 음이온 교환막 수전해 시스템에 적용가능성을 확인하고자 상용 음이온 교환막인 FAA-3-50, Neosepta-ASE, Sustainion grade T, Fujifilm type 10의 관련 물성을 평가하였다. 음이온교환막을 이용하는 특성상 음이온교환 기의 확인을 위하여 SEM/EDX를 이용하여 상용막의 모폴로지와 표면의 원소를 분석하여 상용막이 포함하고 있는 작용기의 분포를 확인하였다. 또한, UTM과 TGA를 이용하여 기계적 강도 및 열분해온도를 측정하여 수전해의 구동조건을 만족하는지 확인하였다. 음이온 교환막으로서의 성능을 파악하기 위하여 중요한 특성인 이온교환용량과 이온전도도를 측정하였으며, 알 칼리 환경에서 구동되기 때문에 각각의 상용막의 내알칼리성을 확인하기 위한 내구성 테스트를 진행하여 비교하였다. 최종적 으로 막-전극 접합체를 제조하여 수전해 single cell test를 진행하여 60°C, 70°C, 80°C의 온도 조건에서 cell 성능을 확인하였 고 장기 cell test로 다른 온도에서 20 cycle 측정하여 수전해 성능을 비교하여 상용막의 음이온 교환막 수전해에 적용가능성 을 비교하여 확인하였다.