In this study, copper oxide, manganese oxide and zeolite, clays containing catalysts were prepared to remove hydrogen sulfide emitted in odor of industry. In order to change the heat treatment temperature, a catalyst was prepared 100 degrees from 600 degrees to 1,000 degrees. GC-MS was used to confirm the hydrogen sulfide removal performance. Although the removal performance produced at 600 degrees was maintained by and large, the removal performance decreased as the temperature increased. In particular, the catalyst manufactured at 900 and 1000 degrees had low removal performance. To find out the cause of the decrease in removal performance, the analytical devices XRD, BET, XRF were used. In order to confirm the properties of the catalyst before and after adsorption, SEM-EDS and CS were used. As a result of analyzing the Cu-Mn catalyst, it was confirmed that the material was adsorbed on the surface. To confirm the adsorbent material, SEM-Mapping was employed. And it was verified that the sulfur was adsorbed. Measuring the SEM-EDS 3Point, it was confirmed to be about 25.09%. Another test method CS analyzer (Carbon/Sulfur Detector) was also deployed. As a result of the test, sulfur was confirmed to be about 27.2%. So comparing the two sets of data, it was verified that sulfur was adsorbed on the surface.

The major concern in the deep geological disposal of spent nuclear fuels include sulfide-induced corrosion and stress corrosion cracking of copper canisters. Sulfur diffusion into copper canisters may induce copper embrittlement by causing Cu2S particle formation along grain boundaries; these sulfide particles can act as crack initiation sites and eventually cause embrittlement. To prevent the formation of Cu2S along grain boundaries and sulfur-induced copper embrittlement, copper alloys are designed in this study. Alloying elements that can act as chemical anchors to suppress sulfur diffusion and the formation of Cu2S along grain boundaries are investigated based on the understanding of the microscopic mechanism of sulfur diffusion and Cu2S precipitation along grain boundaries. Copper alloy ingots are experimentally manufactured to validate the alloying elements. Microstructural analysis using scanning electron microscopy with energy dispersive spectroscopy demonstrates that Cu2S particles are not formed at grain boundaries but randomly distributed within grains in all the vacuum arc-melted Cu alloys (Cu-Si, Cu-Ag, and Cu-Zr). Further studies will be conducted to evaluate the mechanical and corrosion properties of the developed Cu alloys.