Composition Control of Pd-Cu-Si Metallic Glassy Alloys for Thin Film Hydrogen Sensor

Abstract

Pd-Cu-Si metallic glassy alloys were investigated as materials for a hydrogen sensor. We prepared thin films of Pd-Cu-Si metallic glassy alloys with varying compositions by RF magnetron sputtering method. And effects of their composition on thermal properties (T_g: glass transition temperature, T_x: crystallization temperature) and H₂ response were examined. The H₂ response was examined by measuring changes of electric resistance of the thin films exposed in N₂ and H₂. Thermal stability depending on thermal properties and large response to hydrogen are key requirements of the hydrogen sensor.
T_g and T_x and H₂ response were significantly affected by Si content. T_g and T_x became higher and H₂ response decreased when Si content was increased. As for metals, Pd and Cu, T_g increased and H₂ response decreased with decreasing Pd/Cu atomic ratio among the samples having almost the same Si contents. These results can be explained by a trigonal prism cluster that is reported as a structural unit of Pd-based amorphous alloy. We discussed the effects of a trigonal prism cluster on thermal properties and H₂ response, as well as the effects of Si content and Cu content on constructing trigonal prism clusters.