Crystalline Structure-Dependent Mechanical and Thermoelectric Performance in Ag2Se1‐xSx System

Abstract

Self-powered wearable electronics require thermoelectric materials simultaneously with a high dimensionless figure of merit ( z T ) and good flexibility to convert the heat discharged by the human body into electricity. Ag 2 (S,Se)-based semiconducting materials can well satisfy these requirements, and thus, they are attracting great attention in thermoelectric society recently. Ag 2 (S,Se) crystalizes in an orthorhombic structure or monoclinic structure, depending on the detailed S/Se atomic ratio, but the relationship between its crystalline structure and mechanical/thermoelectric performance is still unclear to date. In this study, a series of A g 2 S e 1 ‐ x S x ( x = 0 , 0.1, 0.2, 0.3, 0.4, and 0.45) samples were prepared and their mechanical and thermoelectric performance dependence on the crystalline structure was systematically investigated. x = 0.3 in the A g 2 S e 1 ‐ x S x system was found to be the transition boundary between orthorhombic and monoclinic structures. Mechanical property measurement shows that the orthorhombic A g 2 S e 1 ‐ x S x samples are brittle while the monoclinic Ag 2 Se 1‐ x S x samples are ductile and flexible. In addition, the orthorhombic A g 2 S e 1 ‐ x S x samples show better electrical transport performance and higher z T than the monoclinic samples under a comparable carrier concentration, most likely due to their weaker electron-phonon interactions. This study sheds light on the further development of flexible inorganic TE materials.