High Thermoelectric Figure of Merit Achieved in Cu2S1-xTex Alloys Synthesized by Mechanical Alloying and Spark Plasma Sintering

Chalcogenides have been considered as promising thermoelectric materials because of their low cost, nontoxicity, and environmental benignity. In this work, we synthesized a series of Cu2S1-xTex (0 <= x <= 1) alloys by a facile, rapid method of mechanical alloying combined with spark plasma sintering process. The Cu2S1-xTex system provides an excellent vision of the competition between pure phase and phase transformation, entropy-driven solid solution, and enthalpy-driven phase separation. When the Te concentration increases, the Cu2S1-xTex system changed from the pure monoclinic Cu2S at x = 0 to monoclinic Cu2S1-xTex solid solution at 0.02 <= x <= 0.06 and then transforms to hexagonal Cu2S1-xTex solid solution at 0.08 <= x <= 0.1. The phase separation of hexagonal Cu2Te in the hexagonal Cu2S matrix occurs at 0.3 <= x <= 0.7 and finally forms the hexagonal Cu2Te at x = 1. Owing to the changed band structure and the coexisted Cu2S and Cu2Te phases, greatly enhanced power factor was achieved in all Cu2S1-xTex (0 < x < 1) alloys. Meanwhile, the point defect introduced by the substitution of Te/S atoms strengthened the phonon scattering, resulting in a lowered lattice thermal conductivity in most of these solid solutions. As a consequence, Cu2S0.94Te0.06 exhibits a maximum ZT value of 1.18 at 723 K, which is about 3.7 and 14.8 times as compared to the values of pristine Cu2S (0.32) and Cu2Te (0.08), respectively.