Abstract
In this study, we investigated the phase transitions and thermoelectric properties of charge-compensated hakite (Zn(x)Cu(12-x)Sb(4)Se(13)) as a function of Zn content. Based on X-ray diffraction and a differential scanning calorimetric phase analysis, secondary phases (permingeatite and bytizite) transformed into hakite depending on the Zn content, while Zn(2)Cu(10)Sb(4)Se(13) existed solely as hakite. Nondegenerate semiconductor behavior was observed, exhibiting increasing electrical conductivity with a rising temperature. With an increase in Zn content, the presence of mixed phases of hakite and permingeatite led to enhanced electrical conductivity. However, Zn(2)Cu(10)Sb(4)Se(13) with a single hakite phase exhibited the lowest electrical conductivity. The Seebeck coefficient exhibited positive values, indicating that even after charge compensation (electron supply) by Zn, p-type semiconductor characteristics were maintained. With the occurrence of an intrinsic transition within the measured temperature range, the Seebeck coefficient decreased as the temperature increased; at a certain temperature, Zn(2)Cu(10)Sb(4)Se(13) exhibited the highest value. Thermal conductivity showed a low temperature dependence, obtaining low values below 0.65 Wm(-1)K(-1). A power factor of 0.22 mWm(-1)K(-2) and dimensionless figure of merit of 0.31 were achieved at 623 K for ZnCu(11)Sb(4)Se(13).