Phase structure and thermoelectric properties of Cu1.8-xSbxS thermoelectric material

Cu1.8S-based materials have become potential thermoelectric materials due to their rich raw material reserves, low toxicity, and excellent electrical and thermal properties. In this study, a series of Cu1.8-xSbxS (x = 0, 0.005, 0.02, 0.03, 0.04) bulk materials is synthesized by using mechanical alloying combined with spark plasma sintering process. This preparation method can shorten the preparation cycle of materials, and effectively improve the research and development efficiency of thermoelectric (TE) materials due to its simple process. The effects of different Sb doping amounts on the structure, micromorphology, and thermoelectric transport properties of Cu1.8-xSbxS phase are investigated. The results show that when 0 <= x < 0.02, the bulk samples are single-phase Cu1.8S. With the further increase of Sb doping to 0.02 <= x <= 0.04, the second phase CuSbS2 is formed when Sb content exceeds the solid solubility limit of x = 0.02 in Cu1.8S, all Cu1.8-xSbxS bulk samples exhibit p-type conductivity characteristics. Benefitting from the synergistic phonon scattering effect by multiscale defects, such as point defects (Sb-Cu(center dot center dot), V-S(center dot center dot)), nanopores, secondary phases (CuSbS2), and dislocations, the thermal conductivity kappa declines significantly from 1.76 W.m(-1).K-1 (x = 0) to 0.99 W.m(-1).K-1 at 723 K for the Cu1.76Sb0.04S sample. Finally, the peak dimensionless TE figure of merit (ZT) value of 0.37 is achieved at 723 K for Cu1.77Sb0.03S resulting from a low thermal conductivity of 1.11 W.m(-1).K-1 combining an appropriate power factor of 563 mu W.m(-1).K-2, which is 12% higher than that (0.33) of pristine Cu1.8S. Although the Sb doped Cu1.8S-based samples have lower thermal conductivity k, the reduced power factor cannot be offset by reducing the thermal conductivity k, so the TE figure of merit (ZT) value is not significantly improved. Therefore, there is still much room for improving the performance of Sb doped Cu1.8S-based thermoelectric material, and its thermoelectric performance can be further optimized through nano-second phase recombination, energy band engineering, and introducing multi-scale defects, etc. Our results suggest that the introduction of Sb into thermoelectric materials is an effective and convenient strategy to improve ZT value by reducing thermal conductivity kappa.

Automated summary

Cu1.8S-based materials have become potential thermoelectric materials due to their rich raw material reserves, low toxicity, and excellent electrical and thermal properties. In this study, a series of Cu1.8-xSbxS bulk materials were synthesized and the effects of different Sb doping amounts on their properties were investigated. The results suggest that further optimization is needed to improve the thermoelectric performance of Sb-doped Cu1.8S-based materials.