Ni doping and rational annealing boost thermoelectric performance of nanostructured double perovskite Pr1.8Sr0.2CoFeO6

Pr2CoFeO6-based double perovskite exhibits intrinsic low thermal conductivity and high Seebeck coefficient, but its low electrical conductivity induces unsatisfied thermoelectric performance. Here, we employ a synergistic strategy of rational annealing and Ni doping to achieve an improved ZT of-0.085 at 573 K in Pr1.8Sr0.2Co- Fe0.95Ni0.05O6, which is-425 % higher than that of pristine Pr2CoFeO6. The annealing process effectively re-duces pores in the as-sintered bulk material, leading to an enhanced electrical conductivity without damaging the Seebeck coefficient, and the Ni doping further effectively improves the hole carrier concentration and in turn enhances the electrical conductivity, leading to a peak power factor of-113 mu W m- 1 K-2 at 573 K. Besides, Ni doping induces localized crystal imperfections including point defects, dislocations, and lattice distortions, contributing to an ultra-low thermal conductivity of < 0.6 W m-1 K-1. As a result, the as-achieved Pr1.8Sr0.2CoFe0.95Ni0.05O6 has a ZT of-0.085 at 573 K, which is highly competitive to reported thermoelec-tric double perovskites, indicating its potential applications in high-performance thermoelectric devices.

Automated summary

This study presents an improved thermoelectric performance of Pr2CoFeO6 through a synergistic strategy of rational annealing and Ni doping. The annealing process reduces pores and enhances electrical conductivity, while Ni doping increases hole carrier concentration and improves electrical conductivity and power factor. Additionally, Ni doping introduces localized crystal defects, reducing thermal conductivity. The achieved Pr1.8Sr0.2CoFe0.95Ni0.05O6 exhibits a high ZT value at high temperatures, indicating its potential applications in high-performance thermoelectric devices.