Potential thermoelectric materials CsMI3 (M=Sn and Pb) in perovskite structures from the first-principles calculations

Abstract

The thermoelectric properties of halide perovskites CsMI3 (M=Sn and Pb) are investigated from a combination of first-principles calculations and semiclassical Boltzmann transport theory by considering both the electron and phonon transport. The electronic part is performed using a modified Becke and Johnson (mBJ) exchange potential, including spin-orbit coupling (SOC), while the phonon part is computed using generalized gradient approximation (GGA). It is found that SOC has remarkable detrimental effect on n-type power factor, while has a negligible influence in p-type doping, which can be explained by considering SOC effect on conduction and valence bands. Calculated results show exceptionally low lattice thermal conductivities in CsSnI3 and CsPbI3, and the corresponding room-temperature lattice thermal conductivity is 0.54 W m-1 K-1 and 0.25 W m-1 K-1. At 1000 K, the maximal figure of merit ZT is up to 0.63 and 0.64 for CsSnI3 and CsPbI3 with scattering time τ=10-14 s, and the peak ZT is 0.49 and 0.41 with τ=10-15 s. These results make us believe that CsMI3 (M=Sn and Pb) in perovskite structures may be potential thermoelectric materials.