Impact of Temperature-Dependent Rattling Phonons on Lattice Dynamics and Thermal Transport in Ag6Ge10P12

Abstract

Crystalline compounds exhibiting low-frequency rattling phonons constitute an important class of high-performance thermoelectrics owning to their intrinsically very low lattice thermal conductivity (l). Theoretical approach that is capable of revealing the physical origin and accurately predicting l is of particular interest, which, however, still remains an outstanding challenge. In this study, we perform a case study of lattice dynamics and thermal transport properties of Ag6Ge10P12, which has recently been identified as a high-performance thermoelectric phosphide due to low l, arising from rattling vibrations associated with Ag6 clusters. Analysis within a first-principles-based lattice-dynamics framework based on self-consistent phonon theory reveals a strong temperature dependence of rattling phonons due to high-order anharmonic interactions. Anharmonic hardening of the rattling optical modes has a strong effect on the lifetimes of heat-carrying acoustic phonons by decreasing the rate of three-phonon combination processes. This mechanism results in a significant increase in l and changes its temperature dependence to 1/T0.64.