Micro/nanoscale thermal transport by phonons beyond the relaxation time approximation: Green's function with the full scattering matrix

The phonon Boltzmann transport equation (BTE) has been widely utilized to study thermal transport in materials within the relaxation time approximation (RTA). However, the RTA limits the study to materials for which this mean field scattering assumption is a valid approximation, preventing the study of a wider class of materials, including graphene and diamond. Here we develop a Green's function solution of the linearized BTE for an arbitrary distribution of heat sources in an unbounded medium, which includes the full scattering matrix, and provide an analytical expression for the temperature distribution. We provide a condition on the scattering matrix to satisfy energy conservation simply in terms of the phonon frequencies, group velocities, and mode specific heat. We provide numerical calculations for graphene for the particular geometry of a spatially sinusoidal heating profile to highlight the importance of using the full scattering matrix compared to the RTA.