Investigation of the Effect of Four-Phonon Scattering on Thermal Transport in Two-Dimensional Group-IV Materials

Four-phonon processes play an essential role in the thermal transport characteristics of materials. The incorporation of four-phonon scattering processes can help to accurately predict the thermal conductivity and tune thermal transport by phonon engineering. This work evaluates the four-phonon scattering mechanisms of two-dimensional (2D) group-IV materials including graphene, silicene, germanene, and stanene using first-principles and the Boltzmann transport equation. It can be proved that after considering the four-phonon scattering, the lattice thermal conductivities of the four materials decrease by 74, 35, 33, and 52% at 300 K, respectively. By analyzing the four-phonon behaviors, we attribute the obvious impact of the four-phonon scattering on lattice thermal conductivity to the following aspects: (1) the larger acoustic-optical energy gap has less effect on the four-phonon scattering process than that on the three-phonon scattering process; (2) in the range of bunched acoustic modes, the four-phonon scattering process is more likely to satisfy the energy conservation law; (3) the reflection symmetry selection rule is less restrictive for the four-phonon scattering process of the ZA phonon mode and improves the scattering rate of ZA phonon modes. In addition, we analyze the recombination process, redistribution process, and splitting process of four-phonon scattering and find that the redistribution process dominates the four-phonon scattering process. This work reveals the effect of four-phonon scattering on the thermal transport in 2D group-IV materials, which may provide fundamental knowledge to engineer phonon thermal transport.