Lattice Thermal Conductivity of MgSiO3 Perovskite from First Principles

We investigate lattice thermal conductivity kappa of MgSiO3 perovskite (pv) by ab initio lattice dynamics calculations combined with exact solution of linearized phonon Boltzmann equation. At room temperature, kappa of pristine MgSiO3 pv is found to be 10.7 W/(m.k) at 0 GPa. It increases linearly with pressure and reaches 59.2 W/(m.k) at 100 GPa. These values are close to multi-anvil press measurements whereas about twice as large as those from diamond anvil cell experiments. The increase of k with pressure is attributed to the squeeze of weighted phase-spaces phonons get emitted or absorbed. Moreover, we find k exhibits noticeable anisotropy, with kappa(zz) being the largest component and (kappa(max) - kappa(min))/(kappa) over bar being about 25%. Such extent of anisotropy is comparable to those of upper mantle minerals such as olivine and enstatite. By analyzing phonon mean free paths and lifetimes, we further show that the weak temperature dependence of kappa observed in experiments should not be caused by phonons reaching 'minimum' mean free paths. These results clarify the microscopic mechanism of thermal transport in MgSiO3 pv, and provide reference data for understanding heat conduction in the Earth's deep interior.