First-principles calculation of the lattice thermal conductivities of α-, β-, and γ-Si3N4

Abstract

Lattice thermal conductivities (LTCs) of α-, β-, and γ-Si3N4 single crystals are investigated from ab initio anharmonic lattice dynamics, within the single-mode relaxation-time approximation of the linearized phonon Boltzmann transport equation. At a temperature of 300 K, a xx of 70 and a zz of 98 (in units of Wm-1K-1) are obtained for α-Si3N4. For β-Si3N4, xx and zz are found to be 71 and 194, respectively, which are consistent with the reported experimental values of 69 and 180 for individual β-Si3N4 grains in a ceramic. The theoretical xx values of α- and β-Si3N4 are comparable, while the zz value of β-Si3N4 is almost twice that of α-Si3N4, which demonstrates the very large anisotropy in the LTC of the β phase. It is found that the large anisotropy in the LTC of β-Si3N4 was caused by the elongated Brillouin zone along the c* axis, where the acoustic phonons mostly contribute to LTC and have large group velocities even near the Brillouin zone boundary. The LTC of γ-Si3N4 is 81, which is as small as that of α-Si3N4, although γ-Si3N4 has much larger elastic constants. This means that elastic constants are not always a good indicator of LTC. We show that knowing the detailed distributions of both the group velocities and phonon lifetimes in the Brillouin zones is important for characterizing the LTC of the three phases.