Energy relaxation due to two-phonon scattering of electrons: Breakdown of the energy diffusion model

Abstract

Recent THz spectroscopy of the quantum paraelectric SrTiO3 (arXiv:2501.15771) and a high-Tc cuprate (arXiv:2503.15646) has renewed interest in energy relaxation in correlated electron systems. We consider a situation in which single-phonon scattering is forbidden by symmetry or momentum conservation, while two-phonon scattering is allowed. Solving the Boltzmann equation, we show that above the Bloch-Gr\"uneisen temperature the energy relaxation rate from two soft transverse optical phonons exceeds the single-phonon one: while the latter scales as 1/T, the former is linear in T. This dominance of two-phonon scattering invalidates the usual picture of energy diffusion due to frequent scattering by subthermal phonons; instead, energy relaxes via rare scattering events involving thermal phonons. Below the Bloch-Gr\"uneisen temperature, the energy relaxation rate scales as the single-particle rate, namely as T3 for soft phonons. For anisotropic electron bands, an intermediate regime appears between two Bloch-Gr\"uneisen temperatures, in which both allowed single-phonon and two-phonon processes scale as T2.