Effect of electron-phonon interaction on lattice thermal conductivity of SiGe alloys

Author(s)

Xu, Qian; Zhou, Jiawei; Liu, Te-Huan; Chen, Gang

Abstract

While it is well-known that electron-phonon scattering often determines the electron mobility, its impact on lattice thermal conductivity is less clear. Dominant phonon scattering mechanisms that determine the lattice thermal conductivity have been attributed to phonon-phonon and phonon-defect interactions. However, recent studies in silicon have shown that strong electron-phonon interaction can also lead to significant phonon scatterings at high carrier concentrations. Here, we use first-principles simulations to study thermal transport in SiGe alloys and show that the effect of electron-phonon interaction on thermal transport is even more significant than that in Si because mass disorder scattering leaves long mean free path phonons behind, which are more strongly scattered by electrons. At the carrier concentration of 1 × 10[superscript 20]cm[superscript −3], the room temperature lattice thermal conductivity of the Si[subscript 0.9]Ge[subscript 0.1] alloy including electron-phonon interaction is only 40% of the value without this interaction. The results show that thermal transport in alloys at a high doping level can be significantly impacted by the free carriers, providing important insights into heat conduction mechanisms in thermoelectric materials which are mostly based on heavily doped alloys.

Date issued

2019-07

URI

https://hdl.handle.net/1721.1/130054

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Applied Physics Letters

Publisher

AIP Publishing

Citation

Xu, Qian et al. "Effect of electron-phonon interaction on lattice thermal conductivity of SiGe alloys." Applied Physics Letters 115, 2 (July 2019): 023903.

Version: Author's final manuscript

ISSN

0003-6951

1077-3118