Vibrational and electron-phonon coupling properties of \b{eta}-Ga2O3 from first-principles calculations: Impact on the mobility and breakdown field
K. A. Mengle, E. Kioupakis

TL;DR
This study uses first-principles calculations to analyze the vibrational and electron-phonon interactions in {eta}-Ga2O3, revealing key insights into its thermal and electronic properties relevant for high-power electronics.
Contribution
It provides a comprehensive theoretical analysis of phonon properties and electron-phonon coupling in {eta}-Ga2O3, advancing understanding of its mobility and breakdown field.
Findings
Identified the polar-optical phonon mode limiting mobility.
Calculated phonon dispersion and heat capacity accurately.
Estimated the breakdown field based on electron-phonon interactions.
Abstract
The wide band gap semiconductor \b{eta}-Ga2O3 shows promise for applications in high-power and high-temperature electronics. The phonons of \b{eta}-Ga2O3 play a crucial role in determining its important material characteristics for these applications such as its thermal transport, carrier mobility, and breakdown voltage. In this work, we apply predictive calculations based on density functional theory and density functional perturbation theory to understand the vibrational properties, phonon-phonon interactions, and electron-phonon coupling of \b{eta}-Ga2O3. We calculate the directionally dependent phonon dispersion, including the effects of LO-TO splitting and isotope substitution, and quantify the frequencies of the infrared and Raman-active modes, the sound velocities, and the heat capacity of the material. Our calculated optical-mode Gr\"uneisen parameters reflect the anharmonicity…
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