First principles study of thermal conductivity of In2O3 in relation to Al2O3, Ga2O3, and KTaO3
Abstract
I use first principles calculations to investigate the thermal conductivity of β-In2O3 and compare the results with that of α-Al2O3, β-Ga2O3, and KTaO3. The calculated thermal conductivity of β-In2O3 agrees well with the experimental data obtain recently, which found that the low-temperature thermal conductivity in this material can reach values above 1000 W/mK. I find that the calculated thermal conductivity of β-Ga2O3 is larger than that of β-In2O3 at all temperatures, which implies that β-Ga2O3 should also exhibit high values of thermal conductivity at low temperatures. The thermal conductivity of KTaO3 calculated ignoring the temperature-dependent phonon softening of low-frequency modes give high-temperature values similar that of β-Ga2O3. However, the calculated thermal conductivity of KTaO3 does not increase as steeply as that of the binary compounds at low temperatures, which results in KTaO3 having the lowest low-temperature thermal conductivity despite having acoustic phonon velocities larger than that of β-Ga2O3 and β-In2O3. I attribute this to the fact that the acoustic phonon velocities at low frequencies in KTaO3 is less uniformly distributed because its acoustic phonon branches are more dispersive compared to the binary oxides, which causes enhanced momentum loss even during the normal phonon-phonon scattering processes. I also calculate thermal diffusivity using the theoretically obtained thermal conductivity and heat capacity and find that all four materials exhibit the expected T-1 behavior at high temperatures. Additionally, the calculated ratio of the average phonon scattering time to Planckian time is larger than the lower bound of 1 that has been observed empirically in numerous other materials.
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