Dissimilar thermal transport properties in -Ga2O3 and β-Ga2O3 revealed by machine-learning homogeneous nonequilibrium molecular dynamics simulations
Abstract
The lattice thermal conductivity (LTC) of Ga2O3 is an important property due to the challenge in the thermal management of high-power devices. We develop machine-learned neuroevolution potentials for single-crystalline β-Ga2O3 and -Ga2O3, and apply them to perform homogeneous nonequilibrium molecular dynamics simulations to predict their LTCs. The LTC of β-Ga2O3 was determined to be 10.3 0.2 W/(m K), 19.9 0.2 W/(m K), and 12.6 0.2 W/(m K) along [100], [010], and [001], respectively, aligning with previous experimental measurements. For the first time, we predict the LTC of -Ga2O3 along [100], [010], and [001] to be 4.5 0.0 W/(m K), 3.9 0.0 W/(m K), and 4.0 0.1 W/(m K), respectively, showing a nearly isotropic thermal transport property. The reduced LTC of -Ga2O3 versus β-Ga2O3 stems from its restricted low-frequency phonons up to 5 THz. Furthermore, we find that the β phase exhibits a typical temperature dependence slightly stronger than T-1, whereas the phase shows a weaker temperature dependence, ranging from T-0.5 to T-0.7.
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