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arxiv: 2201.00516 · v3 · pith:DO55VUV6new · submitted 2022-01-03 · ❄️ cond-mat.mtrl-sci

Deep-potential enabled multiscale simulation of gallium nitride devices on boron arsenide cooling substrates

classification ❄️ cond-mat.mtrl-sci
keywords coolingmultiscalesubstratesthermalapplicationsarsenidebas-ganboron
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High-efficient heat dissipation plays critical role for high-power-density electronics. Experimental synthesis of ultrahigh thermal conductivity boron arsenide (BAs, 1300 W m-1K-1) cooling substrates into the wide-bandgap semiconductor of gallium nitride (GaN) devices has been realized. However, the lack of systematic analysis on the heat transfer across the BAs-GaN interface hampers the practical applications. In this study, by constructing the accurate and high-efficient machine learning interatomic potentials, we performed multiscale simulations of the BAs-GaN heterostructures. Ultrahigh interfacial thermal conductance (ITC) of 265 MW m-2K-1 is achieved, which lies in the well-matched lattice vibrations of BAs and GaN. Moreover, the competition between grain size and boundary resistance was revealed with size increasing from 1 nm to 100 {\mu}m. Such deep-potential equipped multiscale simulations not only promote the practical applications of BAs cooling substrates in electronics, but also offer new approach for designing advanced thermal management systems.

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