Observation of ballistic-diffusive thermal transport in GaN transistors using thermoreflectance thermal imaging
Zhi-Ke Liu, Yang Shen, Han-Ling Li, Bing-Yang Cao

TL;DR
This study investigates how phonon ballistic transport affects heat dissipation in GaN transistors, revealing that ballistic effects significantly raise hotspot temperatures and impact thermal predictions, especially at smaller heat source sizes.
Contribution
It combines thermoreflectance thermal imaging with hybrid phonon Monte Carlo-diffusion simulations to quantify ballistic phonon effects in GaN transistors, highlighting their importance in thermal management.
Findings
Ballistic phonon effects significantly increase hotspot temperature.
Fourier's law predictions become less accurate with smaller heat sources.
Experimental and simulation results are in good agreement.
Abstract
To develop effective thermal management strategies for GaN transistors, it is essential to accurately predict the device junction temperature. Since the width of the heat generation in the devices is comparable to phonon mean free paths of GaN, phonon ballistic transport exists and can significantly affect the heat transport process, which necessitates a thorough understanding of the influence of the phonon ballistic effects in GaN transistors. In this paper, the ballistic-diffusive phonon transport in GaN-on-SiC devices is examined by measuring the hotspot temperature using the thermoreflectance thermal imaging TTI combined with the hybrid phonon Monte Carlo-diffusion simulations. A series of Au heaters are fabricated on the top of the GaN layer to quantitatively mimic the different heat source distributions during device operation. The experimental and simulation results show a good…
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Taxonomy
TopicsThermal properties of materials · Heat Transfer and Optimization · Adhesion, Friction, and Surface Interactions
