A Study on the Impact of Channel Mobility on Switching Performance of Vertical GaN MOSFETs

This paper presents a comparison of switching performances between the in-situ oxide, gallium nitride (GaN) interlayer FET (OG-FET) and the conventional GaN metal–oxide–semiconductor FET (MOSFET), and explores the influence of the channel electron mobility on the device switching performance. GaN OG-FET is a novel structure with a pristine GaN layer grown between the gate oxide and the p-GaN enhancing the channel mobility up to 185 cm 2 / $\text {V}\cdot \text {s}$ , which is over $3{\times}$ larger than that of the typical reported value (50 cm 2 / $\text {V}\cdot \text {s}$ ) in GaN MOSFET. Owing to the high channel electron mobility, the GaN OG-FET showed a switching loss 30% lower than that of the conventional GaN trench MOSFET. Our results indicate that GaN OG-FET has the potential to attain greater efficiency, particularly at higher frequencies, showing a possible patch toward megahertz range conversions.