Ga2O3 is the only ultra-wide bandgap semiconductor with melt-growth substrate technology similar to that of Si, heterostructure device technology similar to that of the III-Nitride family, and high growth rate (GR) epitaxial technologies such as MOCVD and HVPE to support the development of ultra-high-breakdown voltage devices competitive with SiC technology. We report a Ga2O3 transistor device based on a high-GR MOCVD technology (Agnitron Technology’s Agilis 100 reactor). We have demonstrated for the first time a β-Ga2O3 MOSFET grown by high-GR MOCVD resulting in significantly improved epilayer quality. The high GR demonstrated via this method paves the road for demonstration of high breakdown voltage devices on a thick Ga2O3 buffer layer.
We determine the band alignment of ScxAl1-xN/GaN heterojunctions at ScN alloy fractions ranging from x = 0.04 to 0.20 using x-ray photoemission spectroscopy, and determine the band gap from spectroscopic ellipsometry. We find a transition from straddling to staggered gap as ScN alloy fraction increases, and show that the experimental results are consistent with first-principles calculations. This crossover from type-I to type-II band alignment shows a degree of freedom for engineering improved heterostructures in ScAlN/GaN-based electronic and optoelectronic devices.
Ga2O3 is the only ultra-wide bandgap semiconductor with melt-growth substrate technology similar to that of Si, heterostructure device technology similar to that of the III-Nitride family, and high growth rate (GR) epitaxial technologies such as MOCVD and HVPE to support the development of ultra-high-breakdown voltage devices competitive with SiC technology. We have demonstrated for the first time a β-Ga2O3 MOSFET grown by high-GR MOCVD (Agnitron Technology’s Agilis 100 reactor) with record high mobility of 170 cm2/Vs, despite increased carrier scattering rate in the doped channel, facilitated by a significant improvement in epilayer quality. The high GR demonstrated via this method paves the road for demonstration of high breakdown voltage devices on a thick Ga2O3 buffer layer. [1] M.J. Tadjer et al., J. Phys. D: Appl. Phys. 54 (2021) 034005.
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