Progress in state-of-the-art technologies of Ga2O3 devices

Gallium oxide (Ga2O3), an emerging ultra-wide-bandgap semiconductor, has the desirable properties of a large bandgap of 4.6-4.9 eV, an estimated critical breakdown field of 8 MV cm(-1), decent electron mobility of 250 cm(2) V s(-1) and high theoretical Baliga figures of merit (BFOMs) of around 3000. Bolstered by their capability of an economical growth technique for high-quality bulk substrate, beta-Ga2O3-based materials and devices have been highly sought after in recent years for power electronics and solar-blind ultraviolet photodetectors. This article reviews the most recent advances in beta-Ga2O3 power device technologies. It will begins with a summary of the field and underlying semiconductor properties of Ga2O3, followed by a review of the growth methods of high-quality beta-Ga2O3 bulk substrates and epitaxial thin films. Then, brief perspectives on the advanced technologies and measurements in terms of ohmic contact and interface state are provided. Furthermore, some state-of-the-art beta-Ga2O3 photoelectronic devices, power devices and radiofrequency devices with distinguished performance are fully described and discussed. Some solutions to alleviating challenging issues, including the difficulty in p-type doping, low thermal conductivity and low mobility, are also presented and explored.

Automated summary

Gallium oxide (Ga2O3) is an emerging ultra-wide-bandgap semiconductor with desirable properties, widely used in power electronics and solar-blind ultraviolet photodetectors. This article reviews the latest advances in beta-Ga2O3 power device technologies and discusses solutions to challenging issues in the field.