Affiliation:
1. Department of Electronic Materials Engineering Kwangwoon University Seoul 01897 Republic of Korea
2. Department of Energy Engineering Dankook University Chungnam 31116 Republic of Korea
3. Department of Information Display Kyung Hee University Seoul 02447 Republic of Korea
4. Memory Business Division Samsung Electronics Gyeonggi‐do 18479 Republic of Korea
5. Department of Applied Chemistry Dong‐Eui University Busan 47227 Republic of Korea
6. Department of Chemical Engineering Kwangwoon University Seoul 01897 Republic of Korea
Abstract
With the increasing demand for modern high‐voltage electronic devices in electric vehicles and renewable‐energy systems, power semiconductor devices with high breakdown fields are becoming essential. β‐Gallium oxide (Ga2O3), which has a theoretical breakdown field of 8 MV cm−1, is being studied as a next‐generation power‐switch material. However, realizing a breakdown field close to this theoretical value remains challenging. In this study, an aerosol deposition‐manufactured Ga2O3 film boasting an extremely high breakdown field, achieved through thickness optimization, heat treatment, and a unique nozzle‐tilting method, is developed. This study explores the effect of oxygen vacancies on the dielectric constant, breakdown field, and microstructure of Ga2O3 films. Through these methods, Ga2O3 films with a denser (98.88%) and uniform surface, made less affected by oxygen vacancies through nozzle tilting and post‐annealing at 800 °C, are produced, resulting in appropriate dielectric constants (9.3 at 10 kHz), low leakage currents (5.8 × 10−11 A cm−2 at 20 kV cm−1), and a very high breakdown field of 5.5 MV cm−1. The results of this study suggest that aerosol‐deposited Ga2O3 layers have great potential to enable power switches with reliable switching.
Funder
Ministry of Science, ICT and Future Planning
National Research Foundation