NiGa2O4 interfacial layers in NiO/Ga2O3 heterojunction diodes at high temperature

Abstract

NiO/Ga2O3 heterojunction diodes have attracted attention for high-power applications, but their high-temperature performance and reliability remain underexplored. Here we report on the time evolution of the static electrical properties in the widely studied p-NiO/n-Ga2O3heterojunction diodes and the formation of NiGa2O4 interfacial layers when operated at 550C. Results of our thermal cycling experiment show an initial leakage current increase which stabilizes after sustained thermal load, due to reactions at the NiO-Ga2O3 interface. High-resolution TEM microstructure analysis of the devices after thermal cycling indicates that the NiO-Ga2O3 interface forms ternary compounds at high temperatures, and thermodynamic calculations suggest the formation of the spinel NiGa2O4 layer between NiO and Ga2O3. First-principles defect calculations find that NiGa2O4 shows low p-type intrinsic doping, and hence can also serve to limit electric field crowding at the interface. Vertical NiO/Ga2O3 diodes with intentionally grown 5 nm thin spinel-type NiGa2O4 interfacial layers show excellent device ON/OFF ratio of > 1010(3 V), VON of ~1.9 V, and breakdown voltage of ~ 1.2 kV for an initial unoptimized 300-micron diameter device. These p-n heterojunction diodes are promising for high-voltage, high-temperature applications.