Thermionic emission or tunneling? The universal transition electric field for ideal Schottky reverse leakage current in β-Ga2O3

Abstract

The reverse leakage current through a Schottky barrier transitions from a thermionic-emission dominated regime to a barrier-tunneling dominated regime as the surface electric field increases. In this study, we evaluate such transition electric field (E T) in β-Ga2O3 using a numerical reverse leakage model. E T is found to have very weak dependence on the doping concentration and barrier height, thus a near-universal temperature dependence suffices and is given by a simple empirical expression in Ga2O3. With the help of a field-plate design, we observed experimentally in Ga2O3 Schottky barrier diodes a near-ideal bulk reverse leakage characteristics, which matches well with our numerical model and confirms the presence of the transition region. Near the transition electric field, both thermionic emission and barrier tunneling should be considered. The study provides important guidance toward accurate design and modeling of ideal reverse leakage characteristics in β-Ga2O3 Schottky barrier diodes.