A Reliability Study on the Effects of HTOL and High-Current Density Stress Testing on Commercial-Grade Vertical N-Type PD/GAN Schottky Diodes

Abstract

Traditional silicon-based power electronics have approached their performance limits for high-power electronic applications. The U.S. Navy is actively pursuing the implementation of wide bandgap (WBG)semiconductor materials to realize reliable devices for use in high-power, high-current, and high-voltage applications. Gallium nitride (GaN) is a promising candidate for these applications due to its inherent material properties, and recent efforts to produce high quality bulk GaN have begun to enable the production of commercial-grade devices. However, much is still unknown regarding the reliability of GaN devices, especially Schottky diodes, which are often affected by issues involving barrier height inhomogeneity (BHI). First, a stress testing system capable of taking in-situ current-voltage-temperature (I-V-T) measurements while applying electrical stress was constructed. Next, a sample of commercial-grade vertical n-type palladium/gallium nitride(Pd/GaN) Schottky diodes were subjected to a series of step current and constant current stress tests. Current densities above 1.3 kA/cm^2 were achieved. Finally, the effects of electrical stress on material properties were observed through comparison of pre-, post-, and in-situ I-V-T data. The in-situ I-V-T measurements enabled degradation to be observed as a function of stress time. Results show that significant degradation to the material properties of the Schottky diodes occurs within the first few hours of stress testing

Document Details

Document Type

Technical Report

Publication Date

Sep 01, 2021

Accession Number

AD1164237

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