p-GaN栅极e模GaN hemt的降解及失效机理

ECS Transactions Pub Date : 2023-09-29 DOI:10.1149/11202.0009ecst

Abhas Mehta, Hisashi Shichijo, Jungwoo Joh, Chang Suh, Moon Kim

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摘要

本文利用栅极应力和失效分析(FA)描述了增强模式(e模式)GaN高电子迁移率晶体管(hemt)中p-GaN栅极的因果退化过程。我们发现失效时间和初始栅极电流(G0)之间没有相关性。相反，在100°C时，温度对器件的栅极电流(I G)和失效时间的影响更大。恒电压应力下的栅极破坏是单级破坏。在恒流应力作用下，栅极呈现多级破坏。击穿开始时栅极电流增加，导致肖特基势垒泄漏，最后导致灾难性接触失效。栅极手指处的金属/p-GaN界面成为栅极堆叠中最薄弱的部分。金属/p-GaN界面和表面缺陷作为泄漏源作为渗透路径发展，并且在栅盖中观察到纳米裂纹。FA还显示由于电应力在金属/p-GaN帽处发生物理降解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Degradation and Failure Mechanism of p-GaN Gate E-Mode GaN HEMTs

This work describes the cause-effect-based degradation process of the p-GaN gate in Enhancement-mode (E-mode) GaN High Electron Mobility Transistors (HEMTs) using gate stressing and failure analysis (FA). We found no correlation between time-to-fail and initial gate current (I G0 ). Instead, a higher impact of temperature was found on the gate current of the device (I G ) and time-to-fail at 100 °C. Gate failure at constant voltage stress was a single-stage failure. Under constant current stress, the gate shows a multi-stage failure. The breakdown starts with increased gate current leading to Schottky barrier leakage and finally to catastrophic contact failure. The metal/p-GaN interface at the gate finger becomes the weakest part of the gate stack. Metal/p-GaN interface and surface defects develop as percolation paths acting as leakage sources, and nano-cracks have been observed in the gate cap. FA also shows physical degradation at the metal/p-GaN cap due to electrical stress.

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ECS Transactions

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