A Comparison of Short-Circuit Failure Mechanisms of 1.2 kV 4H-SiC MOSFETs and JBSFETs

2022 IEEE 9th Workshop on Wide Bandgap Power Devices & Applications (WiPDA) Pub Date : 2022-11-07 DOI:10.1109/WiPDA56483.2022.9955302

Dongyoung Kim, Skylar DeBoer, S. Jang, Adam J. Morgan, Woongje Sung

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Abstract

This paper presents a comparison of 1.2 kV 4H-SiC MOSFETs and Ti JBSFETs with deep P-well structures. For a fair comparison of the short-circuit characteristics between the MOSFETs and JBSFETs, an innovative design approach for the JBSFETs was implemented to obtain the same specific on-resistance to the MOSFETs. To improve the short-circuit characteristics of the MOSFETs and JBSFETs, channeling implantation was conducted to form a deep P-well structure, that helps reduce the maximum saturation current during the shortcircuit event. Using this approach superior short-circuit characteristics are achieved in the MOSFETs and JBSFETs. However, the JBSFETs provide a shorter shortcircuit withstand time than the MOSFETs due to the high leakage current from Schottky contact. Sentaurus 2D TCAD was used to understand and clarify the short-circuit mechanisms of the MOSFETs and JBSFETs. It was discovered that the MOSFETs failed due to the high current in the channel region, but the failure of JBSFETs happens in the Schottky contact. Moreover, solutions to improve the short-circuit characteristics of the JBSFETs are proposed; a narrow Schottky width and high work function metal.

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1.2 kV 4H-SiC mosfet与jbsfet短路失效机理比较

本文对1.2 kV 4H-SiC mosfet和深p井结构的Ti jbsfet进行了比较。为了公平地比较mosfet和jbsfet之间的短路特性，采用了一种创新的jbsfet设计方法，以获得与mosfet相同的特定导通电阻。为了改善mosfet和jbsfet的短路特性，进行了沟道注入形成深p阱结构，有助于降低短路事件时的最大饱和电流。利用这种方法，可以在mosfet和jbsfet中实现优越的短路特性。然而，由于肖特基触点的高泄漏电流，jbsfet提供比mosfet更短的耐短路时间。使用Sentaurus 2D TCAD来了解和阐明mosfet和jbsfet的短路机制。发现mosfet的失效是由于沟道区域的大电流，而jbsfet的失效发生在肖特基触点。提出了改善jbsfet短路特性的解决方案;窄肖特基宽度和高功功能金属。

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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2022 IEEE 9th Workshop on Wide Bandgap Power Devices & Applications (WiPDA)

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