Investigation of self-heating induced hot-carrier-injection stress behavior in high-voltage power devices

2013 IEEE International Reliability Physics Symposium (IRPS) Pub Date : 2013-04-14 DOI:10.1109/IRPS.2013.6532038

Y.-H. Huang, L. Leu, C. C. Liu, Y. Lee, J. Wang, A. Mehta, K. Wu, Hui-Ting Lu, P. Su, Jui-Ping Chiang, H. Chou, Y. Jong, H. Tuan

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引用次数: 9

Abstract

In this paper, we investigate hot carrier injection (HCI) stress induced self-heating behavior for high-voltage n-type Lateral-Diffused-MOSFET (NLDMOS) multi-finger devices. A NMOS device with more poly fingers, for the first time, is found to suffer more threshold voltage drift (ΔVt) but less linear current drift (ΔIdlin) under HCI stress at high gate and drain voltages. The experiment of monitoring device temperature is carried out and TCAD simulations are performed to investigate the physical mechanisms. The effect of poly gate finger numbers (PGFN) is attributed to higher lattice temperature with more PGFN, resulting in higher electrical field in the channel region and lower electrical field in the drift region. HCI behavior in ΔVt and ΔIdlin for different PGFN devices at various ambient temperatures are verified by TCAD simulation. In addition, the effect of PGFN on AC HCI stress and DC HCI Safe-Operation-Area (SOA) are studied. All the experimental findings can be well explained by the effect of self-heating during HCI stress mode.

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高压电力器件自热诱导热载流子注入应力行为研究

本文研究了高压n型横向扩散mosfet (NLDMOS)多指器件的热载流子注入(HCI)应力诱导自热行为。首次发现具有更多多指的NMOS器件在高栅极和漏极电压的HCI应力下遭受更多的阈值电压漂移(ΔVt)但更少的线性电流漂移(ΔIdlin)。进行了器件温度监测实验，并进行了TCAD仿真研究其物理机制。多栅极指数(PGFN)的影响是由于多栅极指数越多，晶格温度越高，通道区电场越大，漂移区电场越小。通过TCAD仿真验证了不同PGFN器件在不同环境温度下在ΔVt和ΔIdlin中的HCI行为。此外，还研究了PGFN对交流HCI应力和直流HCI安全操作区域(SOA)的影响。所有的实验结果都可以用HCI应力模式下的自热效应来解释。

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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2013 IEEE International Reliability Physics Symposium (IRPS)

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