Study of Time-Dependent Dielectric Breakdown on Gate Oxide Capacitors at High Temperature

2007 14th International Symposium on the Physical and Failure Analysis of Integrated Circuits Pub Date : 2007-07-11 DOI:10.1109/IPFA.2007.4378103

R. Moonen, P. Vanmeerbeek, G. Lekens, W. De Ceuninck, P. Moens, J. Boutsen

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引用次数: 7

Abstract

Thin layers of silicon dioxide used as a dielectric for capacitors or as the gate oxide for a MOS semiconductor device are subject to a wear-out mechanism known as time- dependent dielectric breakdown (TDDB). This physical failure mechanism has always been of notable reliability matter in semiconductor industry because of the incessant tendency towards smaller devices. In this paper, the intrinsic oxide lifetime of 7.2 nm gate oxide capacitors (n-type) has been studied in, a wide electric field ranging from 8.3 to 13.2 MV/cm at high temperatures (up to 240degC). By means of a high resolution/high speed TDDB measurement technique, we performed TDDB tests with constant voltage stress (CVS) at different stress conditions of temperature and voltage. We particularly concentrated on the high temperature aspect of TDDB to answer the demands of new smart power technologies (Tjunc up to 225degC). It was found that the intrinsic oxide breakdown mechanism perfectly matches the anode hole injection (AHI) model (1/EOX model) at these high temperatures. In summary, this physical model is most convenient to extrapolate the intrinsic oxide lifetime from accelerated tests to normal at-use conditions.

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栅极氧化物电容器高温下随时间介电击穿的研究

作为电容器的电介质或MOS半导体器件的栅氧化物的二氧化硅薄层受到称为时间相关介电击穿(TDDB)的磨损机制的影响。由于器件不断趋向于小型化，这种物理失效机制一直是半导体工业中值得注意的可靠性问题。本文研究了7.2 nm栅极氧化物电容器(n型)在8.3 ~ 13.2 MV/cm宽电场下高温(高达240℃)的固有氧化寿命。采用高分辨率/高速TDDB测量技术，在不同的温度和电压应力条件下进行了恒压应力(CVS) TDDB测试。我们特别关注TDDB的高温方面，以满足新的智能电源技术(高达225摄氏度)的需求。结果表明，在上述高温条件下，内生性氧化物击穿机制与阳极空穴注入(AHI)模型(1/EOX模型)完全吻合。总之，该物理模型最便于从加速试验到正常使用条件推断固有氧化物寿命。

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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2007 14th International Symposium on the Physical and Failure Analysis of Integrated Circuits

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