A robust reliability methodology for accurately predicting Bias Temperature Instability induced circuit performance degradation in HKMG CMOS

2011 International Reliability Physics Symposium Pub Date : 2011-04-10 DOI:10.1109/IRPS.2011.5784559

D. Ioannou, K. Zhao, A. Bansal, B. Linder, R. Bolam, E. Cartier, J.J. Kim, R. Rao, G. La Rosa, G. Massey, M. Hauser, K. Das, J. Stathis, J. Aitken, D. Badami, S. Mittl

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引用次数: 14

Abstract

A robust reliability characterization / modeling approach for accurately predicting Bias Temperature Instability (BTI) induced circuit performance degradation in High-k Metal Gate (HKMG) CMOS is presented. A series of device level stress experiments employing both AC and DC stress/relax BTI measurements are undertaken to characterize FET's threshold voltage instability response to a dynamic (inverter type) operation. Results from the AC stress experiments demonstrate that VT instability is frequency independent, an observation that suggests that VT degradation under AC stress can be equivalently measured through the simpler DC stress/relax sequence. An AC BTI model is developed that accurately captures the critical BTI relaxation effect through the DC stress/relax predictions on duty cycle dependence. A Ring Oscillator (RO) circuit is used as a model verification vehicle. Excellent agreement is demonstrated between the frequency degradation measurements obtained with a newly developed Ultra-Fast On-The-Fly (OTF) measurement technique optimized for BTI and the AC BTI model based RO simulations.

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一种准确预测HKMG CMOS偏置温度不稳定性诱发电路性能退化的可靠方法

提出了一种可靠的可靠性表征/建模方法，用于准确预测高k金属栅极CMOS中偏置温度不稳定性(BTI)引起的电路性能下降。采用交流和直流应力/弛豫BTI测量进行了一系列器件级应力实验，以表征FET对动态(逆变器类型)操作的阈值电压不稳定性响应。交流应力实验的结果表明，VT的不稳定性与频率无关，这一观察结果表明，交流应力下VT的退化可以通过更简单的直流应力/弛豫序列等效地测量。建立了一个交流BTI模型，该模型通过对占空比依赖的直流应力/松弛预测准确地捕获了临界BTI松弛效应。采用环形振荡器(RO)电路作为模型验证载体。采用最新开发的针对BTI优化的超快速实时(OTF)测量技术获得的频率退化测量结果与基于AC BTI模型的RO仿真结果非常吻合。

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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2011 International Reliability Physics Symposium

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