Time and temperature dependence of early stage Stress-Induced-Voiding in Cu/low-k interconnects

2009 IEEE International Reliability Physics Symposium Pub Date : 2009-04-26 DOI:10.1109/IRPS.2009.5173297

K. Croes, C. Wilson, M. Lofrano, Y. Travaly, D. de Roest, Z. Tokei, G. Beyer

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引用次数: 5

Abstract

The time and temperature dependence of Stress-Induced-Voiding below and in copper VIA's with a diameter of 80nm integrated in a k=2.5 material was studied. The focus was on the early phase of the voiding process. To accelerate the degradation, test structures with big metal plates below and/or above the VIA were used. We found two degradation mechanisms in which one dominated below and the other dominated above a certain temperature. The first mechanism has an activation energy of 0.9eV and is the result of interface-diffusion driven by a stress-gradient. This mechanism was more pronounced below the VIA, but was significant in the VIA as well. The second mechanism has an activation energy of 1.2eV, which is argued to be driven by grain boundary diffusion due to a vacancy gradient in and above the VIA. To explain both mechanisms, an addition to the traditional stress-creep model is proposed and fits our data well. Additionally, it is discussed that VIA's connected to the center of big metal plates above and below the VIA are less susceptible to SIV compared to VIA's connected to line ends either below or on top of the VIA. We support our argumentation and analytical modeling with Finite Element Modeling.

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Cu/低k互连中早期应力诱导空化的时间和温度依赖性

研究了在k=2.5材料中集成直径为80nm的铜VIA下和内部应力诱导空化的时间和温度依赖性。重点是排尿过程的早期阶段。为了加速降解，在VIA下方和/或上方使用了带有大金属板的测试结构。我们发现了两种降解机制，一种在一定温度以下起主导作用，另一种在一定温度以上起主导作用。第一种机制的活化能为0.9eV，是应力梯度驱动界面扩散的结果。这种机制在VIA下更为明显，但在VIA中也很重要。第二种机制的活化能为1.2eV，这被认为是由晶界扩散引起的，这是由VIA内部和上方的空位梯度引起的。为了解释这两种机制，提出了传统应力-蠕变模型的补充，并很好地拟合了我们的数据。此外，还讨论了与连接到VIA下方或下方的线端相比，连接到VIA上方或下方的大金属板中心的VIA不易受到SIV的影响。我们用有限元模型来支持我们的论证和分析建模。

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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2009 IEEE International Reliability Physics Symposium

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