Atomic drift-less electromigration model for submicron copper interconnects

YMER Digital Pub Date : 2022-07-28 DOI:10.37896/ymer21.07/94
A. Adhikari, A. Roy, C. Tan
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Abstract

Electromigration in chip level interconnect is commonly described by atomic drift due to electron-wind force that arises from electron-ion momentum transfer. As an alternative to this model, in early 1980’s, Sah proposed a two dimensional analytical ‘void-surface bond-breaking’ model by dropping the atomic drift term that resulted from electron-wind force (in his book ‘Fundamentals of Solid-State Electronics’) and the rate of change of area of void is computed. Due to the continuous down scaling and evolution of interconnect patterning technologies, the void growth process in modern interconnect becomes more complex and electromigration failures are found to be catastrophic in nature instead of gradual type failures observed in early days. In this work, Sah’s model is revisited from the perspective of its applicability to modern submicron copper interconnects. The electromigration-induced resistance change behavior is analytically derived considering a three-dimensional atomic drift-less model. A good correlation between the findings of our model with experimental observations is presented. Keywords: Analytical model, Copper, Drift-less, Electromigration, Resistance change, Time to failure
亚微米铜互连的原子无漂移电迁移模型
芯片级互连中的电迁移通常用由电子-离子动量转移引起的电子风力引起的原子漂移来描述。作为该模型的替代方案,在20世纪80年代初,Sah提出了一个二维解析的“空洞表面断键”模型,通过放弃由电子-风力引起的原子漂移项(在他的书《固态电子学基础》中),并计算了空洞面积的变化率。由于互连技术的不断缩小和发展,现代互连中的空洞生长过程变得更加复杂,电迁移失效的性质是灾难性的,而不是早期观察到的渐进式失效。在这项工作中,Sah的模型从其对现代亚微米铜互连的适用性的角度进行了重新审视。考虑三维原子无漂移模型,对电迁移引起的电阻变化行为进行了解析推导。我们的模型的发现与实验观察之间有很好的相关性。关键词:解析模型,铜,无漂移,电迁移,电阻变化,失效时间
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