Modeling the copper microstructure and elastic anisotropy and studying its impact on reliability in nanoscale interconnects

Adarsh Basavalingappa, Ming Y. Shen, James R. Lloyd
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引用次数: 10

Abstract

Copper is the primary metal used in integrated circuit manufacturing of today. Even though copper is face centered cubic it has significant mechanical anisotropy depending on the crystallographic orientations. Copper metal lines in integrated circuits are polycrystalline and typically have lognormal grain size distribution. The polycrystalline microstructure is known to impact the reliability and must be considered in modeling for better understanding of the failure mechanisms.

In this work, we used Voronoi tessellation to model the polycrystalline microstructure with lognormal grainsize distribution for the copper metal lines in test structures. Each of the grains is then assigned an orientation with distinct probabilistic texture and corresponding anisotropic elastic constants based on the assigned orientation. The test structure is then subjected to a thermal stress.

A significant variation in hydrostatic stresses at the grain boundaries is observed by subjecting the test structure to thermal stress due to the elastic anisotropy of copper. This introduces new weak points within the metal interconnects leading to failure.

Inclusion of microstructures and corresponding anisotropic properties for copper grains is crucial to conduct a realistic study of stress voiding, hillock formation, delamination, and electromigration phenomena, especially at smaller nodes where the anisotropic effects are significant.

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模拟铜的微观结构和弹性各向异性及其对纳米互连可靠性的影响
铜是当今集成电路制造中使用的主要金属。尽管铜是面心立方,但由于晶体取向的不同,其力学各向异性显著。集成电路中的铜金属线是多晶的,通常具有对数正态分布的晶粒尺寸。已知多晶微观结构会影响可靠性,为了更好地理解失效机制,在建模时必须考虑多晶微观结构。在这项工作中,我们使用Voronoi镶嵌来模拟测试结构中铜金属线的对数正态粒度分布的多晶微观结构。然后为每个晶粒分配具有不同概率纹理的取向和相应的各向异性弹性常数。然后测试结构承受热应力。由于铜的弹性各向异性,通过将测试结构置于热应力下,观察到晶界处静水应力的显著变化。这在金属互连中引入了导致故障的新弱点。铜晶粒的微观结构及其相应的各向异性对于进行应力释放、丘状形成、分层和电迁移现象的现实研究至关重要,特别是在各向异性效应显著的较小节点上。
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