30nm宽Cu线电迁移过程中空穴成核和生长:不同界面对失效模式的影响

T. Kirimura, K. Croes, Y. Siew, K. Vanstreels, P. Czarnecki, Z. Ei-Mekki, M. H. van der Veen, D. Dictus, A. Yoon, A. Kolics, J. Bommcls, Z. Tokei
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引用次数: 2

摘要

研究了30 nm半间距铜线电迁移过程中空穴的成核和生长。扩散界面的变化是a)通过使用SiCN介电帽或cop金属帽,b)通过调整TaN/Ta阻挡金属的厚度。发展的局部感应电磁测试方法和原位电磁观测可以了解空洞的成核和生长阶段。对于SiCN帽,不受势垒厚度的影响,存在两种对晶粒结构敏感的空洞生长模式。相比之下,对于cop帽,观察到与晶粒结构无关的单模态,其中有核空洞被钉在测试线上。我们还发现Co扩散到屏障金属和Cu之间的界面,并抑制了Cu在该界面的扩散率。由于Co的存在抑制了帽层和势垒界面处的Cu扩散系数,因此在需要更薄的势垒金属的高级互连中,cop帽层有利于电迁移。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Void nucleation and growth during electromigration in 30 nm wide Cu lines: Impact of different interfaces on failure mode
We investigate void nucleation and growth during electromigration in 30 nm half pitch Cu lines. Diffusion interfaces are varied a) by using SiCN dielectric cap or a CoWP metal cap and b) by tuning the thickness of TaN/Ta barrier metal. The developed local sense EM test method and in-situ EM observations allow understanding void nucleation and growth stages. For the SiCN cap, independent of barrier thickness, there are two void growth modes sensitive to grain structure. In contrast, for the CoWP cap, a single mode independent of the grain structure is observed, where a nucleated void is pinned in the test line. We also show that Co diffuses into the interface between the barrier metal and Cu, and suppresses Cu diffusivity at that interface. As both Cu diffusivities at the cap and barrier interfaces are suppressed by the presence of Co, a CoWP cap is beneficial to electromigration for advanced interconnects where thinner barrier metals are required.
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