Effect of microstructure and alloy doping on electromigration in Pb-free solder interconnect

2013 IEEE International Integrated Reliability Workshop Final Report Pub Date : 2013-10-01 DOI:10.1109/IIRW.2013.6804192

Minhua Lu

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引用次数: 4

Abstract

Pb-free solders are studied for electromigration (EM) reliability. Two major EM failure mechanisms are identified in Sn-based Pb-free solders, due to the differences in microstructures and Sn-grain orientation. Rapid depletion of intermetallic-compounds and Under-Bump-Metallurgy are caused by fast diffusion of Cu and Ni along the c-axis of Sn crystals. When c-axis of Sn-grain is not aligned with the current direction, electromigration damage is dominated by Sn self-diffusion, which takes longer to occur. In general, the EM damage in SnCu solder is driven by the fast interstitial diffusion of Ni and Cu away from solder/UBM interface resulting in early fails; while the damage in SnAg solders is mostly dominated by Sn-self diffusion resulting in longer lifetime. The effective activation energy is 0.95 eV for SnAg solder and 0.54 eV for SnCu solder. The power exponent is 2 for SnAg and 1.2 for SnCu. Blech effect is observed only in the solders with Sn-self diffusion dominated failures, not in fast diffusion dominated failures. Therefore, optimizing and control solder microstructure is important to the solder reliability.

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显微组织和合金掺杂对无铅焊料互连电迁移的影响

对无铅焊料的电迁移可靠性进行了研究。由于锡基无铅焊料的微观结构和锡晶粒取向的差异，确定了两种主要的电磁破坏机制。金属间化合物的快速耗损和欠碰撞冶金是由Cu和Ni沿Sn晶体c轴的快速扩散引起的。当锡晶粒c轴与电流方向不一致时，电迁移损伤以锡自扩散为主，且发生时间较长。一般来说，SnCu钎料中的电磁损伤是由Ni和Cu从钎料/UBM界面快速扩散导致的早期失效驱动的;而焊料的损伤主要以sn自扩散为主，寿命较长。SnAg钎料的有效活化能为0.95 eV, SnCu钎料的有效活化能为0.54 eV。SnAg的幂指数为2,SnCu的幂指数为1.2。只在sn自扩散为主失效的焊料中观察到漂白效应，而在快速扩散为主失效的焊料中没有。因此，优化和控制焊料微观结构对提高焊料的可靠性具有重要意义。

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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2013 IEEE International Integrated Reliability Workshop Final Report

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