Thermo-mechanical Design of Resilient Contact Systems for Wafer Level Packaging

R. Dudek, H. Walter, R. Doering, B. Michel, T. Meyer, J. Zapf, H. Hedler
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引用次数: 15

Abstract

Wafer level packaging (WLP) technologies are cost effective packaging solutions which are used increasingly. Second level reliability, i.e. mainly the thermo-mechanical reliability during thermal cycling, is a major concern of WLP. To avoid excessive solder straining, solder balls have been replaced by resilient interconnects, which can adopt the main part of the thermal mismatch deformation. One solution combining an increased reliability on module level with advantages in processing and the capability of full wafer level test and burn-in is ELASTecreg (ELASTec hArr Elastic-bump on Silicon Technology), particularly developed for memory products. The new failure risks are mainly related to fatigue of the metallic redistribution layer (RDL). Parametric studies using finite element analyses (FEA) were performed to avoid excessive straining of the metal lines. A balance of metal straining and solder straining had to be achieved. Comparisons were made for different soft bump layouts and RDL patterns. Optimal solutions figured out by FEA were also investigated experimentally by thermal cycle tests. However, the thermo-mechanical characteristics like stress-strain behaviour and fatigue resistance of the metallic films are the most important parameters for reliability predictions. In particular, the elastic-plastic properties of thin metallic Cu and Ni films are shown to depend on features like film thickness, grain size and orientation, resulting in a thin film strength exceeding the bulk strength of the same metal by several hundred percent
晶圆级封装弹性接触系统的热机械设计
晶圆级封装(WLP)技术是一种成本效益高的封装解决方案,应用越来越广泛。二级可靠性,即热循环过程中的热机械可靠性,是WLP的主要关注点。为了避免焊料过度拉伸,焊料球被弹性互连所取代,它可以采用热失配变形的主要部分。ELASTecreg (ELASTec hArr Elastic-bump on Silicon Technology)是一种结合了模块级可靠性提高、处理优势和全晶圆级测试和老化能力的解决方案,特别为存储产品开发。新的失效风险主要与金属重分布层(RDL)的疲劳有关。采用有限元分析(FEA)进行参数化研究,以避免金属线过度拉伸。必须达到金属张力和焊料张力的平衡。比较了不同的软凹凸布局和RDL模式。并通过热循环试验对有限元分析得到的最优解进行了验证。然而,热机械特性,如金属薄膜的应力应变行为和抗疲劳性能是可靠性预测的最重要参数。特别是,薄金属Cu和Ni薄膜的弹塑性性能取决于薄膜厚度、晶粒尺寸和取向等特征,从而导致薄膜强度超过相同金属的体积强度数百倍
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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