Lifetime Prediction of SnPb and SnAgCu Solder Joints of Chips on Copper Substrate Based on Crack Propagation FE-Analysis

微纳电子与智能制造 Pub Date : 2006-04-24 DOI:10.1109/ESIME.2006.1643976

S. Deplanque, W. Nuchter, B. Wunderle, R. Schacht, B. Michel

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引用次数: 28

Abstract

It is necessary to improve the lifetime prediction based on FE-methods of different electronic packages in order to reduce the time and costs of new developments. This paper purposes a method describing the crack propagation of chip on copper substrate solder joints. The chips that were studied are power transistors. They were soldered on copper substrate (NiAu metallization) with two different solder alloys (SnPb eutectic and SAC 305). The chip dimensions and the solder joint thickness have an influence on the lifetime, so that two different chips with two different solder thicknesses were used as test specimens. These were thermally loaded, and the state of the solder joints was regularly checked. Three different kind of methods were used to characterize the damage of solder joints: the scanning acoustic microscope (SAM) detects the crack initiation and propagation; the cross section analysis can validate the results of the scanning acoustic microscope and can show the microstructure changes; and the thermal resistance which is influenced by the damage of the solder joint was measured and correlated to damage. After presenting the results of these investigations, a general FE-method predicting the crack initiation and propagation using the Paris laws is presented

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基于裂纹扩展有限元分析的铜基芯片SnPb和SnAgCu焊点寿命预测

为了减少新产品开发的时间和成本，有必要改进基于有限元方法的不同电子封装寿命预测。本文提出了一种描述铜衬底焊点上切屑裂纹扩展的方法。所研究的芯片是功率晶体管。用两种不同的钎料合金(SnPb共晶和SAC 305)将它们焊接在铜衬底(NiAu金属化)上。由于芯片尺寸和焊点厚度对寿命有影响，因此采用两种不同的芯片和两种不同的焊点厚度作为试样。这些都是热加载的，并定期检查焊点的状态。采用三种不同的方法来表征焊点的损伤:扫描声显微镜(SAM)检测裂纹的萌生和扩展;截面分析可以验证扫描声显微镜的结果，并能显示微观结构的变化;测量了受焊点损伤影响的热阻，并与损伤进行了关联。在介绍这些研究结果的基础上，提出了一种利用Paris定律预测裂纹萌生和扩展的通用有限元方法

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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微纳电子与智能制造

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145