Effect of preformed Cu-Sn IMC layer on electromigration reliability of solder capped Cu pillar bump interconnection on an organic substrate

2012 2nd IEEE CPMT Symposium Japan Pub Date : 2012-12-01 DOI:10.1109/ICSJ.2012.6523394

Y. Orii, K. Toriyama, S. Kohara, H. Noma, K. Okamoto, K. Uenishi

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引用次数: 4

Abstract

The electromigration behavior of 80μm pitch solder capped Cu pillar bump interconnection on an organic carrier is studied and discussed. In 2011, the EM tests were performed on 80μm pitch solder capped Cu pillar bump interconnections and the effects of Ni barrier layers on the Cu pillars and the pre-formed intermetallic compound (IMC) layers on the EM tests were studied. The EM test conditions of the test vehicles were 7-10 kA/cm2 at 125-170°C. The Cu pillar height was 45μm and the solder height was 25μm. The solder composition was Sn-2.5Ag. Aged condition for pre-formed IMCs was 2,000 hours at 150°C. It was shown that the formation of the pre-formed IMC layers and the insertion of Ni barrier layers are effective in reducing the Cu atom dissolution. In this report, it is studied that which of the IMC layers, Cu3Sn or Cu6Sn5, is more effective in preventing the Cu atom dissolution. The cross-sectional analyses of the joints after the 2,000 hours of the test with 7kA/cm2 at 170°C were performed for this purpose. The relationship between the thickness of Cu3Sn IMC layer and the Cu migration is also studied by performing the current stress tests on the joints with controlled Cu3Sn IMC thicknesses. The samples were thermally aged prior to the tests at a higher temperature (200°C) and in a shorter time (10-50 hours) than the previous experiments. The cross-sectional analyses of the Sn-2.5Ag joints without pre-aging consisting mostly of Cu6Sn5, showed a significant Cu dissolution while the Cu dissolution was not detected for the pre-aged joints with thick Cu3Sn layers. A large number of Kirkendall voids were also observed in the joints without pre-aging. The current stress tests on the controlled Cu3Sn joints showed that Cu3Sn layer thickness of more than 1.5μm is effective in reducing Cu dissolution in the joints.

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预成形Cu- sn IMC层对有机衬底上锡盖铜柱凸点互连电迁移可靠性的影响

研究并讨论了80μm间距焊料覆盖铜柱凹凸互连在有机载体上的电迁移行为。2011年，对80μm间距焊料覆盖的铜柱凹凸互连进行了电磁测试，研究了Ni势垒层对铜柱和预成形金属间化合物(IMC)层的影响。试验车辆的电磁测试条件为7-10 kA/cm2，温度为125-170℃。铜柱高度为45μm，焊料高度为25μm。焊料成分为Sn-2.5Ag。预成型IMCs在150℃下时效2000小时。结果表明，预先形成的IMC层的形成和Ni势垒层的插入可以有效地减少Cu原子的溶解。本文研究了Cu3Sn和Cu6Sn5两种IMC层中哪一种能更有效地防止Cu原子的溶解。为此，在170°C下以7kA/cm2进行2000小时的测试后，对接头进行了截面分析。通过对控制Cu3Sn IMC厚度的接头进行电流应力试验，研究了Cu3Sn IMC厚度与Cu迁移的关系。在测试之前，样品在比之前的实验更高的温度(200°C)和更短的时间(10-50小时)下进行热老化。对Cu6Sn5为主的未预时效Sn-2.5Ag接头进行截面分析，发现有明显的Cu溶出，而对Cu3Sn厚层预时效Sn-2.5Ag接头没有发现Cu溶出。未预时效的关节中也观察到大量的Kirkendall空洞。对Cu3Sn控制接头进行的电流应力试验表明，Cu3Sn层厚度大于1.5μm可有效减少Cu在接头中的溶解。

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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2012 2nd IEEE CPMT Symposium Japan

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