共晶焊料碰撞倒装芯片的发展

Twenty First IEEE/CPMT International Electronics Manufacturing Technology Symposium Proceedings 1997 IEMT Symposium Pub Date : 1997-10-13 DOI:10.1109/IEMT.1997.626938

T. Akashi, T. Chikai, T. Hamano, A. Yoshida, S. Honma, H. Aoki, M. Miyata, K. Ezawa, T. Makita, M. Miyaoka

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引用次数: 8

摘要

近年来，对更小、更薄、密度更高的封装技术提出了更高的要求。倒装芯片互连是满足这些需求的解决方案之一。我们已经开发了具有共晶焊点碰撞的裸晶片的焊点碰撞和晶圆分选工艺。给出了焊料碰撞和晶圆分选过程的重点和可靠性测试结果。结果表明，我们的裸片具有良好的可靠性，可以将碰撞工艺应用于量产产品。接下来，我们报告了晶圆分选工艺的一些实验结果，这是裸片量产的关键工艺。对于外围碰撞的裸芯片，我们选择了传统类型的探测卡，悬臂针卡。我们用四张针头不同的卡片做了一些实验，确定了最佳的针头形状。使用最佳卡片，我们研究了超速和凸起高度变形量之间的关系。我们证明，当从所有引脚接触操作75 /spl mu/m的超速驱动器时，变形可以控制在小于5 /spl mu/m。用刷子比用陶瓷板抛光能更好地清洁卡片。为了选择区域碰撞裸芯片的探测卡，我们用悬臂式、碰撞式和眼镜蛇式三种类型的探测卡进行了实验。结果表明，眼镜蛇类型最适合区域颠簸。

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Eutectic solder bumped flip chip development

Recently, smaller, thinner and higher density packaging technology is demanded. Flip chip interconnection is one of solution to these demands. We have developed solder bumping and wafer sorting processes for bare dice with eutectic solder bumps. The highlights of our solder bumping and wafer sorting process and the reliability test results are shown. The results proved that our bare chips have good reliability, allowing the bumping process to be applied to mass production product. Next we report some experimental results of the wafer sorting process, which is the key process for mass production of bare chips. For peripherally bumped bare chips, we chose a conventional type probing card, the cantilever needle card. We carried out some experiments with four cards which had different needle heads, and decided the best head shape. Using the best card, we investigated the relationship between the overdrive and the amount of bump height deformation. We demonstrated that the deformation can be controlled to smaller than 5 /spl mu/m when operating a 75 /spl mu/m overdrive from all pin contacts. The card can be cleaned better by brushing than by polishing with ceramic plates. To choose probing cards for area bumped bare chips, we did some experiments with three types of probing card: the cantilever type, the bumped type, and the cobra type. Results showed the cobra type is best suited to area bumps.

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Twenty First IEEE/CPMT International Electronics Manufacturing Technology Symposium Proceedings 1997 IEMT Symposium

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