直接贴片封装的下流工艺

Proceedings. The First IEEE International Symposium on Polymeric Electronics Packaging, PEP '97 (Cat. No.97TH8268) Pub Date : 1997-10-26 DOI:10.1109/PEP.1997.656500

E. Cotts, T. Driscoll, N. Guydosh, G. Lehmann, P. Li

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引用次数: 39

摘要

在倒装芯片封装中，使用毛细管流动过程将下填充混合物放置在由焊料凸起阵列产生的芯片与衬底之间的距离中。下填料混合物被密集地填充固体二氧化硅颗粒，以达到期望的有效热膨胀系数。因此，在流动过程中，下填体混合物是液体载体中固体颗粒的密集悬浮物。流动特性是混合特性、润湿特性和流动几何形状的复杂函数。确定正确的指标来表征流动行为是我们正在进行的DARPA资助的下填土流动过程调查的主要目标。本文报道了利用平面通道毛细管流动来表征下填土材料。我们定义并探索了一个称为流量参数的度量，其尺度为/spl sigma/cos(/spl theta/)//spl mu//sub app/。实测流动特性表明，在流动条件变化的影响下，接触角(/spl theta/)和悬浮液粘度(/spl mu//sub app/)随时间变化。流量参数在检测这两种现象时都很有用。接触角的变化与润湿动力学的文献一致，其中/spl θ /被观察到是接触线速度的函数。模型悬浮液和商业底填材料的非线性流体行为都是明显的。

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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Underflow process for direct-chip-attachment packaging

In flip-chip packaging, an underfill mixture is placed into the chip-to-substrate stand-off created by the array of solder bumps, using a capillary flow process. The underfill mixture is densely filled with solid silica particles to achieve the desired effective coefficient of thermal expansion. Thus, during the flow process, the underfill mixture is a dense suspension of solid particles in a liquid carrier. The flow behaviour is a complex function of the mixture properties, the wetting properties, and the flow geometry. The determination of the correct metrics to characterize the flow behaviour is a major goal of our ongoing DARPA funded investigation of the underfill flow process. This paper reports on the use of a plane channel capillary flow to characterize underfill materials. We define and explore a metric termed the flow parameter which scales as /spl sigma/cos(/spl theta/)//spl mu//sub app/. The measured flow behaviour provides evidence that both the contact angle (/spl theta/) and the suspension viscosity (/spl mu//sub app/) vary with time under the influence of changing flow conditions. The flow parameter is useful in detecting both of these phenomena. The contact angle variation is consistent with the literature on wetting dynamics, where /spl theta/ is observed to be a function of the contact line speed. Nonlinear fluid behaviour is evident for both model suspensions and commercial underfill materials.

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来源期刊

Proceedings. The First IEEE International Symposium on Polymeric Electronics Packaging, PEP '97 (Cat. No.97TH8268)

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