A study of electromigration in 3D flip chip solder joint using numerical simulation of heat flux and current density

2001 Proceedings. 51st Electronic Components and Technology Conference (Cat. No.01CH37220) Pub Date : 2001-05-29 DOI:10.1109/ECTC.2001.927783

T. Lee, Taek-Yeong Lee, K. Tu

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引用次数: 9

Abstract

This paper applies an analogy between heat flow and current flow to examine the current density distribution in a solder interconnect, which has a direct relationship with the atomic flux movement. From a 3D heat conduction analysis, we discover that the heat flux distribution in the solder bump is a strong function of the direction of heat flow. If the heat flow turns 90 degrees when it leaves the solder bump, the high heat flux region will also turn 90 degrees. From a cross-sectional view of the mean heat flux, the high heat flux (or current flux) region in the solder moves from the top of the UBM region to the lower right corner, and the right side of the solder has the highest flux density. This result correlates well with the experimental data where the measured atomic flux in the left side of the solder is less than in the right side. Two other cases with 0 and 180-degree heat flows also illustrate the difference in heat flux distribution. This suggests that the current density distribution in the solder changes as the direction of the current flow changes.

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基于热流密度和电流密度数值模拟的三维倒装焊点电迁移研究

本文采用热流和电流流的类比方法研究了焊料互连中与原子通量运动有直接关系的电流密度分布。通过三维热传导分析，我们发现凸点内的热流密度分布与热流方向有很大关系。如果热流在离开焊料凸点时转90度，则高热流区域也将转90度。从平均热通量的横截面来看，焊料中的高热通量(或电流通量)区域从UBM区域的顶部移动到右下角，并且焊料的右侧具有最高的通量密度。这一结果与在焊料左侧测得的原子通量小于右侧的实验数据相吻合。另外两种0度和180度热流的情况也说明了热流分布的差异。这表明焊料中的电流密度分布随着电流流动方向的变化而变化。

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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来源期刊

2001 Proceedings. 51st Electronic Components and Technology Conference (Cat. No.01CH37220)

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