The diffusion of Ni into Al wire at the interface of ultrasonic wire bond during high temperature storage

2005 6th International Conference on Electronic Packaging Technology Pub Date : 2005-08-30 DOI:10.1109/ICEPT.2005.1564652

H. Ji, Mingyu Li, Au Tai Kung, Chunqing Wang, Dongqing Li

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引用次数: 5

Abstract

Ultrasonic wire bonding is one of the most important techniques for die interconnection in microelectronic packaging. It is widely used for power devices, microwave devices and photoelectron devices packaging. At room temperature, ultrasonic energy and plastic deformation energy, generated by metal wire plastic deformation under the wedge tool pressure, make the wire and metallization join together. The ultrasonic bonds, after bonding and aging, of Al+1%Si wire with 25/spl mu/m diameter bonded on the Au/Ni/Cu pad, are analyzed by scanning electronic microscopy (SEM) with energy dispersive x-ray spectrometer (EDX). The joints begin at the bond periphery where it is the location of the greatest plastic flow. It is found that the mechanism of ultrasonic bonding is, both the plastic flow of metal wire generated by wedge tool pressure which results in the diffusion of Ni into Al wire; and the effect of ultrasound is that, on the one hand, ultrasonic vibration enhances the metal wire ability of plastic flow and, on the other hand, it generates many defects inside the metal wire which are the fast diffusion channels. The diffusion type is likely the short-circuit diffusion, which is more prominent than the crystal diffusion when the temperature is low. After high temperature storage at 170 /spl deg/C for 10 days, there is evident diffusion of Ni into Al wire, but the microstructure is the same with the bonds after bonding, there is no evident change. Aged for 30 days, the bond interface forms a cloud-like structure, and the major composition is Al and Ni with weight percent of 78.82% and 15.55% respectively. However, the diffusion is not even and some parts of the bond interface are absence of Ni diffusion. When the aging time is 40 days, the cloud-like structure transforms into rectangular island-like structure and there are many cavities inside the bond wire, which are different from the Kirkendall voids because of the shape and dimension.

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高温储存过程中，超声波焊丝界面处Ni向Al丝中的扩散

超声线键合是微电子封装中最重要的芯片互连技术之一。广泛应用于功率器件、微波器件、光电子器件的封装。在室温下，金属丝在楔刀压力下塑性变形产生的超声波能和塑性变形能，使金属丝与金属化结合在一起。利用扫描电子显微镜(SEM)和能量色散x射线光谱仪(EDX)分析了直径为25/spl mu/m的Al+1%Si丝在Au/Ni/Cu焊盘上的键合和时效后的超声键合。节理从粘结外围开始，这是塑性流动最大的位置。结果表明:超声键合的机理是:楔刀压力使金属丝产生塑性流动，导致Ni向Al丝扩散;超声波的作用一方面是提高金属丝的塑性流动能力，另一方面是在金属丝内部产生许多缺陷，这些缺陷是快速扩散通道。扩散类型可能为短路扩散，在温度较低时比晶体扩散更为突出。在170 /spl℃下高温贮存10天后，Ni在Al丝中有明显的扩散，但微观组织与键合后的键合相同，无明显变化。时效30 d后，键合界面形成云状结构，主要成分为Al和Ni，质量分数分别为78.82%和15.55%。但扩散不均匀，部分键界面不存在Ni扩散。当时效时间为40 d时，云状结构转变为矩形岛状结构，焊丝内部存在许多空腔，其形状和尺寸与Kirkendall空腔不同。

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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2005 6th International Conference on Electronic Packaging Technology

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