Analysis of bump resistance and current distribution of ultra-fine-pitch microbumps

To keep up with the demand of continuous increase in device densities, the integration of three-dimensional integrated circuits (3D-IC) has become the most probable solution, and the utilization of ultra-fine-pitch microbump has emerged as an essential component of 3D-IC technology. In this study, a...

Full description

Saved in:
Bibliographic Details
Published in:Microelectronics and reliability 2013-01, Vol.53 (1), p.41-46
Main Authors: Chang, Y.W., Peng, H.Y., Yang, R.W., Chen, Chih, Chang, T.C., Zhan, C.J., Juang, J.Y., Huang, Annie T.
Format: Article
Language:English
Subjects:
Aluminum
Copper
Crowding
Finite element method
Mathematical models
Microorganisms
Solders
Thickening
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:To keep up with the demand of continuous increase in device densities, the integration of three-dimensional integrated circuits (3D-IC) has become the most probable solution, and the utilization of ultra-fine-pitch microbump has emerged as an essential component of 3D-IC technology. In this study, a Kelvin bump structure was fabricated and resistances measured at different angles on a 20.0μm microbump were investigated. The microbump resistance at 0°, 60°, 120°, and 180° are 74.7, 45.9, 14.6, and 13.7mΩ, respectively. These high resistances in microbumps may result in high interconnect resistance and cause resistance/capacitance (RC) delay, and thus lower the electrical performance of 3D-IC. A series of finite-element-model (FEM) was built to analyze the distribution of electric field in microbump. The FEM results have shown that the current is distributed uniformly in the thin solder joint, but current crowding still occurs in the Cu under-bump-metallization (UBM). The finding of the current crowding in the Cu UBM is the main cause of high resistances in the microbump. Thickening the Al trace, for example, from 0.4μm to 1.5μm, is a direct solution to reduce the unexpected high microbump resistance. A numerical model which treated solder joints as a resistance network was also performed in this study. For comparison, both FEM and the numerical model show the same trend and agree with the measurement results from Kelvin bump structure. The results all point to one thing: thickening the Al trace turn out to be the most effective approach to reduce high microbump resistance. When the Al trace thickness is increased from 0.8 to 3.0μm, the microbump resistance is decreased to half of the original value, resulted from the alleviation of current crowding in the Cu UBM.
ISSN:0026-2714
1872-941X
DOI:10.1016/j.microrel.2012.08.021