DocumentCode
1253802
Title
Fatigue crack propagation along polymer-metal interfaces in microelectronic packages
Author
Guzek, John ; Azimi, Hamid ; Suresh, Subra
Author_Institution
Intel Corp., Chandler, AZ, USA
Volume
20
Issue
4
fYear
1997
fDate
12/1/1997 12:00:00 AM
Firstpage
496
Lastpage
504
Abstract
In this study, a fracture mechanics-based technique was used for characterizing fatigue crack propagation (FCP) at polymer-metal interfaces. Sandwich double-cantilever beam (DCB) specimens were fabricated using nickel and copper-coated copper substrates bonded with a thin layer of silica-filled polymer encapsulant. Under cyclic loading, crack propagation was found to occur at the polymer-metal interface. The interfacial failure mode was verified by scanning electron microscopy (SEM) analysis of the fatigue fracture surfaces. The crack growth rate was found to have a power-law dependence on the strain energy release rate range, and exhibited a crack growth threshold, much like the fatigue crack growth threshold stress intensity factor range for monolithic bulk metals, polymers, and ceramics. Interfacial FCP data for three candidate encapsulants predicted cracking resistances that were well correlated with package-level reliability tests. By varying the surface roughness of the copper and nickel plating, it was shown that interfacial FCP resistance increased with increasing roughness. The observed increases in FCP resistance were attributed to a reduction in the effective driving force for fatigue fracture along the rougher interfaces, and could be accounted for by a crack-deflection model
Keywords
delamination; encapsulation; failure analysis; fatigue cracks; integrated circuit packaging; integrated circuit reliability; scanning electron microscopy; crack growth rate; crack-deflection model; cyclic loading; effective driving force; encapsulants; fatigue crack propagation; fracture mechanics-based technique; interfacial failure mode; microelectronic packages; package-level reliability tests; polymer-metal interfaces; power-law dependence; sandwich double-cantilever beam specimens; scanning electron microscopy; silica-filled polymer encapsulant; strain energy release rate range; surface roughness; Bonding; Capacitive sensors; Copper; Failure analysis; Fatigue; Nickel; Polymers; Scanning electron microscopy; Surface cracks; Surface resistance;
fLanguage
English
Journal_Title
Components, Packaging, and Manufacturing Technology, Part A, IEEE Transactions on
Publisher
ieee
ISSN
1070-9886
Type
jour
DOI
10.1109/95.650940
Filename
650940
Link To Document