Evaluation of contact resistance for isotropic electrically conductive adhesives

Electrically conductive adhesives are discussed and studied with ever-increasing interest as an alternative to solder interconnection in microelectronics circuit packaging. A similar level of scrutiny that is used to evaluate contact resistance performance for interconnections made with solder and s...

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Bibliographic Details
Published inIEEE transactions on components, packaging, and manufacturing technology. Part B, Advanced packaging Vol. 18; no. 2; pp. 299 - 304
Main Authors Gaynes, M.A., Lewis, R.H., Saraf, R.F., Roldan, J.M.
Format Journal Article Conference Proceeding
LanguageEnglish
Published New York, NY IEEE 01.05.1995
Institute of Electrical and Electronics Engineers
Subjects
Applied sciences
Conducting materials
Conductive adhesives
Connectors
Contact resistance
Copper
Design. Technologies. Operation analysis. Testing
Electric resistance
Electrical resistance measurement
Electronics
Exact sciences and technology
Integrated circuit interconnections
Integrated circuits
Packaging
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Thermal stresses
Encapsulation
Thermal ageing
Thermal cycle
Temperature effect
Electronic circuit
Contact resistance
Experimental study
Surface mounted component
Electrical connection
Lifetime
Microelectronic fabrication
Humidity effect
Manufacturing process
Electrical conductor
Reliability
Adhesive
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Summary:Electrically conductive adhesives are discussed and studied with ever-increasing interest as an alternative to solder interconnection in microelectronics circuit packaging. A similar level of scrutiny that is used to evaluate contact resistance performance for interconnections made with solder and separable connectors is necessary for electrically conductive adhesives. Experience with solder interconnection and separable connectors shows low initial contact resistance of less than 10 m/spl Omega/ when bulk conductor material is minimized in the measurement scheme. Stability is typically determined to be less than a 5-10 m/spl Omega/ change as a function of stress. The main intent of this study is to characterize the electrical contact resistance performance of joints made with isotropic electrically conductive adhesives. A copper comb pattern test vehicle was designed and fabricated using 0.25-mm thick lead frame material. The plating finishes that were applied to the copper substrate included a palladium alloy, gold, tin, and nickel. Test samples were made with several electrically conductive adhesives. Samples consisted of two comb patterns bonded to each other making a gang of 40 lap joints. Variables from circuit packaging such as coefficient of thermal expansion mismatches are purposely avoided in this study. Contact resistance measurements were made initially and as a function of time during environmental tests. Stresses included thermal cycling, thermal aging, and temperature and humidity conditioning. The stability of electrical contact resistance is shown to be influenced by both plating metallurgy and the conductive adhesive itself. Contact resistance equivalent to solder is possible with some electrically conductive adhesives on appropriate metallurgical finishes. Mechanically, adhesive joints are less robust than solder joints, and therefore care must be taken to eliminate or minimize the effects of mechanical loading.< >
ISSN:1070-9894
1558-3686
DOI:10.1109/96.386265