Measurement of the temperature dependent constitutive behavior of underfill encapsulants

Reliable, consistent, and comprehensive material property data are needed for microelectronic encapsulants for the purpose of mechanical design, reliability assessment, and process optimization of electronic packages. In our research efforts, the mechanical responses of several different capillary f...

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Bibliographic Details
Main Authors: Islam, M.S., Suhling, J.C., Lall, P.
Format: Conference Proceeding
Language:English
Subjects:
Applied sciences
Design optimization
Design. Technologies. Operation analysis. Testing
Electronic packaging thermal management
Electronics
Exact sciences and technology
Integrated circuits
Material properties
Materials
Materials reliability
Materials testing
Microelectronics
Packaging machines
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Temperature dependence
Temperature measurement
Tensile strain
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Summary:Reliable, consistent, and comprehensive material property data are needed for microelectronic encapsulants for the purpose of mechanical design, reliability assessment, and process optimization of electronic packages. In our research efforts, the mechanical responses of several different capillary flow snap cure underfill encapsulants are being characterized. A microscale tension-torsion testing machine has been used to evaluate the uniaxial tensile stress-strain behavior of underfill materials as a function of temperature, strain rate, specimen dimensions, humidity, thermal cycling exposure, etc. A critical step to achieving accurate experimental results has been the development of a sample preparation procedure that produces mechanical test specimens that reflect the properties of true underfill encapsulant layers. In the developed method, 75-125 /spl mu/m (3-5 mil) thick underfill uniaxial tension specimens are dispensed and cured using production equipment and the same processing conditions as those used with actual flip chip assemblies. Although several underfills have been examined, this work features results for the mechanical response of a single typical capillary flow snap cure underfill. A three parameter hyperbolic tangent empirical model has been shown to provide accurate fits to the observed underfill nonlinear stress-strain behavior over a range of temperatures and strain rates.
DOI:10.1109/ITHERM.2004.1318272