Your search keyword '"D. R. Frear"' showing total 2 results

1. Microstructurally Based Finite Element Simulation on Solder Joint Behaviour*

Author

D. R. Frear, J.J. Stephens, S.N. Burchett, and Michael K. Neilsen

Subjects

State variable, Materials science, Viscoplasticity, Metallurgy, Alloy, engineering.material, Condensed Matter Physics, Microstructure, Creep, Soldering, engineering, General Materials Science, Electrical and Electronic Engineering, Composite material, Joint (geology), Eutectic system

Abstract

The most commonly used solder for electrical interconnects in electronic packages is the near eutectic 60Sn‐40Pb alloy. This alloy has a number of processing advantages(suitable melting point of 183°C and good wetting behaviour). However, under conditions of cyclic strain and temperature (thermomechanical fatigue) the microstructure of this alloy undergoes a heterogeneous coarsening and failure process that makes the prediction of solder joint lifetime complex. A finite element simulation methodology to predict solder joint mechanical behaviour, that includes microstructural evolution, has been developed. The mechanical constitutive behaviour was incorporated into the time‐dependent internal state variable viscoplastic model through experimental creep tests. The microstructural evolution is incorporated through a series of mathematical relations that describe mass flow in a temperature/strain environment. The model has been found to simulate observed thermomechanical fatigue behaviour in solder joints.

Published

1997

2. Research on the Mechanism of Thermal Fatigue in Near‐eutectic Pb‐Sn Solders

Author

T. S. E. Summers, D. R. Frear, D. Tribula, D. Grivas, and J. W. Morris

Subjects

Materials science, Brittleness, Soldering, Metallurgy, Intermetallic, Ultimate failure, General Materials Science, Electrical and Electronic Engineering, Deformation (engineering), Condensed Matter Physics, Microstructure, Joint (geology), Eutectic system

Abstract

This paper discusses the microstructures of solder joints and the mechanism of thermal fatigue, which is an important source of failure in electronic devices. The solder joints studied were near‐eutectic Pb‐Sn solder contacts on copper. The microstructure of the joints is described. While the fatigue life of near‐eutectic solder joints is strongly dependent on the operating conditions and on the microstructure of the joint, the metallurgical mechanisms of failure are surprisingly constant. When the cyclic load is in shear at temperatures above room temperature the shear strain is inhomogeneous, and induces a rapid coarsening of the eutectic microstructure that concentrates the deformation in well‐defined bands parallel to the joint interface. Fatigue cracks propagate along the Sn‐Sn grain boundaries and join across the Pb‐rich regions to cause ultimate failure. The failure occurs through the bulk solder unless the joint is so thin that the intermetallic layer at the interface is a significant fraction of the joint thickness, in which case failure may be accelerated by cracking through the intermetallic layer. The coarsening and subsequent failure are influenced more strongly by the number of thermal cycles than by the time of exposure to high temperature, at least for hold times up to one hour. Thermal fatigue in tension does not cause well‐defined coarsened bands, but often leads to rapid failure through cracking of the brittle intermetallic layer. Implications are drawn for the design of accelerated fatigue tests and the development of new solders with exceptional fatigue resistance.

Published

1989