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Title
Multiscale modeling of mechanical shock behavior of environmentally-benign lead-free solders in electronic packaging
Description
With the increasing focus on developing environmentally benign electronic packages, lead-free solder alloys have received a great deal of attention. Mishandling of packages, during manufacture, assembly, or by the user may cause failure of solder joint. A fundamental understanding of the behavior of lead-free solders under mechanical shock conditions is lacking. Reliable experimental and numerical analysis of lead-free solder joints in the intermediate strain rate regime need to be investigated. This dissertation mainly focuses on exploring the mechanical shock behavior of lead-free tin-rich solder alloys via multiscale modeling and numerical simulations. First, the macroscopic stress/strain behaviors of three bulk lead-free tin-rich solders were tested over a range of strain rates from 0.001/s to 30/s. Finite element analysis was conducted to determine appropriate specimen geometry that could reach a homogeneous stress/strain field and a relatively high strain rate. A novel self-consistent true stress correction method is developed to compensate the inaccuracy caused by the triaxial stress state at the post-necking stage. Then the material property of micron-scale intermetallic was examined by micro-compression test. The accuracy of this measure is systematically validated by finite element analysis, and empirical adjustments are provided. Moreover, the interfacial property of the solder/intermetallic interface is investigated, and a continuum traction-separation law of this interface is developed from an atomistic-based cohesive element method. The macroscopic stress/strain relation and microstructural properties are combined together to form a multiscale material behavior via a stochastic approach for both solder and intermetallic. As a result, solder is modeled by porous plasticity with random voids, and intermetallic is characterized as brittle material with random vulnerable region. Thereafter, the porous plasticity fracture of the solders and the brittle fracture of the intermetallics are coupled together in one finite element model. Finally, this study yields a multiscale model to understand and predict the mechanical shock behavior of lead-free tin-rich solder joints. Different fracture patterns are observed for various strain rates and/or intermetallic thicknesses. The predictions have a good agreement with the theory and experiments.
Date Created
2011
Contributors
- Fei, Huiyang (Author)
- Jiang, Hanqing (Thesis advisor)
- Chawla, Nikhilesh (Thesis advisor)
- Tasooji, Amaneh (Committee member)
- Mobasher, Barzin (Committee member)
- Rajan, Subramaniam D. (Committee member)
- Arizona State University (Publisher)
Topical Subject
- Mechanical Engineering
- Materials Science
- Electrical Engineering
- Interfacial law
- Intermetallic
- Lead-free solder
- Shock (Mechanics)
- Microstructural fracture
- Random defects
- Shock (Mechanics)
- Solder and soldering--Environmental aspects.
- Solder and soldering
- Electronic packaging--Environmental aspects.
- Electronic packaging
- Microstructure--Materials.
- Microstructure
Resource Type
Extent
xviii, 162 p. : ill. (some col.)
Language
eng
Copyright Statement
In Copyright
Primary Member of
Peer-reviewed
No
Open Access
No
Handle
https://hdl.handle.net/2286/R.I.9321
Statement of Responsibility
Huiyang Fei
Description Source
Viewed on Feb. 1, 2012
Level of coding
full
Note
thesis
Partial requirement for: Ph.D., Arizona State University, 2011
bibliography
Includes bibliographical references (p. 129-143)
Field of study: Mechanical engineering
System Created
- 2011-08-12 04:53:50
System Modified
- 2021-08-30 01:52:00
- 3 years 2 months ago
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