Measurement of Mechanical Behavior of High Lead Lead-Tin Solder Joints Subjected to Thermal Cycling

Pao, Yi-Hsin; Badgley, S.; Govila, R. K.; Baumgartner, Linda S.; Allor, R. L.; Cooper, R.

doi:10.1115/1.2906410

Cited by 21 publications

(8 citation statements)

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“…The von Mises yield criterion and kinematic hardening rule were applied in the analysis. The steady creep behavior of the eutectic solder in the simulation was governed by NortonÕs equation [32,33]:…”

Section: Finite Element Analysismentioning

confidence: 99%

Impact of the number of chips on the reliability of the solder balls for wire-bonded stacked-chip ball grid array packages

Jen¹,

Wu²,

Fang³

2006

Microelectronics Reliability

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Section: Finite Element Analysismentioning

confidence: 99%

Impact of the number of chips on the reliability of the solder balls for wire-bonded stacked-chip ball grid array packages

Jen¹,

Wu²,

Fang³

2006

Microelectronics Reliability

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“…The fatigue life of a eutectic solder joint can be predicted using an empirical Coffin-Manson relationship [7], [8], [12]- [14] (1)…”

Section: Fatigue Life Prediction Modelmentioning

confidence: 99%

Parametric reliability analysis of no-underfill flip chip package

Chiang

Liu

Peng

2001

IEEE Trans. Comp. Packag. Technol.

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This research proposes a parametric analysis for a flip chip package with a constraint-layer structure. Previous research has shown that flip-chip type packages with organic substrates require underfill for achieving adequate reliability life. Although underfill encapsulant is needed to improve the reliability of flip chip solder joint interconnects, it will also increase the difficulty of reworkability, increase the packaging cost and decrease the manufacturing throughput. This research is based on the fact that if the thermal mismatch between the silicon die and the organic substrate could be minimized, then the reliability of the solder joint could be accordingly enhanced. This research proposes a structure using a ceramic-like material with CTE close to silicon, mounted on the backside of the substrate to constrain the thermal expansion of the organic substrate. The ceramic-like material could reduce the thermal mismatch between silicon die and substrate, thereby enhancing the reliability life of the solder joint. Furthermore, in order to achieve better reliability design of this flip chip package, a parametric analysis using finite element analysis is performed for package design. The design parameters of the flip chip package include die size, substrate size/material, and constraint-layer size/material, etc. The results show that this constraint-layer structure could make the solder joints of the package achieve the same range of reliability as the conventional underfill material. More importantly, the flip chip package without underfill material could easily solve the reworkbility problem, enhance the thermal dissipation capability and also improve the manufacturing throughput. he became Associate Professor of power mechanical engineering, National Tsing Hua University, Taiwan. He has published more than 70 conference/journal papers in the area of CAE and electronic packaging. He was responsible for more than ten electronic packaging projects that related to the solder reflow, package simulation/design, and reliability analysis of electronic devices. Currently, he hold three U.S. and five Taiwan Electronic Packaging Device patents, and he has five U.S. and 12 Taiwan Electronic Packaging/Optical Device patents pending.

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“…In this approach, not only the global mismatch loads but the local mismatch between the solder itself and the solder pads, together with any associated bending in the layers, are taken into account in simulating the deformation occurring within the solder joints during a thermal cycle. Using a constitutive equation of the form suggested by Equation 1, E tot = Ee + Ep + Ee (4) where the terms represent deformation rates corresponding to the terms defined in Equation 1. The creep rate is defined by Ec = A (sinhBcr)n exp(-Q/RT) (5) where A, B, and n are material constants;…”

Section: Model Development and Life Predictionmentioning

confidence: 99%

“…An illustration of the complexities confronting a fracture mechanics analysis is highlighted by the results of Pao et aI., who have compared the fatigue behavior of eutectic and high-lead solder joints. 4 Examples of the stress/ strain hysteresis behavior of joints of both solders under the same thermal cycle conditions (Figure 9) illustrate the marked differences in behavior. Pao et a1.…”

Section: Model Development and Life Predictionmentioning

confidence: 99%

Converting to lead-free solders: An automotive industry perspective

Winterbottom

1993

JOM

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The solder tests currently used in defining solder alloy properties are not sufficient for selecting interconnect materials for improved reliability and reduced cost in automotive electronic applications. A "preventive" design approach based upon more accurate models of failure mechanisms and life prediction than are currently available will be required in order to assess solder alloys and to determine whether lead-free solders will provide improved reliability and lower-cost manufacturing options when compared to the lead-based solders currently used.

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Measurement of Mechanical Behavior of High Lead Lead-Tin Solder Joints Subjected to Thermal Cycling

Cited by 21 publications

References 0 publications

Impact of the number of chips on the reliability of the solder balls for wire-bonded stacked-chip ball grid array packages

Impact of the number of chips on the reliability of the solder balls for wire-bonded stacked-chip ball grid array packages

Parametric reliability analysis of no-underfill flip chip package

Converting to lead-free solders: An automotive industry perspective

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