Microstructure and Damage Evolution During Thermal Cycling of Sn-Ag-Cu Solders Containing Antimony-Reference-Cited by-同舟云学术

Microstructure and Damage Evolution During Thermal Cycling of Sn-Ag-Cu Solders Containing Antimony

Published:2020-10-26 Issue:3 Volume:50 Page:825-841
ISSN:0361-5235
Container-title:Journal of Electronic Materials
language:en
Short-container-title:Journal of Elec Materi

Author:

Belyakov S. A.^ORCID,Coyle R. J.,Arfaei B.,Xian J. W.,Gourlay C. M.

Abstract

AbstractAntimony is attracting interest as an addition to Pb-free solders to improve thermal cycling performance in harsher conditions. Here, we investigate microstructure evolution and failure in harsh accelerated thermal cycling (ATC) of a Sn-3.8Ag-0.9Cu solder with 5.5 wt.% antimony as the major addition in two ball grid array (BGA) packages. SbSn particles are shown to precipitate on both Cu6Sn5 and as cuboids in β-Sn, with reproducible orientation relationships and a good lattice match. Similar to Sn-Ag-Cu solders, the microstructure and damage evolution were generally localised in the β-Sn near the component side where localised β-Sn misorientations and subgrains, accelerated SbSn and Ag3Sn particle coarsening, and β-Sn recrystallisation occurred. Cracks grew along the network of recrystallised grain boundaries to failure. The improved ATC performance is mostly attributed to SbSn solid-state precipitation within β-Sn dendrites, which supplements the Ag3Sn that formed in a eutectic reaction between β-Sn dendrites, providing populations of strengthening particles in both the dendritic and eutectic β-Sn.

Funder

Engineering and Physical Sciences Research Council

Publisher

Springer Science and Business Media LLC

Subject

Materials Chemistry,Electrical and Electronic Engineering,Condensed Matter Physics,Electronic, Optical and Magnetic Materials

Link

https://link.springer.com/content/pdf/10.1007/s11664-020-08507-x.pdf

Reference58 articles.

1. R.J. Coyle, K. Sweatman, and B. Arfaei, JOM 67, 2394 (2015).

2. R.J. Coyle, R. Parker, K. Howell, D. Hillman, J. Smetana, G. Thomas, S. Longgood, M. Osterman, E. Lundeen, P. Snugovsky, J. Silk, A. Kleyner, K. Sweatman, R. Padilla, T. Yoshikawa, J. Bath, M. Holtzer, H. Zhang, J. Noiray, F. Duondel, R. Aspandiar, and J. Wilcox, in SMTA International (Rosemont, IL, USA, 2016), pp. 188–196.

3. M. Celikin, M. Maalekian, and M. Pekguleryuz, J. Electron. Mater. 48, 5562 (2019).

4. S. Hamasha, F. Akkara, M. Abueed, M. Rababah, C. Zhao, S. Su, J. Suhling and J. Evans, in 2018 IEEE 68th Electronic Components and Technology Conference (ECTC) (2018), pp. 2032–2040.

5. C.J. Thwaites, Int. Mater. Rev. 29, 45 (1984).

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