Microstructural evolution and failure analysis of Sn–Bi57–Ag0.7 solder joints during thermal cycling

Although many studies have reported the behaviors of thermal cycling of Sn-based solder joints, the corresponding mechanism is difficult to describe universally due to the complexity of different cases. In the present study, microstructural evolution and failure of Sn–Bi57–Ag0.7 solder joints caused...

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Published in:Journal of materials science. Materials in electronics 2022-02, Vol.33 (4), p.1942-1952
Main Authors: Chen, Yinbo, Wang, Changchang, Gao, Yue, Gao, Zhaoqing, Liu, Zhi-Quan
Format: Article
Language:English
Subjects:
Bismuth
Characterization and Evaluation of Materials
Chemistry and Materials Science
Electron backscatter diffraction
Evolution
Failure analysis
Grains
Intermetallic compounds
Materials Science
Microstructure
Optical and Electronic Materials
Silver
Soldered joints
Solders
Thermal cycling
Thermal mismatch
Thermal stress
Tin
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cited_by cdi_FETCH-LOGICAL-c319t-64ce984149349ee1b8ec70810a64f1a07864912aa7bfbf9118c8aaee7d6ff48b3
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container_end_page 1952
container_issue 4
container_start_page 1942
container_title Journal of materials science. Materials in electronics
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creator Chen, Yinbo
Wang, Changchang
Gao, Yue
Gao, Zhaoqing
Liu, Zhi-Quan
description Although many studies have reported the behaviors of thermal cycling of Sn-based solder joints, the corresponding mechanism is difficult to describe universally due to the complexity of different cases. In the present study, microstructural evolution and failure of Sn–Bi57–Ag0.7 solder joints caused by thermal cycling between − 40 and 85 °C from 0 to 1000 cycles were systematically investigated. The results indicated that the Sn–Bi–Ag solder joint was composed of Sn-rich phase, Bi-rich phase, large numbers of Bi dispersed-particles, and Ag 3 Sn precipitate. With the extension of time during thermal cycling, the microstructure of Sn–Bi–Ag solder joint gradually coarsened and the IMC layer became thicker (from 0.82 to 2.38 μm). However, Sn–Bi–Ag solder joints failed after 3000 thermal cycles. Two different stages of failure were found and the mechanism, related to the increment of thermal mismatch stress, was illuminated. Furthermore, Electron Backscattered Diffraction was used to detailedly elucidate the grain characteristics of the failed Sn–Bi–Ag solder joints, and the effect of thermal stress on orientations of Sn and Bi grains was also revealed. Being different from the orientation change observed in traditional Sn–Bi eutectic solder joints in previous studies, the present results demonstrated that both Sn and Bi grains did not present any preferred orientations after thermal cycling. And the reason of this phenomenon might be attributed to the Ag 3 Sn, which could be regarded as second-phase particles. Our present work would provide theoretical guidance for the development of new Sn–Bi-X solders with high reliabilities.
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In the present study, microstructural evolution and failure of Sn–Bi57–Ag0.7 solder joints caused by thermal cycling between − 40 and 85 °C from 0 to 1000 cycles were systematically investigated. The results indicated that the Sn–Bi–Ag solder joint was composed of Sn-rich phase, Bi-rich phase, large numbers of Bi dispersed-particles, and Ag 3 Sn precipitate. With the extension of time during thermal cycling, the microstructure of Sn–Bi–Ag solder joint gradually coarsened and the IMC layer became thicker (from 0.82 to 2.38 μm). However, Sn–Bi–Ag solder joints failed after 3000 thermal cycles. Two different stages of failure were found and the mechanism, related to the increment of thermal mismatch stress, was illuminated. Furthermore, Electron Backscattered Diffraction was used to detailedly elucidate the grain characteristics of the failed Sn–Bi–Ag solder joints, and the effect of thermal stress on orientations of Sn and Bi grains was also revealed. Being different from the orientation change observed in traditional Sn–Bi eutectic solder joints in previous studies, the present results demonstrated that both Sn and Bi grains did not present any preferred orientations after thermal cycling. And the reason of this phenomenon might be attributed to the Ag 3 Sn, which could be regarded as second-phase particles. 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Two different stages of failure were found and the mechanism, related to the increment of thermal mismatch stress, was illuminated. Furthermore, Electron Backscattered Diffraction was used to detailedly elucidate the grain characteristics of the failed Sn–Bi–Ag solder joints, and the effect of thermal stress on orientations of Sn and Bi grains was also revealed. Being different from the orientation change observed in traditional Sn–Bi eutectic solder joints in previous studies, the present results demonstrated that both Sn and Bi grains did not present any preferred orientations after thermal cycling. And the reason of this phenomenon might be attributed to the Ag 3 Sn, which could be regarded as second-phase particles. 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Being different from the orientation change observed in traditional Sn–Bi eutectic solder joints in previous studies, the present results demonstrated that both Sn and Bi grains did not present any preferred orientations after thermal cycling. And the reason of this phenomenon might be attributed to the Ag 3 Sn, which could be regarded as second-phase particles. Our present work would provide theoretical guidance for the development of new Sn–Bi-X solders with high reliabilities.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s10854-021-07395-z</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0001-7097-8977</orcidid></addata></record>
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ispartof Journal of materials science. Materials in electronics, 2022-02, Vol.33 (4), p.1942-1952
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source Springer Nature
subjects Bismuth
Characterization and Evaluation of Materials
Chemistry and Materials Science
Electron backscatter diffraction
Evolution
Failure analysis
Grains
Intermetallic compounds
Materials Science
Microstructure
Optical and Electronic Materials
Silver
Soldered joints
Solders
Thermal cycling
Thermal mismatch
Thermal stress
Tin
title Microstructural evolution and failure analysis of Sn–Bi57–Ag0.7 solder joints during thermal cycling
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