Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests

Drop ball reliability for Ball Grid Array (BGA) package on lead-free product is a major reliability concern. Integrating a polymer core in the solder ball could be a good strategy to dissipate stress better compared to the purely metallic solder ball. However, the diffusion rate of the copper is muc...

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Main Authors: Kar Y.B., Hui T.C., Agileswari R., Lo C.
Other Authors: 26649255900
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Published: 2023
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spelling my.uniten.dspace-294582023-12-28T12:13:12Z Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests Kar Y.B. Hui T.C. Agileswari R. Lo C. 26649255900 55340767200 16023154400 55340865500 Copper Diffusion Drops Electronics packaging Intermetallics Nickel Polymers Reliability Testing Analytical software Ball grid array packages Comparison study Cu diffusion Diffusion rate Drop test Drop test reliability Drop-balls High temperature stress IMC thickness Kirkendall void Lead-free products Reliability performance Reliability test Solder ball shear Solder balls Solder joints Stress test Work study Soldering Drop ball reliability for Ball Grid Array (BGA) package on lead-free product is a major reliability concern. Integrating a polymer core in the solder ball could be a good strategy to dissipate stress better compared to the purely metallic solder ball. However, the diffusion rate of the copper is much faster than the diffusion rate of the solder. Hence, Kirkendall voids starts forming and causing crack between the interface of copper and solder. This could affect the solder joint as well as the solder ball drop reliability especially when subjected to high temperature stress. The new polymer core solder ball with 1 ?m thickness of nickel (Ni) coated on the copper (polymer core/copper/nickel/solder) could offer better solder ball joint and drop reliability performance. This work studies the effects of IMC growth, solder ball shear strength and drop test reliability. Subsequently, the failure modes were observed after multiple reflow (up to 5 times) and HTS stress tests. The IMC formation was observed under the high power scope with magnification 50� via the mechanical cross-section and was measured using an analytical software tool. Solder ball shear test was carried out to measure the solder joint performance after multiple reflow and HTS stress tests via the Dage 4000 series bond tester. Drop reliability test was carried out via the packing drop test. From this study, we could conclude that the polymer core solder ball with an additional Ni layer coating demonstrates better performance than the polymer core solder ball without Ni layer. The same observation applies to the solder ball shear strength, drop reliability performance in multiple reflow and HTS stress tests. The IMC thickness for polymer core solder ball without additional Ni layer is much thicker than the polymer core solder ball with an additional Ni layer, most probably because Ni could limit the Cu diffusion into the solder, thus resulting in better reliability performance. � 2012 Elsevier Ltd. All rights reserved. Final 2023-12-28T04:13:12Z 2023-12-28T04:13:12Z 2013 Article 10.1016/j.microrel.2012.07.032 2-s2.0-84872112183 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84872112183&doi=10.1016%2fj.microrel.2012.07.032&partnerID=40&md5=011d3caa4f307be0f3725d0122a6526c https://irepository.uniten.edu.my/handle/123456789/29458 53 1 164 173 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Copper
Diffusion
Drops
Electronics packaging
Intermetallics
Nickel
Polymers
Reliability
Testing
Analytical software
Ball grid array packages
Comparison study
Cu diffusion
Diffusion rate
Drop test
Drop test reliability
Drop-balls
High temperature stress
IMC thickness
Kirkendall void
Lead-free products
Reliability performance
Reliability test
Solder ball shear
Solder balls
Solder joints
Stress test
Work study
Soldering
spellingShingle Copper
Diffusion
Drops
Electronics packaging
Intermetallics
Nickel
Polymers
Reliability
Testing
Analytical software
Ball grid array packages
Comparison study
Cu diffusion
Diffusion rate
Drop test
Drop test reliability
Drop-balls
High temperature stress
IMC thickness
Kirkendall void
Lead-free products
Reliability performance
Reliability test
Solder ball shear
Solder balls
Solder joints
Stress test
Work study
Soldering
Kar Y.B.
Hui T.C.
Agileswari R.
Lo C.
Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests
description Drop ball reliability for Ball Grid Array (BGA) package on lead-free product is a major reliability concern. Integrating a polymer core in the solder ball could be a good strategy to dissipate stress better compared to the purely metallic solder ball. However, the diffusion rate of the copper is much faster than the diffusion rate of the solder. Hence, Kirkendall voids starts forming and causing crack between the interface of copper and solder. This could affect the solder joint as well as the solder ball drop reliability especially when subjected to high temperature stress. The new polymer core solder ball with 1 ?m thickness of nickel (Ni) coated on the copper (polymer core/copper/nickel/solder) could offer better solder ball joint and drop reliability performance. This work studies the effects of IMC growth, solder ball shear strength and drop test reliability. Subsequently, the failure modes were observed after multiple reflow (up to 5 times) and HTS stress tests. The IMC formation was observed under the high power scope with magnification 50� via the mechanical cross-section and was measured using an analytical software tool. Solder ball shear test was carried out to measure the solder joint performance after multiple reflow and HTS stress tests via the Dage 4000 series bond tester. Drop reliability test was carried out via the packing drop test. From this study, we could conclude that the polymer core solder ball with an additional Ni layer coating demonstrates better performance than the polymer core solder ball without Ni layer. The same observation applies to the solder ball shear strength, drop reliability performance in multiple reflow and HTS stress tests. The IMC thickness for polymer core solder ball without additional Ni layer is much thicker than the polymer core solder ball with an additional Ni layer, most probably because Ni could limit the Cu diffusion into the solder, thus resulting in better reliability performance. � 2012 Elsevier Ltd. All rights reserved.
author2 26649255900
author_facet 26649255900
Kar Y.B.
Hui T.C.
Agileswari R.
Lo C.
format Article
author Kar Y.B.
Hui T.C.
Agileswari R.
Lo C.
author_sort Kar Y.B.
title Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests
title_short Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests
title_full Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests
title_fullStr Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests
title_full_unstemmed Comparison study on reliability performance for polymer core solder balls under multiple reflow and HTS stress tests
title_sort comparison study on reliability performance for polymer core solder balls under multiple reflow and hts stress tests
publishDate 2023
_version_ 1806427990065676288
score 13.214268