High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging
Nano-copper sintering is one of new die-attachment and interconnection solutions to realize the wide bandgap semiconductor power electronics packaging with benefits on high temperature, low inductance, low thermal resistance and low cost. Aiming to assess the high-temperature reliability of sintered...
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sg-ntu-dr.10356-1648802023-07-14T16:07:59Z High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging Fan, Jiajie Jiang, Dawei Zhang, Hao Hu, Dong Liu, Xu Fan, Xuejun Zhang, Guoqi School of Materials Science and Engineering Engineering::Materials Power Electronics Packaging Nano-Copper Sintering Nano-copper sintering is one of new die-attachment and interconnection solutions to realize the wide bandgap semiconductor power electronics packaging with benefits on high temperature, low inductance, low thermal resistance and low cost. Aiming to assess the high-temperature reliability of sintered nano-copper die-attachment and interconnection, this study characterized the mechanical properties of sintered nano-copper particles using the high-temperature nanoindentation tests. The results showed that: firstly, the hardness and indentation modulus of the sintered nano-copper particles increased rapidly when the loading rate increased below 0.2 mN·s−1 and then stabilized, and decreased with increased applied load up to 30 mN. Next, by extracting the yield stress and strain hardening index, a plastic stress–strain constitutive model at room temperature for sintered nano-copper particles was obtained. Finally, the high temperature nanoindentation tests were performed at 140 ˚C–200 ˚C on the sintered nano-copper particles prepared under different assisted pressures, which showed that a high assisted pressure resulted in the reduced temperature sensitivity of hardness and indentation modulus. The creep tests indicated that high operation temperature resulted in a high steady-state creep rate, which negatively impacted the creep resistance of sintered nano-copper particles, while the higher assisted pressure could improve the creep resistance. Published version This work was supported by National Natural Science Foundation of China (51805147), Shanghai Pujiang Program (2021PJD002) and Taiyuan Science and Technology Development Funds (Jie Bang Gua Shuai Program). 2023-02-22T00:46:28Z 2023-02-22T00:46:28Z 2022 Journal Article Fan, J., Jiang, D., Zhang, H., Hu, D., Liu, X., Fan, X. & Zhang, G. (2022). High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging. Results in Physics, 33, 105168-. https://dx.doi.org/10.1016/j.rinp.2021.105168 2211-3797 https://hdl.handle.net/10356/164880 10.1016/j.rinp.2021.105168 2-s2.0-85121910659 33 105168 en Results in Physics © 2021 The Author(s). Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). application/pdf |
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Engineering::Materials Power Electronics Packaging Nano-Copper Sintering Fan, Jiajie Jiang, Dawei Zhang, Hao Hu, Dong Liu, Xu Fan, Xuejun Zhang, Guoqi High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
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Nano-copper sintering is one of new die-attachment and interconnection solutions to realize the wide bandgap semiconductor power electronics packaging with benefits on high temperature, low inductance, low thermal resistance and low cost. Aiming to assess the high-temperature reliability of sintered nano-copper die-attachment and interconnection, this study characterized the mechanical properties of sintered nano-copper particles using the high-temperature nanoindentation tests. The results showed that: firstly, the hardness and indentation modulus of the sintered nano-copper particles increased rapidly when the loading rate increased below 0.2 mN·s−1 and then stabilized, and decreased with increased applied load up to 30 mN. Next, by extracting the yield stress and strain hardening index, a plastic stress–strain constitutive model at room temperature for sintered nano-copper particles was obtained. Finally, the high temperature nanoindentation tests were performed at 140 ˚C–200 ˚C on the sintered nano-copper particles prepared under different assisted pressures, which showed that a high assisted pressure resulted in the reduced temperature sensitivity of hardness and indentation modulus. The creep tests indicated that high operation temperature resulted in a high steady-state creep rate, which negatively impacted the creep resistance of sintered nano-copper particles, while the higher assisted pressure could improve the creep resistance. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Fan, Jiajie Jiang, Dawei Zhang, Hao Hu, Dong Liu, Xu Fan, Xuejun Zhang, Guoqi |
| format |
Article |
| author |
Fan, Jiajie Jiang, Dawei Zhang, Hao Hu, Dong Liu, Xu Fan, Xuejun Zhang, Guoqi |
| author_sort |
Fan, Jiajie |
| title |
High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
| title_short |
High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
| title_full |
High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
| title_fullStr |
High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
| title_full_unstemmed |
High-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
| title_sort |
high-temperature nanoindentation characterization of sintered nano-copper particles used in high power electronics packaging |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/164880 |
| _version_ |
1773551364508483584 |