Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics
A novel lead-free foil (AlMgGaLi) with a melting point of 398.3 ~ 414.8 °C was developed for active soldering of copper to aluminum matrix composite. The effect of joining pressure on the microstructure, interface wetting and shear strength of the dissimilar joints was analyzed. When the joining pre...
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sg-ntu-dr.10356-1514872021-06-17T01:29:31Z Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics Chen, Biqiang Chen, Zhong Du, Zehui Zhang, Guifeng School of Materials Science and Engineering Engineering::Materials Copper Dissolution A novel lead-free foil (AlMgGaLi) with a melting point of 398.3 ~ 414.8 °C was developed for active soldering of copper to aluminum matrix composite. The effect of joining pressure on the microstructure, interface wetting and shear strength of the dissimilar joints was analyzed. When the joining pressure increased to 1 MPa, an Al-based solid solution with an atomic composition of 89.62% Al, 6.5% Mg, 3.1% O, 0.46% Cu, 0.23% Ga and 0.09% Si was formed within the bond seam and the thickness of the transition layer with copper dissolution was approximately 4.9 μm. The joining pressure improved the interfacial wettability of the dissimilar joint by enhancing mutual diffusion with a shortened interface layer, tailored the runout and the formation of bond seam, and controlled an appropriate thickness of the copper dissolution transition layer. Sound joint with a maximum shear strength of 94 MPa (~ 80% of parent composites) is achievable at 450 °C using the joining pressure of 1 MPa. The failure mechanism of the joints with the AlMgGaLi foil under shear stress has been revealed from the analysis on the interface layers of the joints with SEM/EDX/XRD. Our studies provide an important guideline for using an AlMgGaLi and other similar fillers for a successfully joining of copper to Al-MMCs for high-temperature and high-power electronic devices. The present research was supported by the National Natural Science Foundation of China (No. 51275390) and the China Scholarship Council. 2021-06-17T01:29:31Z 2021-06-17T01:29:31Z 2019 Journal Article Chen, B., Chen, Z., Du, Z. & Zhang, G. (2019). Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics. Applied Physics A: Materials Science and Processing, 125(8), 581-. https://dx.doi.org/10.1007/s00339-019-2884-2 0947-8396 0000-0001-7783-1185 https://hdl.handle.net/10356/151487 10.1007/s00339-019-2884-2 2-s2.0-85073644464 8 125 581 en Applied Physics A: Materials Science and Processing © 2019 Springer-Verlag GmbH Germany, part of Springer Nature. All rights reserved. |
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Engineering::Materials Copper Dissolution Chen, Biqiang Chen, Zhong Du, Zehui Zhang, Guifeng Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics |
| description |
A novel lead-free foil (AlMgGaLi) with a melting point of 398.3 ~ 414.8 °C was developed for active soldering of copper to aluminum matrix composite. The effect of joining pressure on the microstructure, interface wetting and shear strength of the dissimilar joints was analyzed. When the joining pressure increased to 1 MPa, an Al-based solid solution with an atomic composition of 89.62% Al, 6.5% Mg, 3.1% O, 0.46% Cu, 0.23% Ga and 0.09% Si was formed within the bond seam and the thickness of the transition layer with copper dissolution was approximately 4.9 μm. The joining pressure improved the interfacial wettability of the dissimilar joint by enhancing mutual diffusion with a shortened interface layer, tailored the runout and the formation of bond seam, and controlled an appropriate thickness of the copper dissolution transition layer. Sound joint with a maximum shear strength of 94 MPa (~ 80% of parent composites) is achievable at 450 °C using the joining pressure of 1 MPa. The failure mechanism of the joints with the AlMgGaLi foil under shear stress has been revealed from the analysis on the interface layers of the joints with SEM/EDX/XRD. Our studies provide an important guideline for using an AlMgGaLi and other similar fillers for a successfully joining of copper to Al-MMCs for high-temperature and high-power electronic devices. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Chen, Biqiang Chen, Zhong Du, Zehui Zhang, Guifeng |
| format |
Article |
| author |
Chen, Biqiang Chen, Zhong Du, Zehui Zhang, Guifeng |
| author_sort |
Chen, Biqiang |
| title |
Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics |
| title_short |
Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics |
| title_full |
Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics |
| title_fullStr |
Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics |
| title_full_unstemmed |
Application of AlMgGaLi foil for joining copper to SiCp/Al-MMCs for high-temperature and high-power electronics |
| title_sort |
application of almggali foil for joining copper to sicp/al-mmcs for high-temperature and high-power electronics |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151487 |
| _version_ |
1703971157619769344 |