Formation mechanism for the interface between Cu and Sn formed by magnetic pulse welding
Hehe Zhang, Tiantian Tan, Man Yang, Chunjiang Guo, Limeng Yin, Long Zhang, Sensen Chai
Abstract
The formation of interfacial intermetallic compounds (IMCs) such as Cu 6 Sn 5 , Cu 3 Sn or platelet-shaped Ag 3 Sn which are formed in reflow soldering process will directly destroy the soldering reliability. Magnetic pulse welding (MPW), as a solid state welding technique can effectively restrain or even impede the formation of interfacial IMCs. In this paper, Cu and Sn dissimilar metals were welded by MPW under the discharge energy from 17 to 31 kJ. The typical wavy interface and metal jet flow were found in all samples. When the discharge energy reached 31 kJ, a typical gradient nanograined (GNG) interface has been observed to undergo an evolution from a sub-micron secondary solid solution of Cu 6.26 Sn 5 IMCs to a nanoscale secondary solid solution of Cu 81 Sn 22 IMCs, followed by the formation of nanoscale equiaxed α-Cu grains, and ultimately leading to the deformed elongated nanoscale α-Cu grains. This discontinuous distribution of the aforementioned phases occurs specifically at the interface of the 23 kJ_1.5 mm sample. In contrast, when subjected to a discharge energy of 17 kJ, there were no indications of a secondary solid solution of Cu 6.26 Sn 5 IMCs or elongated nanoscale α-Cu grains. However, a discontinuous secondary solid solution of Cu 81 Sn 22 IMCs was observed to form at the Cu/Sn interface under these conditions. Based on these findings, the utilization of microprojection welding (MPW) techniques involving Cu and Sn-based solder in the microscale is anticipated to serve as a highly efficient and automated technology within the field of electronic micropackaging.