Abstract
The failure mechanisms of Cu–Cu bumps under thermal cycling test (TCT) were investigated. The resistance change of Cu–Cu bumps in chip corners was less than 20% after 1000 thermal cycles. Many cracks were found at the center of the bonding interface, assumed to be a result of weak grain boundaries. Finite element analysis (FEA) was performed to simulate the stress distribution under thermal cycling. The results show that the maximum stress was located close to the Cu redistribution lines (RDLs). With the TiW adhesion layer between the Cu–Cu bumps and RDLs, the bonding strength was strong enough to sustain the thermal stress. Additionally, the middle of the Cu–Cu bumps was subjected to tension. Some triple junctions with zig-zag grain boundaries after TCT were observed. From the pre-existing tiny voids at the bonding interface, cracks might initiate and propagate along the weak bonding interface. In order to avoid such failures, a postannealing bonding process was adopted to completely eliminate the bonding interface of Cu–Cu bumps. This study delivers a deep understanding of the thermal cycling reliability of Cu–Cu hybrid joints.
Highlights
The COVID-19-pandemic-led surge in demand for high-performance computing chips is prevailing
DtoutehteohthigehhCigThECoTfEthoef dthieldecietrleiccstraicnsdawndeawkegarkaignrabionubnoduanrdieasrioefs the bonding interface, cracks formed at the middle of the Cu–Cu bumps
We found that some triple junctions formed at the bonding interface of the bump bonded at 300 ◦C/90 MPa/30 s
Summary
The COVID-19-pandemic-led surge in demand for high-performance computing chips is prevailing. They are used in high-end electronic devices, such as complementary metal oxide semiconductor (CMOS) image sensors [1] and high bandwidth memory (HBM) [2]. In a 3D IC device, solder microbumps have been widely used as interconnects between functional chips and an interposer [7]. Those solders severely suffer from electromigration [8,9,10] and thermal fatigue [11,12,13] during operations. This can lead to the severe formation of intermetallic compounds (IMCs), necking, and voids in the solder microbumps [6,14,15,16,17]
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