Low-Resistance and high-Strength Copper Direct Bonding in no-Vacuum Ambient Using Highly (111)-Oriented Nano-Twinned Copper

2019 IEEE 69th Electronic Components and Technology Conference (ECTC) Pub Date : 2019-05-28 DOI:10.1109/ECTC.2019.00102

J. Juang, K. Shie, Po-Ning Hsu, Yu Jin Li, K. Tu, Chih Chen

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引用次数: 7

Abstract

In this study, we fabricated (111)-oriented nt-Cu microbumps with 30 µm in diameter, and bonded them together using chip-to-chip bonding scheme in N2 ambient, without vacuum. A well bonded interface in the Cu-to-Cu joint was identified by the microstructure observation. Scanning electron microscope (SEM) images showed a void-less bonding interface within the bonded Cu joint. In addition, a die shear test was conducted. The test results revealed that the shear strength is 124 MPa, which is nearly two times higher than the SnAg solder joint (64 MPa). It indicates that the Cu joint is more robust than the SnAg joint. In addition, fracture analysis showed that the joint fractured in a ductile manner. Besides, we also performed the resistance measurement by using Kelvin probes on the bonded chip-to-chip test vehicles. The resistance is 4.12 mΩ for a single joint and its contact resistivity is 4.26 × 10-8 Ω·cm2. More than 30% resistance reduction has been confirmed as compared to the SnAg solder joint (6.32 mΩ). Moreover, we can further reduce the joint resistance by the second annealing process. The resistance can be brought down to 3.27 mΩ with a resistivity of 3.14 × 10^-8 Ω·cm^2. There is a nearly 50% resistance reduction The resistance for second annealed Cu joint is close the ideal bulk Cu. In summary, the chip-to-chip copper direct bonding has been successfully achieved and low resistance Cu-to-Cu joints has been realized by using (111) oriented nt-Cu in no-vacuum ambient.

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高(111)取向纳米孪晶铜在无真空环境下的低电阻和高强度铜直接键合

在本研究中，我们制作了直径为30µm的(111)取向的nt-Cu微凸起，并在N2环境下无真空的情况下采用芯片对芯片的键合方式将它们粘接在一起。通过显微组织观察，发现cu - cu接头中存在良好的结合界面。扫描电子显微镜(SEM)图像显示，铜接头内存在无孔洞的结合界面。此外，还进行了模具剪切试验。试验结果表明，其抗剪强度为124 MPa，比SnAg焊点(64 MPa)高出近2倍。这表明Cu接头比SnAg接头更坚固。断口分析表明，接头断裂为延性断裂。此外，我们还利用开尔文探针在键合芯片对芯片测试车上进行了电阻测量。单个接头的电阻为4.12 mΩ，接触电阻率为4.26 × 10-8 Ω·cm2。与SnAg焊点(6.32 mΩ)相比，已确认电阻降低30%以上。此外，我们可以通过二次退火工艺进一步降低接头电阻。电阻可降至3.27 mΩ，电阻率为3.14 × 10^-8 Ω·cm^2。二次退火铜接头的电阻接近理想体铜。综上所述，在无真空环境下，采用(111)取向的nt-Cu材料成功地实现了片与片之间的铜直接键合，实现了低电阻的cu - cu连接。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 IEEE 69th Electronic Components and Technology Conference (ECTC)

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