Annealing temperature effect on the Cu-Cu bonding energy for 3D-IC integration

被引：0

作者：

Eun-Jung Jang

Jae-Won Kim

Bioh Kim

Thorsten Matthias

Young-Bae Park

机构：

[1] Andong National University,School of Materials Science and Engineering

[2] EV Group,undefined

来源：

Metals and Materials International | 2011年 / 17卷

关键词：

diffusion bonding; toughness; metals; focus ion beam (FIB); transmission electron microscopy (TEM);

D O I：

暂无

中图分类号：

学科分类号：

摘要：

Interfacial adhesive energy was evaluated quantitatively in relation to the bonding temperature and subsequent thermal treatment to develop a Cu-Cu thermal compressed bonding process at low temperature for a three-dimensional integration circuit (3D-IC) package. Two pieces of sputtered Cu films coated on a Si wafer were bonded at 300 °C, 350 °C, and 400 °C. A high bonding temperature increased the interfacial adhesive energy, and the original interfacial layers of Cu film gradually disappeared, as observed in focus ion beam (FIB) images. Specimens of Cu to Cu bonding were thermally compressed at 300 °C and were post-annealed at 200 °C, 250 °C, and 300 °C in a N2 environment for 1 h. As a result, the original interfacial layer of Cu disappeared at 300 °C, and an interfacial adhesive energy value above 10 J/m2 was obtained.

引用

页码：105 / 109

页数：4

共 50 条

[31] Enhancement on the bonding strength of Cu-Cu joints by 2 steps annealing
Ong, Jia Juen
Tu, K. N.
Chen, Chih
2020 15TH INTERNATIONAL MICROSYSTEMS, PACKAGING, ASSEMBLY AND CIRCUITS TECHNOLOGY CONFERENCE (IMPACT 2020), 2020, : 79 - 81
[32] Low temperature direct Cu-Cu bonding with low energy ion activation method
Kim, TH
Howlader, MMR
Itoh, T
Suga, T
ADVANCES IN ELECTRONIC MATERIALS AND PACKAGING 2001, 2001, : 193 - 195
[33] Nano Ni/Cu-TSVs with an Improved Reliability for 3D-IC Integration Application
Murugesan, M.
Mori, K.
Kojima, T.
Hashimoto, H.
Bea, J. C.
Fukushima, T.
Koyanagi, M.
2020 31ST ANNUAL SEMI ADVANCED SEMICONDUCTOR MANUFACTURING CONFERENCE (ASMC), 2020,
[34] Low Temperature Cu-Cu Bonding Technology in Three-Dimensional Integration: An Extensive Review
Panigrahy, Asisa Kumar
Chen, Kuan-Neng
JOURNAL OF ELECTRONIC PACKAGING, 2018, 140 (01)
[35] Low-temperature bonding technologies for MEMS and 3D-IC
20143818167102
(1) SINTEF, Oslo, Norway; (2) STMicroelectronics Malta, Kirkop, Malta; (3) Besi Austria GmbH, Radfeld, Austria; (4) Fraunhofer EMFT, Munich, Germany; (5) University of Oslo, Oslo, Norway, 1600, Technology Society; The IEEE Components, Packaging, and Manufacturing (IEEE Computer Society):
[36] Low Temperature Cu/In Bonding for 3D Integration
Panchenko, Iuliana
Bickel, Steffen
Meyer, Joerg
Mueller, Maik
Wolf, Juergen M.
2017 5TH INTERNATIONAL WORKSHOP ON LOW TEMPERATURE BONDING FOR 3D INTEGRATION (LTB-3D), 2017, : 17 - 17
[37] Diffusion enhanced drive sub 100 °C wafer level fine-pitch Cu-Cu thermocompression bonding for 3D IC integration
Panigrahi, Asisa Kumar
Sathish, Bonam
Ghosh, Tamal
Vanjari, Siva Rama Krishna
Singh, Shiv Govind
2019 IEEE 69TH ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE (ECTC), 2019, : 2156 - 2161
[38] Low-Temperature (260 °C) Solderless Cu-Cu Bonding for Fine-Pitch 3-D Packaging and Heterogeneous Integration
Park, Haesung
Seo, Hankyeol
Kim, Yoonho
Park, Seungmin
Kim, Sarah Eunkyung
IEEE TRANSACTIONS ON COMPONENTS PACKAGING AND MANUFACTURING TECHNOLOGY, 2021, 11 (04): : 565 - 572
[39] Low Temperature Bump-less Cu-Cu Bonding Enhancement with Self Assembled Monolayer (SAM) Passivation for 3-D Integration
Lim, Dau Fatt
Wei, Jun
Chee Mang Ng
Tan, Chuan Seng
2010 PROCEEDINGS 60TH ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE (ECTC), 2010, : 1364 - 1369
[40] Low-Temperature Cu-Cu Direct Bonding Using Pillar-Concave Structure in Advanced 3-D Heterogeneous Integration
Yang, Yu-Tao
Chou, Tzu-Chieh
Yu, Ting-Yang
Chang, Yu-Wei
Huang, Tai-Yuan
Yang, Kai-Ming
Ko, Cheng-Ta
Chen, Yu-Hua
Tseng, Tzyy-Jang
Chen, Kuan-Neng
IEEE TRANSACTIONS ON COMPONENTS PACKAGING AND MANUFACTURING TECHNOLOGY, 2017, 7 (09): : 1560 - 1566

← 1 2 3 4 5 →