DocumentCode
3115959
Title
Energy release rate investigation for through silicon vias (TSVs) in 3D IC integration
Author
Hsieh, Ming-Che ; Wu, Sheng-Tsai ; Wu, Chung-Jung ; Lau, John H. ; Tain, Ra-Min ; Lo, Wei-Chung
Author_Institution
Ind. Technol. Res. Inst., Hsinchu, Taiwan
fYear
2011
fDate
18-20 April 2011
Firstpage
42376
Lastpage
42558
Abstract
The technology of 3D IC integration is highly probable to achieve the demand for high performance, better reliability, miniaturization and lower-priced portable electronic products. Since the through silicon via (TSV) is the heart in 3D IC integration architectures, the reliability issues of TSV interconnects should be extremely concerned. Due to the large thermal expansion mismatch among the Cu, Si, and SiO2, the induced thermal stresses and strains can occur and become the driving forces for failures in TSV interconnects. Hence, the stress analyses and failure mode investigation for TSVs are in urgent need. Among the typical failures, the mostly common failure type is delamination, which will be caused when lower energy release rate (ERR) or higher critical stresses at interfaces are presented. In this study, the finite element modeling (FEM) for a symmetrical single in-line copper filled TSV with redistribution layer is illustrated. Two kinds of horizontal cracks that embedded in the interface of SiO2 passivation and Cu seed layer (Cu pad delamination cases) are introduced to realize the interfacial ERR, where is also the critical stress area that observed from finite element analysis. The significance of design parameters such as crack length, TSV diameter, TSV pitch, depth of TSV, SiO2 thickness and Cu seed layer thickness are also brought up. The methodology of design of experiments (DoE) has been adopted to capture the most important mechanical parameters of the TSV to comprehend the corresponding ERR. It is believed that these results would be helpful to avoid delamination of TSV interconnects in 3D IC integration.
Keywords
copper; design of experiments; finite element analysis; integrated circuit interconnections; integrated circuit reliability; passivation; silicon; silicon compounds; thermal stresses; three-dimensional integrated circuits; 3D integrated circuits; Cu; Si; SiO2; TSV interconnects; design of experiments; energy release rate; failure mode investigation; finite element modeling; induced thermal stresses; integrated circuit reliability; passivation; thermal expansion mismatch; through silicon vias; Copper; Delamination; Finite element methods; Materials; Software; Stress; Through-silicon vias;
fLanguage
English
Publisher
ieee
Conference_Titel
Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE), 2011 12th International Conference on
Conference_Location
Linz
Print_ISBN
978-1-4577-0107-8
Type
conf
DOI
10.1109/ESIME.2011.5765764
Filename
5765764
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