Stress-Induced Delamination Of Through Silicon Via Structures

Ryu, Suk Kyu; Lu, Kaijun; Im, James S.; Huang, Rui; Ho, Paul S.

doi:10.1063/1.3615702

Cited by 16 publications

(7 citation statements)

References 24 publications

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“…9a). A previous study has suggested that via extrusion could be caused by interfacial delamination [19]. However, in the present study, no evidence of interfacial delamination was observed.…”

Section: Effect Of Cu Plasticity On Via Extrusioncontrasting

confidence: 83%

Thermomechanical characterization and modeling for TSV structures

Jiang

Ryu

Zhao

et al. 2014

AIP Conference Proceedings

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Abstract. Continual scaling of devices and on-chip wiring has brought significant challenges for materials and processes beyond the 32-nm technology node in microelectronics. Recently, three-dimensional (3-D) integration with through-silicon vias (TSVs) has emerged as an effective solution to meet the future technology requirements. Among others, thermo-mechanical reliability is a key concern for the development of TSV structures used in die stacking as 3-D interconnects. This paper presents experimental measurements of the thermal stresses in TSV structures and analyses of interfacial reliability. The micro-Raman measurements were made to characterize the local distribution of the near-surface stresses in Si around TSVs. On the other hand, the precision wafer curvature technique was employed to measure the average stress and deformation in the TSV structures subject to thermal cycling. To understand the elastic and plastic behavior of TSVs, the microstructural evolution of the Cu vias was analyzed using focused ion beam (FIB) and electron backscattering diffraction (EBSD) techniques. Furthermore, the impact of thermal stresses on interfacial reliability of TSV structures was investigated by a shear-lag cohesive zone model that predicts the critical temperatures and critical via diameters.

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Section: Effect Of Cu Plasticity On Via Extrusioncontrasting

confidence: 83%

Thermomechanical characterization and modeling for TSV structures

Jiang

Ryu

Zhao

et al. 2014

AIP Conference Proceedings

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“…Sukharev [ 43 ] and Lau [ 44 ] reported finite element analysis simulations of TSV upon electromigration (EM) failure, which is when the TSV is unable to deliver the necessary voltage to any circuitry gate. Ryu et al [ 45 ] and Stiebing et al [ 46 ] suggested considering thermal cycling, which causes the TSV to extrude from the surrounding matrix or substrate. This phenomenon occurs due to a coefficient of thermal expansion mismatch between the surrounding substrate and the metal filler in TSV.…”

Section: Three-dimensional Integrated Circuits: the Technologymentioning

confidence: 99%

Intermetallic compounds in 3D integrated circuits technology: a brief review

Annuar

Mahmoodian

Hamdi

et al. 2017

Science and Technology of Advanced Materials

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The high performance and downsizing technology of three-dimensional integrated circuits (3D-ICs) for mobile consumer electronic products have gained much attention in the microelectronics industry. This has been driven by the utilization of chip stacking by through-Si-via and solder microbumps. Pb-free solder microbumps are intended to replace conventional Pb-containing solder joints due to the rising awareness of environmental preservation. The use of low-volume solder microbumps has led to crucial constraints that cause several reliability issues, including excessive intermetallic compounds (IMCs) formation and solder microbump embrittlement due to IMCs growth. This article reviews technologies related to 3D-ICs, IMCs formation mechanisms and reliability issues concerning IMCs with Pb-free solder microbumps. Finally, future outlook on the potential growth of research in this area is discussed.

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“…The vias have structures that go through the entire substrate and the stresses can be higher in the middle of the stack than the flanges. The stress field induced by differential thermal expansion in the via is threedimensional in nature [1]. It is necessary to investigate the stresses in the stacked via to get the full picture.…”

Section: Stacked Microvia Stressesmentioning

confidence: 99%

Predicting Package Level Failure Modes in Multi Layered Packages

Sharon

Caswell

Blattau

2015

International Symposium on Microelectronics

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Package technology is constantly improving in order to keep up with the advances in silicon technology. Multi layered packages exhibit several failure modes that can be predicted using modern software tools. This paper provides a methodology for creating a high-fidelity model of the interposer with all the conductor geometries. The two failure modes that are explored with this model are package warpage prediction due to actual copper imbalance and filled microvia delamination. Each layer can meshed based on the actual geometry in the layout design. Package warpage is caused by copper imbalance between the two sides of the interposer. The CTE mismatch between the two sides can bend the package to such a degree that it becomes impossible to assemble the solder interconnects. The filled microvias have copper structures that can delaminate from the copper traces in the conductor layers. The high-fidelity model provides the predictive tool to allow designers to adjust the layout before any manufacturing has taken place.

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Stress-Induced Delamination Of Through Silicon Via Structures

Cited by 16 publications

References 24 publications

Thermomechanical characterization and modeling for TSV structures

Thermomechanical characterization and modeling for TSV structures

Intermetallic compounds in 3D integrated circuits technology: a brief review

Predicting Package Level Failure Modes in Multi Layered Packages

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