Numerical Analysis of the Reliability of Cu/low-k Bond Pad Interconnections Under Wire Pull Test: Application of a 3D Energy Based Failure Criterion

Gallois-Garreignot, Sebastien; Fiori, Vincent; Orain, S.; Sluis, O. van der

doi:10.1109/esime.2007.359940

Cited by 9 publications

(7 citation statements)

References 12 publications

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“…Note that the numerical parameters to be used, the sensitivity and the ability to link this value with the energy release rate has been previously validated; and additional insights compared to a standard stress based analysis have been demonstrated [18] Finite Element Models Multi level models The three dimensional bonding model consists of a silicon die containing the interconnect layers, the gold wire and ball, and the capillary. The simulated die stack is seven copper metal levels (7ML) including five low-k levels and the two others containing classical silicon dioxide dielectric.…”

Section: Modeling Methodologymentioning

confidence: 99%

“…Furthermore, micro-crack is highly suspected at the early stage of peeling failure, which is initiated at the many interfaces of metal layer and low-k dielectric. Hence, the targeted failure mode, which is brittle delamination, is related to fracture mechanics and specific energy based numeric tools are developed [18,19]. The so-called Nodal Released Energy (NRE) post processing procedure is based on the computation of energetic quantity from the nodal solution.…”

Section: Modeling Methodologymentioning

confidence: 99%

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3D Multi Scale Modeling of Wire Bonding Induced Peeling in Cu/Low-k Interconnects: Application of an Energy Based Criteria and Correlations with Experiments

Fiori

Beng²,

Downey³

et al. 2007

2007 Proceedings 57th Electronic Components and Technology Conference

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Amongst solutions to connect the die to the package, thermosonic wire bonding process remains widely used. However, the introduction of low-k dielectric materials, and the feature size decrease of IC chips to follow Moore's law, pose great integration challenge.This paper aims to demonstrate the compliance of the proposed modeling approach with the aids of experimental validations. 3D multi scale simulation of both bonding process and wire pull test is carried out. Using a previously validated homogenization procedure to include pad structure description even at the global scale, stress fields acting in the copper/low-k stack are evaluated. The modeling strategy also includes an in-house developed energy based analysis.For the experimental part, a wide range of wire bond trials have been performed in order to qualify the 65-nm technology node. On behalf of that, several bond pad architectures have been implemented and wire bonded on a test vehicle. It was found a significant effect of the copper/low-k design on peeling failure rates, in particular with severe bonding conditions. In this paper, typical modeling results are presented. Contrary to stress based one, the energy based analysis shows a better ability to forecast the observed failed interface. From simulation results obtained, it is confirmed that the bonding process plays major role in the peeling failure, despite the fact that most of them are observed during the wire pull test. Failure mechanisms are also proposed. Then, the implemented pad structures are evaluated and analyzed. Both general trends and architecture ranking are provided. Simulations are then faced to experimental results and a full agreement is found. The complementary nature of the energy based failure criteria is again highlighted through a clearer discrimination of the tested structures.Finally, the simulation procedure with confirmed experimental results demonstrates its ability in design and process optimizations by providing a better understanding of pad peeling failure mechanisms.

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Section: Modeling Methodologymentioning

confidence: 99%

Section: Modeling Methodologymentioning

confidence: 99%

3D Multi Scale Modeling of Wire Bonding Induced Peeling in Cu/Low-k Interconnects: Application of an Energy Based Criteria and Correlations with Experiments

Fiori

Beng²,

Downey³

et al. 2007

2007 Proceedings 57th Electronic Components and Technology Conference

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“…This method is quite attractive since both the nucleation and the propagation are included in the model. The second one has been in-house developed, the named Nodal Release Energy (NRE) method [9] (inspired from Area Release Energy technique [10]) has demonstrated its robustness and efficiency through similar applications [11][12]. However, since a virtual crack must be initially assumed, only propagation phenomenon is addressed by this method.…”

Section: Numerical Investigationsmentioning

confidence: 99%

Package induced low-k delaminations: Numerical developments and experimental investigations to address FEBE compatibility fracture phenomena.

Gallois-Garreignot

Fiori

Nélias

2009

EuroSimE 2009 - 10th International Conference on Thermal, Mechanical and Multi-Physics Simulation and Experiments in Microelect

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“…However, failure criterion and failure mode are still unknown even wire bond induced stress can be monitored. Finite element analysis (FEA) of wire bonding can lead to the possibility for virtual experiment, leading to an improved knowledge of how parameters influence the bonding process and damage mechanisms [6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Study on failure mode and mechanism of bond pad under Cu ball bonding process using wire pull test and finite element modeling

Wai

Hsiao

et al. 2015

2015 IEEE 17th Electronics Packaging and Technology Conference (EPTC)

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In this work, wire pull test combined with finite element analysis (FEA) were conducted to investigate failure mode and failure criterion for bond pad reliability assessment under Cu wire bond process. Pull test was conducted for bonded Cu wires with different pull locations changing from the first ball bond to the second wedge bond. Failure forces were recorded and failure site and modes were studied. The effect of pull location on failure mode was observed. Failure modes change from wire neck broken, ball lift, pad peel to wedge broken when pull location is changing from the first bond towards the second bond. Based on wire pull test and FEA simulation results, failure mechanism and failure criterion were developed for different Cu wire bond failure modes. The effects of wire loop height on pull test results and modeling stress were also investigated.

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Numerical Analysis of the Reliability of Cu/low-k Bond Pad Interconnections Under Wire Pull Test: Application of a 3D Energy Based Failure Criterion

Cited by 9 publications

References 12 publications

3D Multi Scale Modeling of Wire Bonding Induced Peeling in Cu/Low-k Interconnects: Application of an Energy Based Criteria and Correlations with Experiments

3D Multi Scale Modeling of Wire Bonding Induced Peeling in Cu/Low-k Interconnects: Application of an Energy Based Criteria and Correlations with Experiments

Package induced low-k delaminations: Numerical developments and experimental investigations to address FEBE compatibility fracture phenomena.

Study on failure mode and mechanism of bond pad under Cu ball bonding process using wire pull test and finite element modeling

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