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PAPERS ON RELIABILITY

Adhesion and Reliability of Epoxy/Glass Interfaces

[+] Author and Article Information
John E. Ritter, Armin Huseinovic

Mechanical and Industrial Engineering Department, University of Massachusetts, Amherst, MA 01003-2210

J. Electron. Packag 123(4), 401-404 (Jan 03, 2000) (4 pages) doi:10.1115/1.1388560 History: Received January 03, 2000
Copyright © 2001 by ASME
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References

Turner,  M. R., Dalgleish,  B. J., Yitte,  M., and Evans,  A. G., 1995, “A Fracture Resistance Measurement Method for Bimaterial Interfaces Having Large Debond Energy,” Acta Metall. Mater., 43, pp. 3459–3465.
Ritter,  J. E., Fox,  J. R., Hutko,  D. I., and Lardner,  T. J., 1998, “Moisture-assisted Crack Growth at Epoxy-Glass Interfaces,” J. Mater. Sci., 33, pp. 4581–4588.
Ritter,  J. E., Learned,  J. C., Jácome,  G. S., Russell,  T. P., and Lardner,  T. J., 1999, “Fatigue and Durability of Silane Bonded Epoxy/Glass Interfaces,” Mater. Res. Soc. Symp. Proc., 563, pp. 291–295.
He,  M. Y., Turner,  M. R., and Evans,  A. G., 1995, “Analysis of the Double Cleavage Drilled Compression Specimen for Interface Fracture Energy Measurements Over a Range of Mode Mixities,” Acta Metall. Mater., 43, pp. 3453–3458.
Suo,  Z., and Hutchinson,  J. W., 1989, “Sandwich Test Specimens for Measuring Interface Crack Toughness,” Mater. Sci. Eng., A107, pp. 135–143.
Swander,  J. G., Liechti,  K. M., and de Lozanne,  A. L., 1999, “The Intrinsic Toughness and Adhesion Mechanisms of a Glass/Epoxy Interface,” J. Mech. Phys. Solids, 47, pp. 223–258.
Iler, R. K., 1975, The Chemistry of Silica, Wiley, New York.
Hertzberg, R. W., 1983, Deformation and Fracture Mechanics of Engineering Materials, 4th Edition, John Wiley, New York.
Ritter,  J. E., Sioui,  D. R., and Lardner,  T. J., 1992, “Indentation Behavior of Polymer Coatings on Glass,” Polym. Eng. Sci., 32, pp. 1366–1371.
Wool, R. P., 1995, Polymer Interfaces, Hanser/Gardner Pub., Cincinnati.
Ritter,  J. E., Conley,  K. M., Gu,  W., and Lardner,  T. J., 1992, “Observations on Finger-Like Crack Growth at a Urethane Acrylate/Glass Interface,” J. Adhes., 39, pp. 173–184.

Figures

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Schematic of the fracture mechanics double cleavage drilled compression (DCDC) specimen. Length of specimen is 60 mm.
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(a) Schematic of the DCDC test; (b) schematic of the DCDC loading fixture
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Cyclic fatigue crack growth rates at <20 percent RH along silane (3-APES) bonded epoxy/glass (soda-lime and fused silica) interfaces
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Fatigue crack growth rates along silane (3-APES) bonded epoxy/glass (soda-lime) interfaces under static and cyclic loading at >95 percent RH (data from Reference 3)
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Comparison of fatigue crack growth along silane (3-APES) bonded epoxy/glass (soda-lime) interface under alternating static and cyclic loading at >95 percent RH (data from Reference 3)
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Comparison of cyclic fatigue crack growth rates along silane (3-APES) bonded epoxy/glass (soda-lime) interfaces under humid and dry conditions
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Comparison of cyclic fatigue crack growth rates at >95 percent RH along silane (3-APES) bonded epoxy/glass (soda-lime) interfaces under static and cyclic loading before and after aging in water up to 94°C, 36 h

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