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A Model of Thermal Stress Development in Microelectronic Components

Published online by Cambridge University Press:  21 February 2011

Geoffrey C. Scott  and
Greg Astfalk
Geoffrey C. Scott
Affiliation:
AT&T Bell Laboratories, Engineering Research Center, P.O. Box 900, Princeton, NJ 08540
Greg Astfalk
Affiliation:
Convex Computer Corporation, Suite 800, 7501 Greenway Center Dr., Greenbelt, MD 20770
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Abstract

A model to characterize the development of thermal stresses in printed wiring board (PWB)-mounted multilayer ceramic capacitors (MLCC's) is presented. The model is developed analytically using uncoupled, quasi-static thermoelastic theory. Both the actual 2D geometry and mechanical and thermal properties of real MLCC-PWB structures are incorporated in the model. A particular method for solving the model equations is presented and implemented. Preliminary numerical results indicate that the values and spatial patterns of stress are in agreement with data available in the experimental literature.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 154: Symposium K – Electronic Packaging Materials Science IV , 1989 , 473
Copyright
Copyright © Materials Research Society 1989

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References

[1] Kahn, M., Burks, D., Burn, I., and Schulze, W.A., Ceramic Capacitor Technology, in Electronic Ceramics: Properties, Devices, and Applications, edited by Thurston, M.O. and Middendorf, W. (Marcel Dreker, New York, 1988), pp. 191, 194.Google Scholar
[2] Maxwell, J., Cracks: The Hidden Defect, Technical Report, AVX Corp., 2, (1988).Google Scholar
[3] Hoyt, S.L., editor, ASME Handbook of Metals Properties (McGraw-Hill, New York, 1954), p. 371.Google Scholar
[4] Lynch, C.T., editor, CRC Handbook of Materials Science, Vol III: Nonmetallic Materials and Applications (CRC Press, Boca Raton, FL, 1984), p. 21.Google Scholar
[5] Kaufman, L. and Schryer, N.L., TTGR - A Package for Solving Partial Differential Equations in Two Space Variables, Technical Memorandum 11274–850605–06TMS, AT&T Bell Laboratories, (1985).Google Scholar
[6] McKinney, K.R., Rice, R.W., and Wu, C.C., Mechanical Failure Characteristics of Ceramic Multilayers Capacitors, J. Amer. Ceram. Soc. 69, 10, C-228, (1986).Google Scholar
[7] Pollock, K.L. and Hodgkins, C.E., Fracture Strength of Multilayer Ceramic Capacitors, Proc. Int. Symp. on Microelectronics, 450–456, (1984).Google Scholar
[8] Avyle, J.A. Van Den and Mecholsky, J J., Analysis of Soldering-Induced Cracking of BaTiO3 Ceramic Capacitors, Ferroelectrics 50, 293298, (1983).Google Scholar
[9] Evans, A.G. and Ruhle, M., On the Mechanics of Failure in Ceramic/Metal Bonded Systems, Mater. Res. Soc. Proc. 40, 153166, (1985).Google Scholar
[10] Thouless, M.D., The Role of Fracture Mechanics in Adhesion, Mat. Res. Soc. Proc. 119, 5162, (1988).Google Scholar