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Materials in Electronic Manufacturing: Electronic Packaging

Published online by Cambridge University Press:  29 November 2013

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Extract

Electronic packaging involves using an appropriate combination of conductive and dielectric materials to electrically interconnect and mechanically support electronic components in a reliable and cost-effective manner. Since the invention of the integrated circuit in 1959 and mass wave-soldering in 1958, the vast majority of electronic packaging has involved a planar substrate to which semiconductor devices in protective packages are attached by melting eutectic solder. The planar substrates or printed circuit boards (PCBs) were invented in 1940, but their widespread implementation was limited until the invention of mass soldering. PCBs use conventional epoxy-glass dielectric material with mass patterned conductive traces of copper, but alternative materials have been used for either enhanced electrical performance or lower product cost.

Type
Materials Manufacturing
Copyright
Copyright © Materials Research Society 1992

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References

1.Leonida, G., Handbook of Printed Circuit Design, Manufacture, Components & Assembly, (Electrochemical Publications, Ayr, Scotland, 1981) p. 437.Google Scholar
2.Leonida, G., Handbook of Printed Circuit Design, Manufacture, Components & Assembly, (Electrochemical Publications, Ayr, Scotland, 1981), p. 123.Google Scholar
3.Bakoglu, H.B., Circuits, Interconnections, and Packaging for VLSI, (Addison Wesley, Reading, Massachusetts, 1990) p. 416421.Google Scholar
4.Schoenthaler, D. and Pfahl, R.C. Jr., “Reflow Soldering of Circuits on Heat Sensitive Materials,” Proceedings of the 11th Electrical Insulation Conference, IEEE Publication No. 73 CHO 7773EI (1973) p. 242245.Google Scholar
5.Chu, T.Y., Mollendorf, J.C., and Pfahl, R.C. Jr., “Soldering Using Condensation Heat Transfer,” Proceedings of the Technical Program NEPCON '74, Anaheim, California (1974) p. 101104.Google Scholar
6.Pfahl, R.C. Jr., Mollendorf, J.C., and Chu, T.Y., “Condensation Soldering,” Welding Journal 54 (1) (1975) p. 2225.Google Scholar
7.Andersen, S.O., “Worldwide Cooperation to Reduce and Eliminate CFC-113 and Methyl Chloroform Use in the Electronics Industry,” Proceedings of the Technical Program NEPCON West '91, Anaheim, California (1991) p. 321328.Google Scholar
8.Rubin, W., Kirschner, M., and Adams, S., “Low Residue Fluxes and Their Application in the Formation of Low Residue Solder Pastes,” IPC-TP-884 Second International Conference on Flux Technology (1990).Google Scholar
9.Morris, J.R., “Characterizing Solder Pastes for the 1990s,” IPC-TP-901 Second International Conference on Flux Technology (1990).Google Scholar
10.Nayer, H.S. and Adams, S.M., “Reflow Soldering with Reactive Gases,” Electronic Packaging and Production, (November 1990) p. 3940.Google Scholar
11.Tummala, R. and Rymaszewski, E.J., Microelectronic Packaging Handbook (Van Nostrand Reinhold, New York, 1989).CrossRefGoogle Scholar
12.Seraphim, D., Lasky, R., and Li, Che-Yu, Principles of Electronic Packaging (McGraw-Hill, New York, 1989).CrossRefGoogle Scholar
13.Johnson, R.W., Tend, R.K.F., and Balde, J.W., Multichip Modules Systems Advantages, Major Constructions, and Materials Technologies (IEEE Press, New York, 1991).Google Scholar
14.Pfahl, R.C. Jr., “Heat Transfer in Electronic Equipment; The Manufacturing Environment,” Heat Transfer in Electronic Equipment: Report of Research Workshop, NSF Grant Eng-7701297 (1977) p. 4951.Google Scholar
15.Brown, V.L., “HyperModule,” IEEE Computer Packaging Workshop, Santa Cruz, CA (1989).Google Scholar
16.Engelmaier, W., “Functional Cycles and Surface Mounting Attachment Reliability,” Surface Mount Technology, ISHM (1984) p. 87114.Google Scholar