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Phase-Separated Inorganic-Organic Hybrids for Microelectronic Applications

Published online by Cambridge University Press:  29 November 2013

R.D. Miller ,
J.L. Hedrick ,
D.Y. Yoon ,
R.F. Cook  and
J.P. Hummel
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Extract

As on-chip device densities increase and active device dimensions shrink, signal delays and noise increase due to capacitive coupling and crosstalk between the metal interconnections. Since delays, noise, and power consumption all depend critically on the dielectric constant of the separating insulator, much attention has focused recently on replacing standard silicon dioxide with new intermetal dielectrics (IMDs) having dielectric constants considerably lower than conventional oxide (k = 3.9–4.2). On-chip silicon dioxide insulators are currently deposited by gas-phase techniques such as chemical vapor deposition or plasma-enhanced chemical vapor deposition. Silicate films may also be formed at lower temperatures by sol-gel procedures. In the sol-gel process, typically an orthosilicate ester is hydrolyzed with water. This often occurs in an organic solvent to form a soluble, partially condensed polymer (sol) that can be spun on a substrate to produce a solvent-containing film. Subsequent solvent removal and curing results in the silicate film. The process involves hydrolysis to generate polyfunctional silanols followed by condensation polymerization to eventually yield a gel. Since both processes involve the substantial loss of volatile materials, considerable shrinkage occurs (75–85% is typical). Inhomogeneity of shrinkage or shrinkage on constraining substrates can often lead to cracking unless the films are very thin (often <1 μm). In the sol-gel process, a variety of techniques are employed to avoid capillary-driven cracking forces, including (1) very slow drying, (2) drying with supercritical fluids, or (3) chemically controlled condensation.

Type
Low-Dielectric-Constant Materials
Information
MRS Bulletin , Volume 22 , Issue 10: Low-Dielectric-Constant Materials , October 1997 , pp. 44 - 48
Copyright
Copyright © Materials Research Society 1997

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References

1. Tummala, R.R., Keyes, R.W., Grobman, W.D., and Kapur, S. in Microelectronics Packaging Handbook, edited by Tummala, R.R. and Rymaszewski, E.J. (VanNostrand Reinhold, 1989) Chapter 9, p.673ff.Google Scholar
2. Murarka, S.P., Solid State Technol. (1986) p. 83; S-P. Jang, R.H. Havemann, and M.C. Chang, in Advanced Metallization for Devices and Circuits—Science, Technology, and Manufacturability, edited by S.P. Murarka, A. Katz, K.N. Tu, and K. Maex (Mater. Res. Soc. Symp. Proc. 337, (1994) Pittsburgh, 1994) p. 25; P. Singer, Semicond. Int. (May 1996) p. 88.Google Scholar
3. Brinker, D.J. and Scherrer, G.W., in Sol-Gel Science, The Physics and Chemistry of Sol-Gel Processing (Academic Press, New York, 1990).Google Scholar
4. Scherrer, G.W., J. Non-Cryst. Solids 87 (1986) p. 199.CrossRefGoogle Scholar
5. Manson, J.A. and Sperling, L.H., in Polymer Blends and Composites (Plenum Press, New York, 1976) p. 77ff.Google Scholar
6. Baney, R.H., Itoh, M., Sakakibara, A., and Suzuki, R., Chem. Rev. 95 (1995) p. 1409.Google Scholar
7. Voronkov, M.G. and Lavrent'yev, V.L., Topics in Current Chemistry 102 (1982) p. 199.Google Scholar
8. Chee, J.Y., Drage, J.S., Gupta, S., Hopkins, R., and Wiesner, J., in Proc. VIMC Conf. (1993) p. 28; N.P. Hacker, J.S. Drage, R. Katsanes, and P. Sebakar, in Proc. VIMC Conf. (1995) p. 138; M.Z. Karim and D.R. Evans, in Proc. DUMIC Conf. (1996) p. 63.Google Scholar
9. Matsui, F., Kobunski Kato 39 (1990) p. 299.Google Scholar
10. Chujo, Y. and Saegusa, T., Adv. Polym. Sci. 100 (1991) p. 12; J. Wen and G.L. Wilkes, Chem. Mater. 8 (1996) p. 667; L. Mascia, Trends Polym. Sci. 3 (2) (1995) p. 61.Google Scholar
11. Novak, B.M., Adv. Mater. 5 (1993) p. 422.CrossRefGoogle Scholar
12. Soane, D.S. and Martynenko, Z., in Polymers in Microelectronics (Elsevier, Amsterdam, 1989) p. 153ff.Google Scholar
13. Spinu, M., Brennan, A., Rancourt, J., Wilkes, G.L., and McGrath, J.E., Mater. Res. Soc. Symp. Proc. 175 (1990) p. 179; M. Nandi, J.A. Conklin, L. Salvati, Jr., and A. Sen, Chem. Mater. 2 (1990) p. 772; A. Morikawa, Y. Iyoku, M. Kakimoto, and Y. Imai, J. Mater. Chem. 2 (7) (1992) p. 679.CrossRefGoogle Scholar
14. Volksen, W., in Advances in Polymer Science, vol. 117, edited by Hergenrother, P.M. (Springer-Verlag, New York, 1994) p. 111.Google Scholar
15. Maruyama, Y., Oishi, Y., Kakimoto, M., and Imai, Y., Macromolecules 21 (1988) p. 2305.CrossRefGoogle Scholar
16. Srinivasan, S., Twieg, R., Hedrick, J.L., and Hawker, C.J., Macromolecules 29 (1996) p. 8543.Google Scholar
17. Hedrick, J.L., Srinivasan, S., Cha, H-J., Yoon, D.Y., Flores, V., Harbison, M., DiPietro, R., Hinsberg, W., Deline, V., Brown, H.R., Sherwood, M., Paulson, E., Miller, R.D., Cook, R., Liniger, E.G., Simonyi, E., Klaus, D., Cohen, S., and Hummel, J., Proc. Mater. Res. Soc., in press; J.L. Hedrick, H-J. Cha, R.D. Miller, D.Y. Yoon, H.R. Brown, S. Srinivasan, R. DiPietro, J.P. Hummel, D.P. Klaus, E.G. Liniger, and E.E. Simonyi, Macromolecules in press.Google Scholar