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Nucleation And Growth Rates in Isothermal Crystallization OpAmorphous Si50Ge50 Films

Published online by Cambridge University Press:  15 February 2011

J. H. Song  and
James S. Im
J. H. Song
Affiliation:
Columbia University, Department of Chemical Engineering, Materials Science, and Mining Engineering, New York, NY
James S. Im
Affiliation:
Columbia University, Department of Chemical Engineering, Materials Science, and Mining Engineering, New York, NY
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Abstract

Isothermal crystallization behavior of as-deposited thin amorphous Si50Ge50 films (∼1000Å-thick) at 580°C has beeninvestigated using transmission electron Microscopy (TEM). The crystalcounting method was employed in order to obtain directly the two-dimensionalsteady-state crystal nucleation rate of 3.9×103#/cm2sec (equivalent volumetric nucleation rate of 3.4×108 #/cm3sec). The Modified two-dimensionalJohnson-Mehl-Avrami analysis, in which the growth rate of the crystals wasthe only adjustable parameter, and in which the time-dependent nucleationrate and the size effect associated with the onset of the observation areconsidered, was developed in order to extract the crystal growth rate of16.5 Å/sec. When compared to the crystallization of a-Si films, thesenucleation and growth rates confirm the observation that it is possible toachieve significantly faster crystallization at lower temperatures whileproducing substantially better Microstructures (i.e., > 5 μ grain-sized poly-Si50Ge50obtained within two hours at 580°C vs. 1–2Μm grain-sized poly-Si obtained inabout > 10 hours at 600°C).

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 321: Symposium E – Crystallization and Related Phenomena in Amorphous Materials—Ceramics, Metals, Polymers, and Semiconductors , 1993 , 307
Copyright
Copyright © Materials Research Society 1994

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References

REFERENCES

1. King, T.-J., Saraswat, K. C. and Pfiester, J. R., IEEE Elect Dev. Lett 12 (1991) 584.Google Scholar
2. King, T.-J., Pfiester, James R., Shott, John D., McVittie, James P., and Saraswat, Krishna C., IEEE DM, (1990) 253.Google Scholar
3. Iverson, R. B. and Reif, R., J.Appi Phys. 62 (1987) 1675.Google Scholar
4. Maenpaa, M. and Lau, S. S., Thin Solid Films 82 (1981) 343.Google Scholar
5. Maenpaa, M., Hung, L. S., Grimaldi, M. G., Suni, I., Mayer, J. W., Nicolet, M.-A., and Lau, S. S., Thin Solid Films 82 (1981) 347.Google Scholar
6. Swalin, R. A., Thermodynamics of Solids, (New York: Wiley, 2nd edition, 1972).Google Scholar
7. Reiss, H., J. Chem Phys. 18, 840 (1950).Google Scholar
8. Russell, K. C, Acta metall 16, 761 (1968).Google Scholar
9. Greer, A. L., Evans, P. V., Hamerton, R. G., Shangguan, D. K., and Kelton, K. F. J.Cryst. Growth 99, 38 (1990).Google Scholar
10. Kelton, K. F. and Greer, A. L., J. Non-Cryst Solids 79, 295309 (1986).Google Scholar
11. Turnbull, D., Metals Technobgy, Technical Publication 2365 (1948).Google Scholar
12. Christian, J. W., The Theory of Transformations in metals and Alloys, second edition, (Oxford: Pergamon Press, 1975).Google Scholar