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Laser Induced Controlled Nucleation and Growth Process For Large Grained Polycrystalline Silicon*

Published online by Cambridge University Press:  15 February 2011

S.C. Danforth ,
F. Van Gieson ,
J.S. Haggerty  and
I. Kohatsu
S.C. Danforth
Affiliation:
Energy Laboratory and Department of Materials Science, Massachusetts Institute of Technology, Room 12–063, Cambridge, Massachusetts 02139
F. Van Gieson
Affiliation:
Energy Laboratory and Department of Materials Science, Massachusetts Institute of Technology, Room 12–063, Cambridge, Massachusetts 02139
J.S. Haggerty
Affiliation:
Energy Laboratory and Department of Materials Science, Massachusetts Institute of Technology, Room 12–063, Cambridge, Massachusetts 02139
I. Kohatsu
Affiliation:
Energy Laboratory and Department of Materials Science, Massachusetts Institute of Technology, Room 12–063, Cambridge, Massachusetts 02139
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Abstract

Research on a new process is described which utilized a laser to achieve controlled crystallization of amorphous Si thinfilms for photovoltaic applications. Amorphous Si films are deposited on suitable substrates using RF sputtering. A laser is used to inoculate these films with crystalline embryos at specific locations. These embryos should then grow in a controlled atmosphere annealing furnace under conditions optimized to maintain the nucleation rate at zero and the transformation rate (from amorphous to crystalline silicon) at a maximum value. The result will be a polycrystalline silicon film with a large grain size to film thickness ratio, where the ultimate grain size will be determined by the laser inoculation spacing.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1: Symposium – Laser and Electron-Beam Solid Interactions in Materials Processing , 1980 , 443
Copyright
Copyright © Materials Research Society 1981

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Footnotes

*

This research was conducted with the support of the U.S. Department of Energy, Grant No. DE-FG01-79ET-00081. However, any opinions, findings, conclusions, or recommendations expressed herein are those of the authors and do not necessarily reflect the views of DOE.

References

REFERENCES

1. Ghosh, A.K., Fishman, C., Feng, T.. “Theory of electrical and photovoltaic properties of polycrystalline silicon,” J. Appl. Phys., 51 (1), 446–54 (1980).Google Scholar
2. Mazey, D.J., Nelson, R.S., Barnes, R.S., “Observation of ion bombardment damage in silicon,” Philos. Mag., 17, 1145–61 (1968).CrossRefGoogle Scholar
3. Blum, N.A., Feldman, C., “The crystallization of amorphous silicon films,” J. Non Cryst. Solids, 11, 242–46 (1972).Google Scholar
4. Williams, J.S., Brown, W.L., Leamy, H.J., Poate, J.M., Rodgers, J.W., Rousseau, D., Rozgonyi, G.A., Shelnutt, J.A., Sheng, T.T., “Solid-phase pitaxy of implanted silicon by CW Ar ion laser irradiation,” Appl. Phys. Lett., 33 (6), 542–4, (1978).Google Scholar
5. Drosd, B., Washburn, J., “A new technique for observing the amorphous to crystalline transformation in thin surface layers on silicon wafers,” J. Appl. Phys., 51, (8), 4106–10, (1980).CrossRefGoogle Scholar
6. Booth, D.C., Allred, D.D., Seraphin, B.O., “Retarding crystallization of CVD amorphous silicon by alloying,” J. Non Cryst. Solids, 35–36, 213–18, (1980).Google Scholar
7. Kennedy, E.F., Csepregi, L., Mayer, J.W. “influence of 16O, 12C, 14N, and noble gases on the crystallization of amorphous Si layers,” J. Appl. Phys, 48 (10), 4241–46, (1977).Google Scholar
8. Janai, M., Allred, D.D., Booth, D.C., Seraphin, B.O., “Optical properties and structure of amorphous silicon films prepared by CVD,” Solar Energy Materials, 1, 1127, (1979).Google Scholar