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Rapid Thermal Chemical Vapor Formation of TiSi2: An alternative refractory metallization process for device fabrication

Published online by Cambridge University Press:  15 February 2011

D. B. Gladden ,
X. Ren ,
C. E. Weintraub  and
M. C. Öztürk
D. B. Gladden
Affiliation:
Department of Materials Science & Engineering, North Carolina State University, Raleigh, NC 27695-7907
X. Ren
Affiliation:
Department of Electrical and Computer Engineering, North Carolina State University, Raleigh, NC 27695-7907
C. E. Weintraub
Affiliation:
Department of Electrical and Computer Engineering, North Carolina State University, Raleigh, NC 27695-7907
M. C. Öztürk
Affiliation:
Department of Electrical and Computer Engineering, North Carolina State University, Raleigh, NC 27695-7907
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Abstract

Scaling of MOSFETs into the deep submicron regime requires novel metallization schemes to form low resistivity contacts on ultra-shallow junctions. In this paper, we present our recent results on rapid thermal chemical vapor formation (RTCVF) of TiSi2. In this process, the gaseous Ti source, TiCl4 (g), reacts with solid Si to form C54 TiSi2(s) at temperatures as low as 700°C with a resistivity of 15-20μΩ-cm without a follow-up anneal. In this paper, we explore the previously reported barrier for nucleation of TiSi2 on Si at temperatures below 800°C. Without proper surface preparation, this barrier results in an incubation time which can vary according to the conditions of the surface and the deposition environment. We show that contrary to general belief, surface morphology instead of surface cleanliness is the most likely contributor to this barrier. We also show that if in-situ deposition of a Si-Ge layer precedes TiSi2 formation, the incubation time can be completely eliminated. Experiments performed in a temperature range of 650°C - 800°C indicate an approximate activation energy of 100 kJ/mol. The process provides excellent selectivity to both SiO2 and Si3N4 and little growth rate dependence on patterns in the 2 μm - 200 μm regime.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 427: Symposium K – Advanced Metallization for Future ULSI , 1996 , 523
Copyright
Copyright © Materials Research Society 1996

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References

1 Taur, Y., Sum, Y.Y., Moy, D., Wang, L.K., Davari, B., Klepner, S. P. and Ting, C., IEEE Trans Electron Dev., ED–34, p.575 (1987)Google Scholar
2 Ilderem, V. and Reif, R., Journal of the Electrochemical Society, 135, (1988)Google Scholar
3 Oztiirk, M.C., Thin Film Deposition, Rapid Thermal Processing Sci. & Tech., Academic Press (1993)Google Scholar
4 Gladden, D. B., Weintraub, C.E., and Öztürk, M. C. Proceedings of the Materials Research Society Symposium on Silicide Thin Films-Fabrication, Properties, and Applications, 402 1995, pp. 295300. Boston, MA.Google Scholar
5 Pfiester, J. R., Sivan, R., Liaw, H.N., and Seelbach, C.A., IEEE: Electron Device Letters, v11 1990, p. 365 Google Scholar
6 Westberg, H., Boman, M., and Carlsson, J.O., Journal De Physique IV, v3 1993.Google Scholar
7 Ilderem, V. & Reif, R., Applied Physics Letters, v53 1988, pp. 687689 Google Scholar
8 Kunii, Y. and Sakakibara, Y., Japanese Journal of Applied Physics, v26 1987, pp. L1816–L1822Google Scholar
9 Saito, K. et al., Japanese Journal of Applied Physics, v29 1990, pp. L185–L187Google Scholar
10 Maury, D., Regolini, J., and Gayet, P. Proceedings of the Materials Research Society Symposium on Silicide Thin Films-Fabrication, Properties, and Applications, v402, pp. 283294. Boston, MA.Google Scholar
11 Seebaur, E.G., Proceedings of the Materials Research Society Symposium on Silicide Thin Films-Fabrication, Properties, and Applications, 402 1995. Boston, MA.Google Scholar
12 Outokumpu HSC Chemistry for Windows, v2.0. Outokumpu Research, Finland.Google Scholar
13 Ren, X., Doctoral Thesis, North Carolina State University, (1995).Google Scholar
14 Ren, X., Gladden, D. B., Batchelor, D., and Öztürk, M. C. Proceedings of the Materials Research Society Symposium on Rapid Thermal and Integrated Processing, 387 p.443, April 1995.. San Francisco, CA.Google Scholar
15 Liehr, et. al., Journal Vacuum Science and Technology A, 8 1990, pp. 2960–2864.Google Scholar
16 Sanganeria, M., Öztürk, M. C., Harris, G., Violette, K., Ban, I., Lee, A., and Maher, D., Journal of Electrochemical Society, v142 1995, pp. 3961–69.Google Scholar