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Shallow Junction Formation by the Redistribution of Species Implanted into Cobalt Silicide

Published online by Cambridge University Press:  28 February 2011

Brian M. Ditchek ,
Marvin Tabasky Marvin Tabasky  and
Emel S. Bulat
Brian M. Ditchek
Affiliation:
Gte Laboratories Incorporated40 Sylvan Road, Waltham, MA 02254
Marvin Tabasky Marvin Tabasky
Affiliation:
Gte Laboratories Incorporated40 Sylvan Road, Waltham, MA 02254
Emel S. Bulat
Affiliation:
Gte Laboratories Incorporated40 Sylvan Road, Waltham, MA 02254
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Interest in CoSi2 as a metallization for very large scale integrated circuits (VLSI) has grown rapidly since the recent demonstration of a simple self-aligned process performed by rapid thermal annealing.1-4 Using a rapid thermal anneal (RTA) to directly silicide Co on Si yields smooth low-sheet-resistance films with little or no lateral diffusion and low contact resistance. In addition, it has been shown that rapid thermal annealing can result in reasonable quality epitaxial CoSi2 on (111) Si wafers.5 An important advantage of CoSi2 over the more commonly used TiSi2 metallization is the relative simplicity of its self-aligned silicidation process. Due to the low reactivity of Co with SiO2, a simple two-step self-alignment process is possible instead of the three-step process necessary with TiSi2.6 The primary disadvantage of CoSi2 is the amount of Si consumed for equal silicide sheet resistance. For example, to yield a silicide sheet resistance of 1.5 1/LD, Van den Hove 4 finds that compared to the TiSi, process, the CoSi, process would consume an additional 24 nm of Si. (This disadvantage can be minimized if very shallow junctions can be formed under the CoSi2.)

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 92: Symposium B – Rapid Thermal Processing of Electronic Materials , 1987 , 199
Copyright
Copyright © Materials Research Society 1987

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References

REFERENCES

1. Tabasky, M., Bulat, E.S., Ditchek, B.M., Sullivan, M.A., and Shates, S., in Rapid Thermal Annealing, VoL 52, Materials Research Society, eds. Sedgwick, T.O., Seidel, T.E., and Tsaur, B.-Y., p. 271 (1985).Google Scholar
2. Van den Hove, L., Wolters, R., Maex, K., Dekeersmaecker, R., and Declerck, G., J. Vac.Sci. Techno., B4 (6), 1358 (1986).Google Scholar
3. Tabasky, M., Bulat, E.S., Ditchek, B.M., Sullivan, M.A., and Shatas, S., IEEE Trans. Electron. ED-34, 548 (1987).Google Scholar
4. Van den Hove, L., Wolters, R., Maex, K., Dekeersmaeker, R.,and Declerck, G., IEEE Trans.Electron. Dev., Ed-34, 554 (1987).Google Scholar
5. Chevallier, J. and Larsen, A.N., Appl. Phys. A, 39, 141 (1986).Google Scholar
6. Haken, R.A., “Coevaporated and Self Aligned Titanium Disilicide Films for Low Resistivity Gates and Interconnects,” Workshop on Refractory Metal Silicides, San Juan Baptista, California (September 1983).Google Scholar
7. Agamy, S.A., Ho., V.Q. and Naguib, H.M., J. Vac. Sci. Technol. A(3) 718 (1985).Google Scholar
8. Nicolet, M.A. and Lau, S.S., in VLSI Electronics, edited by Einspruch, N.G. and Larrabee, G.B. (Academic Press, N.Y.), p. 330 (1983).Google Scholar