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THERMAL, STABILITY OF W/C MULTILAYER FILMS

Published online by Cambridge University Press:  28 February 2011

Yasuo Takagi ,
David A. Pawlik ,
Alan M. Kadin ,
Steven A. Flessa ,
Keith L. Hart ,
John E. Keem  and
John E. Tyler
Yasuo Takagi
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
David A. Pawlik
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
Alan M. Kadin
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
Steven A. Flessa
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
Keith L. Hart
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
John E. Keem
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
John E. Tyler
Affiliation:
Ovonic Synthetic Materials Company, A Division of Energy Conversion Devices, Incorporated, 1788 Northwood Drive, Troy, Michigan 48084
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Abstract

Arstract:

W(15 Å)/C(15 Å), W(50 Å)/C(50 Å) and W(100 Å)/C(100 Å) periodic multilaver films were prepared by magnetron sputtering and suhsequently annealed at 980, 730 and 500°C. The changes of layered and crystal structures were studied by x-ray diffraction. The results depended largely on the thickness of W layers and their initial crystal struictures of W. The kinds of transformations are classified into two types: one is the non-reacting type in the case of multilayers having the thinner W layers like W(15 Å)/C(15 Å), in which the crystallization of W layers prevails over the reactions between W and C layers; the other, the reacting type in the multilayers having thicker W layers like W(50 Å)/C(50 Å) and W(100 Å)/C(100 Å), in which reactions Prevail over crystallization. A tentative model in which the effective reaction rate between amorphous–W and amornhous–C is much smaller than that of crystalline-W(beta phase) and amorphous-C is proposed to explain the origin of the phenomena.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 56: Symposium H – Layered Structures and Epitaxy , 1985 , 441
Copyright
Copyright © Materials Research Society 1986

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References

Reffrences

1.A.L. rreer and F. Spaepen, in Synthetic Modulated Structures, ed. by L.L. Chang and 9.C. Giessen (Academic Press, Orlando, 19R5), p. 410.Google Scholar
2.P.L. Johnson, et at., in Proc. of 5th Int. Conf. on Rapidly Ouenched Metals, Vol. IT, ed. by S. Steeb and F. Warlimont (Nortb-Polland Physics Puhlishing, Amsterdam, 195), P. 1515.Google Scholar
3.Y. Takagi, et at., in Proc. of SPIE Vol. 563, Anplications of Thin-Film Multilayered Structures to Figured X-Ray Optics, Ed. by C.F. “Marshall,(SPIE, Rellingham, Washington 1985), n. 66.Google Scholar
4.Powder Diffraction File, (American Society for Testing and Materials, Philadelphia), W(a) (4-0806), 17( B ) (2-1138) (cited as W30?), W2C (20-1315), WC (25-1047) and WClx (20-1316).Google Scholar