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Generation of a Two-Dimensional Silicon Carbide Lattice*

Published online by Cambridge University Press:  06 March 2019

R. L. Prickett  and
R. L. Hough
R. L. Prickett
Affiliation:
Air Force Materials Laboratory, Wright-Patterson Air Force Base, Ohio
R. L. Hough
Affiliation:
Air Force Materials Laboratory, Wright-Patterson Air Force Base, Ohio
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Abstract

Silicon carbide vvas generated by pyrolysis of gas mixtures consisting of silicon tetrachloride, hydrogen, and organic vapors, such as acetone, on fine tungsten wires resistance-heated at 1500°C. Prominent two-dimensional structure was demonstrated for the 220 reflection. All other lines were of the normal threedimensional lattice type.

Elevation of less than 100° in the pyrolysis temperature eliminated the twodimensional reflection, and simultaneously changed the visible crystallite size.

Specialized techniques were used td generate the silicon carbide deposits and also to examine the structure of these deposits by X-ray diffraction to obtain lines from only the silicon carbide while ignoring the tungsten wire core. Diffraction techniques include offset collimation and vertical integration.

Type
Research Article
Information
Advances in X-Ray Analysis , Volume 9: Fourteenth Annual Conference on Applications of X-ray Analysis, August 25-27, 1965 , 1965 , pp. 142 - 151
Copyright
Copyright © International Centre for Diffraction Data 1965

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Footnotes

*

All rights reserved by the U.S. Air Force, Air Force Materials Laboratory. This research was done at Wright-Patterson Air Force Base under Task numbers 735101 and 734003.

References

1. Frickett, R. L. and Mazdiyasni, K. S., “Offset Collimatson in Powder Photographs for Increasing Resolution in Unstable Low Symmetry Systems,” paper presented at the American Crystallographic Association meeting, July, 1964.Google Scholar
2. Prickett, R. L. and Mazdiyasni, K. S., “Offset Collimator for Use on X-Ray Powder Camera and Method for Increasing Resolution,” U.S. Air Force Invention No. 9743, U.S. Patent Serial No. 380, 959.Google Scholar
3. Prickett, R. L., “Structure Integrating Stress and General Purpose X-Ray Camera,” paper presented at the 21st Pittsburgh Diffraction Conference, November, 1963.Google Scholar
4. Prickett, R. L., Fenter, J., and Robinson, V., “Structure Integrating Stress and General Purpose X-Ray Camera; Combined Long Cylindrical, Laue and Stress Camera for Single Crystal and Orientation Studies with Integration U.S. Air Force Invention No. 9842, U.S. Patent Serial No. 406, 630.Google Scholar
5. Prickett, R. L. and Hough, R. L., “Vertical Integrating Attachment,” U.S. patent submitted.Google Scholar
6. Brindley, G. W., Robinson, K., and MacEwan, D. M. C., “The Clay Minerals Halloysite and Meta-halloystte,” Nature 157: 225226, 1946.Google Scholar
7. Guinier, A., “Structure of Age-Hardened Aluminium-Copper Alloys, “ Nature 142: 569570, 1938.Google Scholar
8. Hendricks, S. B., “Variable Structures and Continuous Scattering of X-rays from Layer Silicate Lattices,” Phys. Rev. 57: 448454, 1940.Google Scholar
9. Hendricks, S. B. and Teller, E., “X-Ray Interference in Partially Ordered Layer Lattices,” J. Chem. Phys. 10: 147167, 1942.Google Scholar
10. Hofmann, U. and Hausdorf, A., “The Crystal Structure and Intracrystal Swelling of Montmorillonite,” Z. Krist. 104: 265293, 1942.Google Scholar
11. Klug, H. P. and Alexander, L. E., “X-Ray Diffraction Procedures,” John Wiley & Sons, Inc., New York, 1954, p. 385.Google Scholar
12. Landau, L., “Scattering of X-Rays by Crystals with Variable Lamellar Structure,” Physika. Z. Sowjetunion 12: 579585, 1937.Google Scholar
13. Laue, M. V., “Cross-Lattice Spectra,” Z. Krist. 82: 127141, 1932.Google Scholar
14. Lifschits, I. M., “Scattering of X-Rays by Crystals of Variable Structure,” Physk. Z. Sowjetunion 12: 623643, 1937.Google Scholar
15. Maegdefrau, E. and Hofmann, U., “The Crystal Structure of Montmorillontte,” Z. Krist. 98: 299323, 1937.Google Scholar
16. Méring, J., “Interference of X-Rays in Systems with Disordered Stacking,” Acta Cryst. 2: 371377, 1949.Google Scholar
17. Méring, J. and Brindley, G. W., “Banded X-Ray Reflections from Clay Minerals,” Nature 161: 774, 1948.Google Scholar
18. Peiser, H. S., Rooksby, H. P., and Wilson, A. J. C., “X-ray Diffraction by Polycrystalline Materials,” The Institute of Physics (London), 1955, p, 418.Google Scholar
19. Preston, G. D., “Structure of Age-Hardened Aluminum-Copper Alloys,” Nature 142: 570, 1938.Google Scholar
20. Warren, B. E., “X-Ray Diffraction in Random Layer Lattices,” Phys. Rev. 59: 693698, 1941.Google Scholar
21. Wilson, A. J. C., “X-Ray Optics,” Methuen & Co., Ltd. (London), 1949.Google Scholar
22. Wilson, A. J. C., “X-Ray Diffraction by Random Layers: Ideal Line Profiles and Determination of Structure Amplitudes from Observed Line Profiles,” Acta Cryst. 2: 245, 1949.Google Scholar
23. Hough, R. L., “Method for the Pyrolytic Deposition of Silicon Carbide,” U.S. Air Force Invention No. 10, 114.Google Scholar
24. Thibault, N. W., “Morphological and Structural Crystallography and Optical Properties of Silicon Carbide (SiC),” Am. Mineralogist 29: 249278 and 327-362, 1944.Google Scholar