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X-Ray Diffraction of Nonmetallic Phases Chemically Extracted from Columbium Alloys

Published online by Cambridge University Press:  06 March 2019

David P. Laverty  and
Ralph H. Hiltz
David P. Laverty
Affiliation:
Thompson Ramo Wooldridge, Inc. Cleveland, Ohio
Ralph H. Hiltz
Affiliation:
Thompson Ramo Wooldridge, Inc. Cleveland, Ohio
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Abstract

The identification of non-metallic phases occurring in a metallic matrix cannot always be accomplished by standard methods of X-ray diffraction analysis. Separation of the nonmetallic phases from the matrix by chemical extraction, with subsequent X-ray diffraction analysis allows identification of the nonmetallic phases without the problems associated with X-ray analysis of bulk samples.

In one study of alloy carbide dispersions in columbium, X-ray diffraction of the bulk samples could adequately identify the carbides present, but it was only by studying the chemically extracted residues that an important oxygen gettering effect of one of the alloy additions was discovered. In another study, X-ray diffraction work on extraction residues of Cb-Zr alloys showed evidence of a double oxygen gettering effect producing two distinct oxides. In the built sample, some of the diffraction lines produced by one of these oxides were masked by the tines of the columbiurn matrix. Therefore, only by use of an extraction technique were these two oxides identifiable by X-ray diffraction. In a Cb–10Ti–10Mo alloy, X-ray diffraction was used to study the nature of the sub scale formed during oxidation of the alloy. At least two nonmetallic phases were found. By using chemical extraction techniques, the phase responsible for the formation of the subscale was identified as TiO.

These studies demonstrate some of the advantages of the chemical extraction techniques for obtaining samples of nonmetallic phases for study by X-ray diffraction.

Type
Research Article
Information
Advances in X-Ray Analysis , Volume 8: Thirteenth Annual Conference on Applications of X-ray Analysis, August 12-14, 1964 , 1964 , pp. 103 - 117
Copyright
Copyright © International Centre for Diffraction Data 1964

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References

1. Pochon, M. L., McKinsey, C. R., Perkins, R. A., and Foregang, W. D., “The Solubility of Carbon and Structure of Carbide Phases in Ta and Cb,” Proceedings of the Third Annual Reactive Metals Conference, Vol. II, Interscience Publishers, New York, May 1959, pp. 327-347.Google Scholar
2. Chang, W. H., “Effect of Carbide Dispersions in Molybdenum Alloys,” Trans. AIME 218: 254, 1960.Google Scholar
3. Campbell, I. E. (ed.), High Temperature Technology, John Wiley & Sons, Inc., New York, 1956, pp. 22123.Google Scholar
4. Hike, R. H., “The Effect of Gettering Additions to Columbium,” paper 145, J. Electron hem. Soc. 106:67c, March 1959.Google Scholar
5. Johnson, J. R., “Development of a Cubic Oxide Protective Film on Zirconium,” Trans. AIME 212:13-14, Feb. 1958.Google Scholar
6. Samsonov, G. V., “Intermediate Stages in the Formation of Carbides of Titanium, Zirconium, Vanadium, Niobium, and Tantalum,” Ukr. Khim. Zh. 23: 287, 1957.Google Scholar
7. Wyckoff, R. W. G., Crystal Structures, Vol. I, second edition, Interscience Pubs., Inc., New York, 1963.Google Scholar
8. Schoenburg, H., “The Structure of the Metallic Quaternary Phase ZrTaNO,” Acta Chem. Scand. 8: 627629, 1954.Google Scholar