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Quantitative Microanalysis of Fine Precipitates in Microalloyed Steels

Published online by Cambridge University Press:  25 February 2011

Joseph R. Michael
Joseph R. Michael*
Affiliation:
Bethlehem Steel Corporation, Research Department, Bethlehem, PA
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Abstract

Matrix and grain boundary precipitation in austenite has been studied in two Nb/V microalloyed steels with different V levels, which were given a number of different heat treatments after hot deformation. The steel with a higher V level was found to have a greater number of fine carbonitride precipitates in the matrix. In both steels, the precipitates became more Nb-rich as the aging temperature was increased from 854°C to 1066°C. For a given steel and heat treatment, the matrix precipitates were generally more Nb-rich than the grain boundary precipitates.

Type
Articles
Information
MRS Online Proceedings Library (OPL) , Volume 62: Symposium Q – Materials Problem Solving with the Transmission Electron Microscope , 1985 , 263
Copyright
Copyright © Materials Research Society 1986

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References

1. Hansen, S.S., Sande, J.B. Vander, Cohen, M., Metall. Trans. A., 11A, 387 (1980).Google Scholar
2. Crooks, M.J., Garratt-Reed, A.J., Sande, J.B. Vander, and Owen, W.S., Metall. Trans. A., 12A, 1999 (1981).Google Scholar
3. Mehta, S., Speer, J.G., and Hansen, S.S., in Analytical Electron Microscopy/1984, edited by Williams, D.B. and Joy, D.C. (San Francisco Press, San Francisco, 1984), p. 173.Google Scholar
4. Speer, J.G., Homer Research Laboratory, Report No. R507-E1-B047, 1985.Google Scholar
5. Baker, T.N. and Duckworth, S.D., in Quantitative Microanalysis with High Spatial Resolution, edited by Lorimer, G.W., Jacobs, M.H., and Doig, P. (The Metals Society, London, 1981), p. 73.Google Scholar
6. Garratt-Reed, A.J., in Quantitative Microanalysis with High Spatial Resolution, edited by Lorimer, G.W., Jacobs, M.H., and Doig, P. (The Metals Society, London, 1981), p. 165.Google Scholar
7. Weatherly, G.C., Houghton, D.C., and Ottensmeyer, F.P., in Analytical Electron Microscopy/1984, edited by Williams, D.B. and Joy, D.C. (San Francisco Press, San Francisco, 1984), p. 252.Google Scholar
8. Irvine, K.J., Pickering, F.B., and Gladman, T., J. Iron and Steel Inst., 205, 161 (1967).Google Scholar
9. Kenik, E.A. and Maziasz, P.J., in Analytical Electron Microscopy/1984, edited by Williams, D.B. and Joy, D.C. (San Francisco Press, San Francisco, 1984), p. 231.Google Scholar
10. Cliff, G. and Lorimer, G.W., J. Micros., 103, 203 (1975).Google Scholar
11. Williams, D.B., Newbury, D.E., Goldstein, J.I. and Fiori, C.E., J. Micros., 136, 209 (1984).Google Scholar
12. Zaluzec, N.J., in Analytical Electron Microscopy 1984, edited by Williams, D.B. and Joy, D.C. (San Francisco Press, San Francisco (1984), p. 279.Google Scholar
13. Williams, D.B., Practical Analytical Electron Microscopy in Materials Science, (Philips Electronic Instruments, Inc., Mahwah, New Jersey, 1984), p. 7582.Google Scholar
14. Wood, J.E., Williams, D.B., and Goldstein, J.I., J. Micros., 133, 255 (1984).Google Scholar
15. Duckworth, S.P. and Baker, T.N., in Analytical Electron Microscopy/1984, edited by Williams, D.B. and Joy, D.C. (San Francisco Press, San Francisco, 1984), p. 239.Google Scholar
16. Leslie, W.C., Rickett, R.L., Dotson, C.L., and Walton, C.S., Trans. ASM, 46, 1470 (1954).Google Scholar
17. Vodopivec, F., Metals Technology, 8, 151 (1974).Google Scholar