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Comparison of TEM Observations with Dislocation Core Structure Calcuiations in B2 Ordered Compounds

Published online by Cambridge University Press:  26 February 2011

D. Farkas ,
R. Pasianot ,
E. J. Savino  and
D.B. Miracle
D. Farkas
Affiliation:
Department of Materials Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA. 24061.
R. Pasianot
Affiliation:
Department of Materials Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA. 24061.
E. J. Savino
Affiliation:
Department of Materials Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA. 24061.
D.B. Miracle
Affiliation:
Wright Patterson AFB Dayton, OH 45433
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Abstract

Dislocation core structures have been calculated using atomistic computer simulations in NiAl and other B2 compounds. In the present work the calculated dislocation core structure are correlated with the known deforniatiorn behavior of B2 alloys. It is found that for the high ordering energy compounds <111> dislocations do not split in the simulations, in agreement with the experimental observations. It is also found that core structures for certain <111> and 1/2 <111> dislocations are spread in { 112} planes, which is consistent with the slip plane often reported for these dislocations. For the < 100> dislocations several orientations of the dislocation line produce sessile core configurations, whereas other orientations produce relatively more glissile cores. However, a structural transition of each of these dislocation cores may be required before < 100> dislocations become mobile, and this is consistent with the limited tensile ductility observed in NiAl “soft” single crystals below 200°C. Core structure simulations for < 110> dislocations are also reported and are discussed with respect to the importance of these dislocations in the deformation of NiAl.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 213: Symposium Q – High-Temperature Ordered Intermetallic Alloys IV , 1990 , 223
Copyright
Copyright © Materials Research Society 1991

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References

REFERENCES

1. Vitek, V., Crystal Lattice Defects, 5, 1 (1974).Google Scholar
1a. A41(4), 541, (1980).Google Scholar
2. Paidar, V., Pope, D.P. and Vitek, V., Acta Metall. 32(3), 435, (1984).Google Scholar
3. Rachinger, W. A. and Cottreli, A.H.,Acta Meall. 4 109 (1956).Google Scholar
4. Umakoshi, Y., Yamaguchi, M., Acta Metall. 24, 89, (1976)Google Scholar
4a. Scripta Metall. 11, 211, (1977).Google Scholar
5. Crawford, R. C., Phil. Mag., 35, 567 (1977).Google Scholar
6. Mendirata, M. G., Kim, H. M., Lipsitt, H. A., Metall. Trans. A(15), 395, (1984).Google Scholar
7. Umakoshi, Y. and Yamaguchi, M., Phil. Mag., A 44, 711 (1981).Google Scholar
8. Bragg, W. L. and Williams, E. J., Proc. Roy. Soc., A 151, 540 (1935).Google Scholar
9. Flinn, P. A., Trans. AIME, 218, 145 (1960).Google Scholar
10. Darolia, R., Field, R. and Lahrman, D., Alloy Modelling and Experimcntal Correlation for ductility Enhancement in Near Stoichiometric Single Crystal Nickle Aluminide, Annual Report, AFOSR Contract F49620- 88-C-0052, (1989).Google Scholar
11. Loretto, M. H. and Wasilewski, R. J., Phil. Mag. 23, 1311 (1971).Google Scholar
12. Ball, A., Smallman, R.E., Acta Met. 14, 1517 (1966).CrossRefGoogle Scholar
13. Voter, A. F., Chen, S. P., MRS Syrup. Proc. 82, 175, (1987).CrossRefGoogle Scholar
14. Pasianot, R., Farkas, D., MRS Symp. Proc. ,San Francisco, 1990.Google Scholar
15. Pasianot, R., Farkas, D., Savino, E.J., Scripta Met. et Mater. 24, 1669 (1990)Google Scholar
16. Munroe, P. R., Baker, I., Scripta Metall. 23,495, (1989).CrossRefGoogle Scholar
17. Bowman, R., Noebe, R. and Darolia, R., NASA Conference Pub. 1989.Google Scholar
18. Pascoe, R. T. and Newey, C. W. A., Metal Sci. J., 2, 138 (1968).CrossRefGoogle Scholar
19. Potter, D. I., Mater. Sci. Eng., 5, 201 (1969/1970).Google Scholar
20. Wasilewski, N. J., Butler, S. R. and Hanlon, J. E., Trans. AIME. H, 239, 1357 (1967).Google Scholar
21. Field, R. D., These proceedings (1990).Google Scholar
22. Zaluzec, N. J. and Fraser, H. L., Scripta Metall., 8, 1049 (1974).CrossRefGoogle Scholar
23. Baker, I. and Schulson, E. M., Metall. Trans., 15A, 1129 (1984).Google Scholar
24. Lloyd, C.H., Loretto, M.H., Phys. Stat. Sol. 39, 163 (1970).Google Scholar
25. Lasalmonie, A., Journ. Mat. Scie. 17, 2419 (1982).CrossRefGoogle Scholar
26. Miracle, D. B., Ph.D. Thesis, Ohio State University, 1990.Google Scholar
27. Pascoe, R.T., Newey, C.A.N., Phys. Stat. Sol. 29, 357 (1968).Google Scholar
28. Bevk, J., Dodd, R.A., Strutt, P.R.S., Metall. Trans. 14, 159 (1973).Google Scholar