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Intergranular Fracture in Neutron Irradiated Vanadium-20 Wt.% Titanium Alloys Undoped and Doped with Phosphorus

Published online by Cambridge University Press:  10 February 2011

J. Kameda ,
T. E. Bloomer  and
D. Y. Lyu
J. Kameda
Affiliation:
Ames Laboratory, Iowa State University, Ames, IA 50011
T. E. Bloomer
Affiliation:
Ames Laboratory, Iowa State University, Ames, IA 50011
D. Y. Lyu
Affiliation:
Department of Die and Mold Design, Chonju Technical College, Chonju 560–760, Korea
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Abstract

This paper presents the effect of neutron irradiation (9.8 × 1024 n/m2 at 438 °C) on the mechanical properties in V-20 wt.% Ti alloys undoped and doped with P using a small punch testing method. The same amount of neutron irradiation-induced hardening, that is almost temperature independent, was observed in undoped and P doped alloys. Neutron irradiation facilitated heterogeneous formation of grain boundary microcracks, not leading to specimen failure, in the undoped alloy. An irradiated undoped alloy showed ductility loss, that is not as much as expected from the easy microcrack formation due to a mixed mode of intergranular and transgranular cracking. Conversely, in the P doped alloy, intergranular microcracking was suppressed and low temperature ductility was improved by the irradiation. The intergranular fracture behavior controlling the ductility change is discussed in terms of the grain boundary composition and yield strength affected by the neutron irradiation.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 458: Symposium W – Interfacial Engineering for Optimized Properties , 1996 , 283
Copyright
Copyright © Materials Research Society 1997

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References

REFERENCES

1. Harris, D.R., Buttermore, G. J., Hishinuma, A. and Wiffen, F. W., J. Nucl. Mater. 191, 92 (1992).Google Scholar
2. Harrod, D. L. and Gold, R. E., Inter Metals Rev. 4, 163 (1980).Google Scholar
3. Diercks, D. R. and Loomis, B. A., J. Nucl. Mater. 141–143, 1117 (1987).Google Scholar
4. Owen, C. V., Spitzig, W. A. and Bevolo, A. J., Mater. Sci. Eng. AHO, 69 (1989).Google Scholar
5. Li, H., Hamilton, M. L. and Jones, R. H., Scripta Metall, et Mater. 33, 1063 (1995).Google Scholar
6. Lyu, D. Y., Bloomer, T. E., Ünal, Ö. and Kameda, J., Scripta Mater 33, 317 (1996).Google Scholar
7. Lyu, D. Y., Bloomer, T. E., Swanson, A. H. and Kameda, J., submitted to J. Nucl. Mater‥Google Scholar
8. Baik, J. M., Kameda, J. and Buck, O., Scripta Metall. 17, 1443 (1983).Google Scholar
9. Mao, X. and Takahashi, H., J. Nucl. Mater. 150, 42 (1987).Google Scholar
10. Kameda, J. and Mao, X., J. Mater. Sci. 27, 983 (1992).Google Scholar
11. Bloomer, T. E., Lyu, D. Y. and Kameda, J., Microstructure Evolution During Irradiation, edited by Diaz de la Rubia, T. et al. (MRS, Pittsburgh, 1996) to be presented.Google Scholar
12. Messemer, R. P. and Briant, C. L., Acta Metali. 30, 457 (1982).Google Scholar
13. Abiko, K., Suzuki, S. and Kimura, H., Trans. Japan Inst. Metals, 23, 43 (1982) 11Google Scholar