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Specific Effects of the Displacement Cascades on the Kinetics of Precipitation of Copper in Iron

Published online by Cambridge University Press:  15 February 2011

A. Barbu ,
D. Lesueur  and
J. Dural
A. Barbu
Affiliation:
SESI / CEA-CNRS – Ecole Polytechnique Palaiseau France
D. Lesueur
Affiliation:
SESI / CEA-CNRS – Ecole Polytechnique Palaiseau France
J. Dural
Affiliation:
CIRIL / CEA – CNRS Caen France
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Abstact

In order to probe the possibility of simulating irradiation effects with swift ions and obtaining some insight about the production rate of freely migrating defects in iron, we studied the kinetics of copper precipitation in FeCu1.34at% irradiated at 300°C with 202 MeV O- ions and 2.5 MeV electrons. The precipitation kinetics are studied in situ (GANIL for O- ions and Van de Graaff for electrons) by measuring the electrical resistivity at 30°C to reduce the phonon component. We found that, in both cases, the resistivity versus fluence (in dpa) curves are identical. This would imply either that the relatively small cascades induced by 202 MeV O- ions (compared with those produced by neutrons) are very efficient in producing freely migrating point defects or that the energy deposition by electronic excitations plays an important role. We show that this latter possibility is not relevant for 202 MeV O18 ions.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 439: Symposium B – Microstructure Evolution During Irradiation , 1996 , 503
Copyright
Copyright © Materials Research Society 1997

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References

1. Norgett, M. J., Robinson, M. T. and Torrens, I. M., Nucl. Eng. Des. 33 p. 50 (1974).Google Scholar
2. Naundorf, V., Macht, M. P. and Wollenberger, H., J. Nucl. Mat. 186 p. 227, 236 (1992)Google Scholar
3. Rehn, L. E., Okamoto, P. R. and Averback, R. S., Phys. Rev. B30, 6 p. 3073, 3080 (1984)Google Scholar
4. Lu, T.N., Barbu, A., Liu, D., Maury, F., Scripta Metall. et Mat., 26 p. 771 (1992)Google Scholar
5. Mathon, M.H., ”Etude de la précipitation et des mécanismes microscopiques de durcissement sous irradiation dans les alliages ferritiques dilués”. Ph. D thesis, University of Paris XI, France (1995).Google Scholar
6. Ziegler, J.F. and Biersack, J.P., ”The stopping power and range of ions in solid”., Pergamon press, New york (1985)Google Scholar
7. Oen, O.S., ”Cross-sections for atomic displacements in solids by fast electrons”, Report ORNL-4897 (1973).Google Scholar
8. Calder, A. F. and Bacon, D. J. J. Nucl. Mat. 207 p. 2545 (1993)Google Scholar
9. Dunlop, A., Lesueur, D., Legrand, P., Dammak, H. and Dural, J., Nucl. Instr. and Meth. B 90 p. 330338 (1994)Google Scholar