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Irradiation Effects in some Crystalline Ceramics*

Published online by Cambridge University Press:  06 March 2019

W. V. Cummings*
Affiliation:
General Electric Company Vallecitos Nuclear Center Pleasanton, California
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Abstract

Irradiation effects that have been observed in the structures of a number of ceramic materials are reviewed. Results of X-ray diffraction studies indicate that, to a great extent, the magnitudes of the crystallographic changes depend upon the type of crystal structure. However, the nature of the atomic bonding and the type of radiation can be the predominant factor in radiation stability in some materials. Damage mechanisms that have been investigated include: (1) fast-neutron and high-energy garnma-ray effects, (2) transmutation effects in high-neutron crosssection materials, and (3) lire effects of the (n, α) reaction in various bolide-containing structures. Some crystallographic changes observed include lattice parameter changes and structure damage of various magnitudes, the appearance of a transmutat. on product structure, and changes from the crystalline to the amorphous state.

Type
Research Article
Copyright
Copyright © International Centre for Diffraction Data 1967

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Footnotes

*

A portion of this work was supported by the U.S. AEC, Contract No. AT(04-3)-189, Project Agreement No. 4.

References

1. Seitz, F., “On the Disordering of Solids bv Action of Fast Massive Particles,” Discussions Faraday Soc. 5: 271, 1949.Google Scholar
2. Seitz, F., “Radiation Effects in Solids,” Phys. Today 5: 6, 1952.Google Scholar
3. Brinkman, J. A., “On the Nature of Radiation Damage in Metals,” J.Appl.Phys. 25: 961, 1954.Google Scholar
4. Seitz, F. and Koehler, J. S., “Displacement of Atoms During Irradiation,” in: F. Seitz and D. Turnbull (eds.), Solid State Physics, Vol. 2, Academic Press, New York, 1956, pp. 307442.Google Scholar
5. Dienes, G. J. and Vineyard, G. H., Radiation Effects in Solids, Interscience Publishers, Inc., New York, 1957.Google Scholar
6. Tucker, C. W. and Sampoon, J. B., “Interstitial Content of Radiation Damaged Metals from Precision X-Ray Lattice Parameter Measurements,” Knolls Atomic Power Laboratory 1037, Jan. 26, 1954.Google Scholar
7. Gray, D. L. and Cummings, W. V., “An X-Ray Diffraction Study of Irradiated Molybdenum,” Acta Met. 8: 446, 1960.Google Scholar
8. Tucker, C. W. and Senio, P., “X-Ray Scattering by Neutron Irradiated Single Crystals of Boron Carbide,'’ Acta Cryst. 7: 456, 1954.Google Scholar
9. Warren, B. E. and Averbach, B. L., “The Separation of Cold-Work Distortion and Particle Size Broadening in X-Ray Patterns,” J. Appi. Phys. 23: 496, 1952.Google Scholar
10. Hoyt, E. W. and Zimmerman, D. L., “Radiation Effects in Borides, Part I. Helium Release and Swelling in Irraciated Borides,” General Electric Atomic Power 3743, Feb. 13, 1962.Google Scholar
11. Samsonov, G. V., “Rare Earth Metal Borides,” Usp. Khim. 28: 189, 1959.Google Scholar