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IN SITU Tem Study of Electron Beam Stimulated Organization of Three-Dimensional Void Superlattice in Caf2

Published online by Cambridge University Press:  01 February 2011

T. H. Ding
Affiliation:
Department of Nuclear Engineering & Radiological Sciences
S. Zhu
Affiliation:
Department of Nuclear Engineering & Radiological Sciences
L. M. Wang
Affiliation:
Department of Nuclear Engineering & Radiological Sciences Department of Geological Science Department of Materials Science and Engineering, University of Michigan, Ann Arbor, MI 48109–2104, [email protected]
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Abstract

CaF2 is widely adopted as deep-UV window material and thin film optical coating. It has been known that ordered defect superlattices may form in electron irradiated CaF2.[1] However, the nature of the defects on the superlattice point (i.e., Ca colloids or voids) has not been certain and the self-organization mechanism has not been fully understood. In this study, single crystal CaF2 were irradiated under 200 keV electron beam at room temperature with in situ TEM observation of the dynamic process of defect ordering. The superlattice reached steady state after an electron dose of 1×1021e-/cm2 with void radius about 5 nm. Videos recorded during the in-situ observation reveal the dynamic self-organization process of the void superlattice. Coalescence was prevalent at the initial stages. Migration and preferential growth were dominant at the final stages of the superlattice formation. At a dose higher than 3×1021 e-/cm2 the superlattice structure was destroyed. These critical doses of void superlattice formation and deformation seem to be independent of dose rate. The anisotropic diffusivity of the migrating “molecules” may explain the superlattice formation.

Type
Research Article
Copyright
Copyright © Materials Research Society 2005

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References

REFERENCES

1. Johnson, E. and Chadderton, L.T., Anion Voidage and the Void Superlattice in Electron-Irradiated CaF2 . Radiation Effects and Defects in Solids, 1983. 79(1–4): p. 183233.Google Scholar
2. Evans, J.H., Observations of a Regular Void Array in High Purity Molybdenum Irradiated with 2 Mev Nitrogen Ions. Nature, 1971. 229(5284): p. 403404.Google Scholar
3. Jager, W. and Trinkaus, H., Defect Ordering in Metals under Irradiation. Journal of Nuclear Materials, 1993. 205: p. 394410.Google Scholar
4. Fisher, S.B.W., K.R., , Void Spatial Regularity in an Electron-Irradiated Stainless Steel. Radiation Effects, 1977. 32: p. 123124.Google Scholar
5. Stiegler, J.O. and Farrell, K., Alignment of Dislocation Loops in Irradiated Metals. Scripta Metallurgica, 1974. 8(6): p. 651655.Google Scholar
6. Jager, W., Ehrhart, P., and Schilling, W., Microstructural Evolution in Metals During Helium and Proton Irradiations. Radiation Effects and Defects in Solids, 1990. 113(1–3): p. 201211.Google Scholar
7. Ghoniem, N.M., Walgraef, D., and Zinkle, S.J., Theory and experiment of nanostructure self-organization in irradiated materials. Journal of Computer-Aided Materials Design, 2001. 8(1): p. 138.Google Scholar
8. Evans, T., Decomposition of Calcium Fluoride and Strontium Fluoride in Electron Microscope. Philosophical Magazine, 1963. 8(91): p. 12351240.Google Scholar
9. Murr, L.E., Transmission Electron-Microscope Study of Crystal Defects in Natural Fluorite. Physica Status Solidi a-Applied Research, 1974. 22(1): p.239251.Google Scholar
10. Murr, L.E., Ordered Lattice-Defects in Colored Fluorite - Direct Observations. Science, 1974. 183(4121): p. 206208.Google Scholar
11. Murr, L.E. Diffraction Studies of Real Atoms and Real Crystals. in Proceeding of International Crystallography Conference. 1974: Melbourne.Google Scholar
12. Chadderton, L.T., Johnson, E., and Wohlenberg, T., Mechanism for Formation of an Ordered Void Array on Anion Sublattice in Fluorite. Radiation Effects and Defects in Solids, 1976. 28(1–2): p. 111112.Google Scholar
13. Chadderton, L.T., Johnson, E., and Wohlenberg, T., Observations of a Regular Void Array in Natural Fluorite Irradiated with 100 Kev Electrons. Physica Scripta, 1976. 13(2): p. 127128.Google Scholar
14. Bennewitz, R, Smith, D, and M, R., Bulk and surface processes in low-energy-electron-induced decomposition of CaF2 . PHYSICAL REVIEW B, 1999. 59(12): p. 82378246.Google Scholar
15. Foreman, J.A.E., AERE Harwell Report.Google Scholar