High-frequency (94.9 GHz) EPR spectroscopy of paramagnetic centers in a neutron-irradiated sapphire single-crystal fiber

Initial results are reported of an EPR study, conducted at 94.9 GHz, of a thermally annealed, neutron-irradiated white sapphire (α-Al2O3) single-crystal fiber. The optical centers produced in sapphire by neutron irradiation and thermal annealing are of interest for optical technologies involving the...

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Bibliographic Details
Published in:Applied magnetic resonance 1999-02, Vol.16 (2), p.223-236
Main Authors: Schwartz, D. A, Walter, E. D, McIlwain, S. J, Krymov, V. N, Singel, D. J
Format: Article
Language:English
Subjects:
Aluminum oxide
Annealing
Color centers
Crystal defects
Crystal fibers
Crystallography
Neutron irradiation
Neutrons
Radiation effects
Sapphire
Sensitivity enhancement
Single crystals
Spectroscopy
Spectrum analysis
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Summary:Initial results are reported of an EPR study, conducted at 94.9 GHz, of a thermally annealed, neutron-irradiated white sapphire (α-Al2O3) single-crystal fiber. The optical centers produced in sapphire by neutron irradiation and thermal annealing are of interest for optical technologies involving the phenomenon of spectral hole-burning. While these centers have been modeled as consisting of electrons localized at anion vacancies, experimental tests of this model have been very limited. EPR spectroscopy — a choice technique for elucidating structural details of such color centers — reveals signals from numerous paramagnetic centers in this material. The predominant signals, with amplitudes a hundredfold greater than any other signals, derive from three closely related, highspin-multiplicity centers. These centers do not, however, derive from radiation-induced lattice defects: they are readily identified as Cr3+ (S = 3/2) and a pair of crystallographically equivalent Fe3+ (S=5/2) impurity ions. The advantages of high-frequency-EPR instrumentation in facilitating this identification are presented and discussed in detail. These advantages include enhanced sensitivity for this volume-limited, fiber sample. Moreover, the analysis of the spectra — entailing spectral assignments, evaluation of the spin-Hamiltonian parameters, and spin-counting — is greatly facilitated when the Zeeman interaction is dominant.
ISSN:0937-9347
1613-7507
DOI:10.1007/BF03161935