Abstract
Persistent spectral hole burning has been utilized as both a tool for studying relaxation processes in amorphous solids1 and a means for possibly achieving high density frequency domain optical storage.2 In photon-gated hole burning, two photons (ideally of different wavelengths) are required to induce the photochemical reaction leading to hole formation. In effect, the first photon produces the site selection, and the second photon acts as a gate on the photochemistry.
© 1990 Optical Society of America
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