Abstract
Persistent spectral hole burning (PHB) offers the potential of ultra high density optical data storage1). Recently much effort has been directed towards photon-gated PHB material systems, since the systems have good properties for optical memories such as non-destructive reading and fast reaction time2). Thus it is important to study the reaction mechanism of photon-gated material systems not only to develop suitable material systems for optical memories but also to find new photochemical reactions at cryogenic temperatures.
© 1994 Optical Society of America
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