Synopses & Reviews
This book describes the underlying scientific fundamentals and principal phenomena associated with persistent spectral hole-burning in solids, and presents an overview of possible future applications to optical storage of digital data and optical signal processing. Organization of the material is by the general physical mechanism responsible for the formation of persistent spectral holes. After a description of the basic principles and methods of hole-burning, with examples from photochemical processes in crystalline and amorphous hosts, the unusual proton tunneling phenomena that occur in hydrogen-bonded polymers and glasses are described. Persistent spectral hole-burning in inorganic materials due either to photoionization or to photophysical effects is then summarized, followed by a detailed discussion of nonphotochemical hole-burning mechanisms for electronic transitions in amorphous solids. The book concludes with a description of potential applications to data storage and optical processsing using frequency-domain, holographic, and electric field techniques. Readers of this volume will gain a detailed appreciation of both the generality of the persistent spectral hole-burning phenomenon and the power of the technique in studying microscopic dynamics and mechanisms of phototransformation in low-temperature solids.
Synopsis
Almost fifteen years have now elapsed since the first observations of per- sistent spectral hole-burning in inhomogeneously broadened absorption lines in solids. The fact that the spectral shape of an inhomogeneously broadened line can be locally modified for long periods of time has led to a large number of investigations of low-temperature photophysics and photochemistry that would not have been possible otherwise. Using hole- burning, important information has been obtained about a variety of in- teractions, including excited-state dephasing processes, host-guest dynam- ics, proton tunnelling, low-frequency excitation in amorphous hosts, relaxation mechanisms for vibrational modes, photochemical mechanisms at liquid helium temperatures, and external field perturbations. At the same time, the possibility that persistent spectral holes might be used to store digital information has led to the study of materials and configura- tions for frequency-domain optical storage and related possible applica- tions. This is the first full-length book on persistent spectral hole-burning. The goal is to provide a broadly based survey of the scientific principles and applications of persistent spectral hole-burning. Since the topic is quite interdisciplinary, the book is intended for researchers, graduate stu- dents, and advanced undergraduates in the fields of chemical physics, solid-state physics, laser spectroscopy, solid-state photochemistry, and high-performance optical storage and optical processing.
Table of Contents
Contents: Introduction.- Basic Principles and Methods of Persistent Spectral Hole-Burning.- Photochemical Hole-Burning in Electronic Transitions.- Persistent Spectral Hole-Burning in Inorganic Materials.- Two-Level System Relaxation in Amorphous Solids as Probed by Nonphotochemical Hole-Burning in Electric Transitions.- Persistent Infrared Spectral Hole-Burning for Impurity Vibrational Modes in Solids.- Frequency Domain Optical Storage and Other Applications of Persistent Spectral Hole-Burning.- Subject Index.