Photochemical hole burning of phthalocyanine in polymer glasses: Thermal cycling and spectral diffusion
- 15 January 1988
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 88 (2), 679-686
- https://doi.org/10.1063/1.454195
Abstract
In this paper we report an analysis of hole burning line shapes yielding both reversible and irreversible contributions to the linewidth which are due to spectral diffusion. These terms show a linear T dependence and can, through cycling experiments, be investigated in the temperature range of 0.5<TT<25 K is particularly interesting because, under normal conditions, Debye contributions and local mode contributions overwhelm the small spectral diffusion terms at these temperatures. Comparison between optical data and specific heat data supports our model of spectral diffusion.Keywords
This publication has 49 references indexed in Scilit:
- Optical dephasing in organic amorphous systems. A photon echo and hole-burning study of pentacene in polymethylmethacrylateThe Journal of Chemical Physics, 1985
- Spectral diffusion of a photochemical proton transfer system in an amorphous organic host: Quinizarin in alcohol glassThe Journal of Chemical Physics, 1984
- Low-Temperature Optical Dephasing of Rare-Earth Ions in GlassPhysical Review Letters, 1984
- An explanation of the anomalous temperature dependence of optical linewidths in glassesZeitschrift für Physik B Condensed Matter, 1984
- Theory of homogeneous linewidths of impurities in polymers and glassesPhysical Review B, 1984
- Measurement of optical dephasing of Eu3+ and Pr3+ doped silicate glasses by spectral holeburningOptics Communications, 1983
- Anomalous Optical Homogeneous Linewidths in GlassesPhysical Review Letters, 1982
- Relationship between the time-dependent specific heat and the ultrasonic properties of glasses at low temperaturesPhysical Review B, 1978
- Intrinsic low-temperature thermal properties of glassesPhysical Review B, 1976
- Specific Heat of Amorphous Polymethyl Methacrylate and Polystyrene Below 4°KThe Journal of Chemical Physics, 1970