Electronic energy transport and trapping on fractals
- 1 December 1989
- journal article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 91 (11) , 7291-7295
- https://doi.org/10.1063/1.457296
Abstract
The kinetics of the excitation quenching by acceptors in the presence of excitation migration over the donors is determined on fractals. We have used the Burshtein approach to determine the dynamics of the excitation hopping mechanism. The results were compared with the experimental study of electronic energy transfer of a two-component system [rhodamine 6G (R6G) as the donor and malachite green (MG) as the acceptor] adsorbed on a silica gel 200 surface. Samples ranging from high acceptor–low donor concentrations (the Förster limit) to the opposite regime were studied. The one-parameter fitting procedure yields a fractal dimension of 2.3±0.03. The same dimension has been previously obtained by us in both depolarization measurements and in direct energy transfer experiments.Keywords
This publication has 20 references indexed in Scilit:
- Fractal surface of porous materials as revealed by electronic energy transfer: Comparison of silica gels and controlled-pore glassesChemical Physics Letters, 1989
- Electronic excitation transport in a substitutionally disordered mediumChemical Physics, 1988
- Time-resolved fluorescence depolarization measurements in mesoporous silicas: the fractal approachThe Journal of Physical Chemistry, 1987
- Direct energy transfer in restricted geometries as a probe of the pore morphology of silicaPhysical Review Letters, 1987
- Integrated Fractal Analysis of Silica: Adsorption, Electronic Energy Transfer, and Small-Angle X-ray ScatteringPhysical Review Letters, 1986
- Energy transfer kinetics in disordered systemsJournal of Luminescence, 1985
- Electronic Energy Transfer on FractalsPhysical Review Letters, 1984
- Time-dependent effects in fluorescent line narrowingPhysical Review B, 1977
- Migration and transfer of optical excitationThe Journal of Chemical Physics, 1976
- Zwischenmolekulare Energiewanderung und FluoreszenzAnnalen der Physik, 1948