Spectral hole burning and holography. III. Electric field induced interference of holograms
- 15 August 1990
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 93 (4) , 2299-2307
- https://doi.org/10.1063/1.459009
Abstract
The electric field induced superposition of holograms recorded by spectralhole burning is investigated. Holograms have been burned at adjacent positions in a plane defined by wavelength and electric field. Application of an appropriate electric field to the sample causes the components of adjacent holograms to overlap as the spectral holes split due to Stark shifts of molecular transition frequencies. The diffraction efficiency of such superimposed holograms depends on their relative phase and has been studied theoretically and experimentally. It is shown that for zero phase difference, constructive interference leads to a strong diffraction efficiency whereas for a phase difference of π, the gratings cancel leading to zero diffraction efficiency. Experiments have been performed with the dye cresyl violet in a polyvinylbutyral film at a temperature of 1.7 K and the data are compared with computer simulations.Keywords
This publication has 16 references indexed in Scilit:
- Spectral hole burning: Electric field effect on resorufin, oxazine-4 and cresylviolet in polyvinylbutyralJournal of Luminescence, 1988
- Spectral hole burning and hologram storageApplied Optics, 1987
- Hole-burning spectroscopy on organic molecules in amorphous silicaChemical Physics Letters, 1987
- Sensitive detection of phase and absorption gratings: Phase-modulated, homodyne detected holographyApplied Physics B Laser and Optics, 1987
- Stark effect of polar and unpolar dye molecules in amorphous hosts, studied via persistent spectral hole burningThe Journal of Chemical Physics, 1987
- Spectral hole burning in glasses and polymer films: the Stark effectThe Journal of Physical Chemistry, 1986
- Holographic detection of photochemical holesChemical Physics, 1985
- Stark effect on the S1 ← S0 transition of the two tautomeric forms of chlorin studied by photochemical hole-burning in n-hexane and n-octane single crystals at 1.2 KChemical Physics Letters, 1983
- Site selection, hole burning, and stark effect on resorufin in poly(methyl methacrylate)Chemical Physics Letters, 1977
- Laser-induced Grating PhenomenaOptica Acta: International Journal of Optics, 1977