Self-Action of Light Beams in an Amorphous Azobenzene Polymer

We report an experimental study of the self-action of TEM 01 and TEM 00 Gaussian modes in a layer of a comb-shaped amorphous polymer with cyanobiphenyl and azobenzene side fragments. For the linearly polarized TEM 01 mode, a pattern of aberration self-action is observed in the form of rings with an...

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Bibliographic Details
Published in:Bulletin of the Lebedev Physics Institute 2024-02, Vol.51 (2), p.62-69
Main Authors: Zolot’ko, A. S., Budagovsky, I. A., Baranov, A. I., Lagunov, V. V., Smayev, M. P., Kuznetsov, A. A., Bobrovsky, A. Yu
Format: Article
Language:English
Subjects:
Aberration
Azo compounds
Chromophores
Circular polarization
Distribution functions
Ellipticity
Light beams
Linear polarization
Nonlinear optics
Nonlinear response
Nonlinearity
Physics
Physics and Astronomy
Polymers
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Summary:We report an experimental study of the self-action of TEM 01 and TEM 00 Gaussian modes in a layer of a comb-shaped amorphous polymer with cyanobiphenyl and azobenzene side fragments. For the linearly polarized TEM 01 mode, a pattern of aberration self-action is observed in the form of rings with an additional system of the fringes, caused by interference from two intensity peaks. The position of the fringes and the microscopic image of the deformation region correspond to the local nature of the nonlinear optical response. For the circularly polarized (with an ellipticity of about 7%) TEM 00 Gaussian mode, the polarization of the outer aberration ring is close to linear. This effect stems from the self-rotation of the polarization ellipse due to the manifestation of Kerr-type nonlinearity. A characteristic feature of this effect in an amorphous polymer is an increase in the eccentricity of the ellipse (transformation of circular polarization into linear polarization), which is caused by a light-induced change in the orientation distribution function of the chromophores.
ISSN:1068-3356
1934-838X
DOI:10.3103/S1068335623602157