Spatial (2+l)D higher-order vector solitons in a photorefractive medium

Carsten Weilnau; Cornelia Denz; Marcus Ahles; Kristian Motzek; Andreas Stepken; Friedemann Kaiser

doi:10.1364/PEMD.2001.455

Photorefractive Effects, Materials, and Devices
OSA Trends in Optics and Photonics (Optica Publishing Group, 2001),
paper 455
•https://doi.org/10.1364/PEMD.2001.455

Spatial (2+l)D higher-order vector solitons in a photorefractive medium

Carsten Weilnau, Cornelia Denz, Marcus Ahles, Kristian Motzek, Andreas Stepken, and Friedemann Kaiser

Photorefractive Effects, Materials, and Devices 2001

Delavan, Wisconsin United States
ISBN: 1-55752-693-1

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C. Weilnau, C. Denz, M. Ahles, K. Motzek, A. Stepken, and F. Kaiser, "Spatial (2+l)D higher-order vector solitons in a photorefractive medium," in Photorefractive Effects, Materials, and Devices, G. Salamo and A. Siahmakoun, eds., Vol. 62 of OSA Trends in Optics and Photonics (Optica Publishing Group, 2001), paper 455.

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Abstract

We investigate the generation of higher-order optical vector solitons in two transverse dimensions in anisotropic nonlinear media consisting of an incoherent superposition of a Gaussian beam and a higher-order laser mode with a complex internal modal structure. We demonstrate both, numerically and experimentally various examples of these stable self-trapped light structures and show that vortex modes carrying topological charge always decay into multiple-humped structures which remain self-trapped during propagation. Furthermore we combine two dipole mode beams in the absence of a fundamental Gaussian component and demonstrate their mutual attraction that displays an unstable propagation behaviour and leads to a splitting of one constituent beam.

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