Self-trapping of optical vortices at the surface of an induced semi-infinite photonic lattice | Zendy

Daohong Song | Zendy; Cibo Lou | Zendy; Kody J. H. Law | Zendy; Liqin Tang | Zendy; Zhuoyi Ye | Zendy; P. G. Kevrekidis | Zendy; Jingjun Xu | Zendy; Zhigang Chen | Zendy

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Self-trapping of optical vortices at the surface of an induced semi-infinite photonic lattice

Author(s) -

Daohong Song,

Cibo Lou,

Kody J. H. Law,

Liqin Tang,

Zhuoyi Ye,

P. G. Kevrekidis,

Jingjun Xu,

Zhigang Chen

Publication year - 2010

Publication title -

optics express

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.394

H-Index - 271

ISSN - 1094-4087

DOI - 10.1364/oe.18.005873

Subject(s) - vortex , trapping , optical vortex , physics , excitation , lattice (music) , soliton , photonic crystal , optical lattice , optics , photonics , optical tweezers , condensed matter physics , light beam , nonlinear system , beam (structure) , quantum mechanics , superfluidity , ecology , acoustics , biology , thermodynamics

We demonstrate self-trapping of singly-charged vortices at the surface of an optically induced two-dimensional photonic lattice. Under appropriate conditions of self-focusing nonlinearity, a singly-charged vortex beam can self-trap into a stable semi-infinite gap surface vortex soliton through a four-site excitation. However, a single-site excitation leads to a quasi-localized state in the first photonic gap, and our theoretical analysis illustrates that such a bandgap surface vortex soliton is always unstable. Our experimental results of stable and unstable topological surface solitons are corroborated by direct numerical simulations and linear stability analysis.

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