Geometric stabilization of extended<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mi>S</mml:mi><mml:mo>=</mml:mo><mml:mn>2</mml:mn></mml:mrow></mml:math>vortices in two-dimensional photonic lattices: Theoretical analysis, numerical computation, and experimental results

Law, Kody J. H.; Song, Daohong; Kevrekidis, P. G.; Xu, Jingjun; Chen, Zhigang

doi:10.1103/physreva.80.063817

Cited by 12 publications

(8 citation statements)

References 62 publications

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“…We emphasize again that such solitons are generated under the eight-site excitation, and they are quite different from the four-site excitation which leads to dynamical charge flipping and topological transformation as discussed above. Thus, in an optically induced square lattice, the DCVs can be geometrically stabilized and self-trapped, in good agreement with our theoretical and numerical results [44].…”

Section: Geometric Stabilization Of Doubly-charged Vorticessupporting

confidence: 88%

“…Our theoretically studies of a continuum model with periodic potentials show that the DCV solitons have large stability regions under both self-focusing and self-defocusing nonlinearities. Details will be reported elsewhere [44]. In our experiment, the same setup of Figure 1 is used.…”

Section: Geometric Stabilization Of Doubly-charged Vorticesmentioning

confidence: 98%

“…It has been suggested that the doubly-charged vortices (DCVs) can be stabilized by introducing a defect site in the square lattices [42], but such defect-stabilized vortex solitons have not been found in experiments. Very recently, however, self-trapping of DCVs into stable higher-order vortex solitons has been observed in experiments with different lattice configurations/excitations under a self-focusing nonlinearity [43,44].…”

Section: Introductionmentioning

confidence: 97%

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Self-trapping and stabilization of doubly-charged optical vortices in two-dimensional photonic lattices

Eugenieva

Song

Bezryadina

et al. 2010

Journal of Modern Optics

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We report our recent work on self-trapping of doubly-charged vortices (DCVs) in two-dimensional optically induced photonic lattices. We show that in an ideal isotropic nonlinear periodic medium self-trapping of a DCV can lead to formation of a rotating 'quasi-vortex' soliton with periodic charge-flipping, but the vortex breaks up into multiple singly-charged vortices in an anisotropic nonlinear medium. Such topological transformation of high-order vortices under conventional four-site excitation in a square photonic lattice has been observed in our experiment and corroborated with numerical simulations. With geometrically extended eight-site excitation, however, discrete self-trapping of a DCV into a stable high-order vortex soliton can be realized with both self-focusing and self-defocusing nonlinearities.We are pleased to contribute this article in honor to and memory of Lorenzo Narducci who remains a source of personal and professional inspiration. Ever clear in his explanations as a teacher and colleague, he was also exemplary in his inclusion of each new student, post-doc, and faculty colleague. Though not an experimentalist, he dedicated himself to understanding experiments and experimental results and matching many of them in his theoretical and computational analyses. He reached out to share his passion for laser physics and quantum optics to colleagues around the world where he was welcomed with warmth which he reciprocated. We treasure his legacy of incisive questions, derivations from first principles, and dedication to physical understanding. We regret that we will not benefit from his questions and critiques in this and future work.

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Section: Geometric Stabilization Of Doubly-charged Vorticessupporting

confidence: 88%

Section: Geometric Stabilization Of Doubly-charged Vorticesmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 97%

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Self-trapping and stabilization of doubly-charged optical vortices in two-dimensional photonic lattices

Eugenieva

Song

Bezryadina

et al. 2010

Journal of Modern Optics

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“…We want to mention that the DCV beams can also stably self-trap into solitons in the semi-infinite gap under self-focusing nonlinearity with 8-site excitation. Such geometrical extended stabilization mechanism has also been confirmed by theoretical analysis [31].…”

Section: Discrete Gap Vortexsupporting

confidence: 61%

Experiments on Linear and Nonlinear Localization of Optical Vortices in Optically Induced Photonic Lattices

Song

Lou

Tang

et al. 2012

International Journal of Optics

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We provide a brief overview on our recent experimental work on linear and nonlinear localization of singly charged vortices (SCVs) and doubly charged vortices (DCVs) in two-dimensional optically induced photonic lattices. In the nonlinear case, vortex propagation at the lattice surface as well as inside the uniform square-shaped photonic lattices is considered. It is shown that, apart from the fundamental (semi-infinite gap) discrete vortex solitons demonstrated earlier, the SCVs can self-trap into stable gap vortex solitons under the normal four-site excitation with a self-defocusing nonlinearity, while the DCVs can be stable only under an eight-site excitation inside the photonic lattices. Moreover, the SCVs can also turn into stable surface vortex solitons under the four-site excitation at the surface of a semi-infinite photonics lattice with a self-focusing nonlinearity. In the linear case, bandgap guidance of both SCVs and DCVs in photonic lattices with a tunable negative defect is investigated. It is found that the SCVs can be guided at the negative defect as linear vortex defect modes, while the DCVs tend to turn into quadrupole-like defect modes provided that the defect strength is not too strong.

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“…More specifically, we will demonstrate that solutions (such as the discrete vortices of topological charge S = 1), which are robust enough that they can be observed in photonic crystal experiments [26], can be destabilized even by arbitrarily 2 small beyond-nearest-neighbor interaction (of suitable sign). Moreover, we will show that other states which are unstable in the standard case (such as the vortices of topological charge S = 2; see for theory [10,27] and for recent experiments [28]) will be stabilized when the next-nearest neighbor effect is sufficiently strong. Moreover, we will identify special limits (such as the degenerate unit diagonal neighbor limit) whereby even solitary wave (non-vortex) solutions will change (or exchange) their stability.…”

Section: Introductionmentioning

confidence: 99%

The drastic role of beyond-nearest-neighbor interactions on discrete two-dimensional dynamical lattices: a case example

Kevrekidis

2013

J. Opt.

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In the present work, we highlight the significant effect that the simplest beyond nearest neighbor interactions can have on two-dimensional dynamical lattices. To do so, we select as our case example the closest further neighbor, namely the diagonal one, and a prototypical nonlinear lattice, the discrete nonlinear Schrödinger equation. Varying solely the strength of this extra neighbor interaction, we see examples of (a) destabilization of states that start out as stable in the nearest neighbor limit; (b) stabilization of states that start out as unstable in that limit; (c) bifurcation of novel states that do not exist in the nearest neighbor case. These dramatic changes are first theoretically highlighted through an analysis of a reduction of the problem to a few excited sites and the associated set of conditions that govern their existence and their dynamical stability. Then, they are corroborated numerically through fixed point computations, spectral analysis and nonlinear dynamical evolution simulations.

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Geometric stabilization of extendedS=2vortices in two-dimensional photonic lattices: Theoretical analysis, numerical computation, and experimental results

Cited by 12 publications

References 62 publications

Self-trapping and stabilization of doubly-charged optical vortices in two-dimensional photonic lattices

Self-trapping and stabilization of doubly-charged optical vortices in two-dimensional photonic lattices

Experiments on Linear and Nonlinear Localization of Optical Vortices in Optically Induced Photonic Lattices

The drastic role of beyond-nearest-neighbor interactions on discrete two-dimensional dynamical lattices: a case example

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