Conical Diffraction and Gap Solitons in Honeycomb Photonic Lattices

Peleg, Or; Bartal, Guy; Freedman, Barak; Manela, Ofer; Segev, Mordechai; Christodoulides, Demetrios N.

doi:10.1103/physrevlett.98.103901

Cited by 353 publications

(307 citation statements)

References 21 publications

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“…However, more recently both in optics [28,29] and in BEC [30,31] (so far in the absence of the lattice for the latter case), the study of higher charge vortices has been of interest. In particular, in the emerging area of hexagonal [21,32] and honeycomb [20] lattices, it has been predicted [33,34] and experimentally observed [35] very recently that a higher-order vortex with topological charge S = 2 is more stable than a fundamental vortex with unit charge (S = 1) when self-trapped with a focusing nonlinearity.…”

Section: Introductionmentioning

confidence: 99%

“…Indeed, the theoretical proposal [5] of such lattice solitons was followed quickly by their experimental realization in 2D induced lattices [9,10], subsequently leading to the observation of a host of novel solitons in this setting, including dipole [11], multipole [12], necklace [13], and rotary [14] solitons as well as discrete [15,16] and gap [17] vortices. In addition to lattice solitons, photonic lattices have enabled observations of other intriguing phenomena such as higher order Bloch modes [18], Zener tunneling [19], and localized modes in honeycomb [20], hexagonal [21] and quasi-crystalline [22] lattices, and Anderson localization [23] (see, e.g., the recent review [24] for additional examples). In parallel, experimental development in the area of BECs closely follows, with prominent recent results including the observation of bright, dark and gap solitons in quasi-onedimensional settings [25], with the generation of similar structures in higher dimensions being experimentally feasible for BECs trapped in optical lattices [26,27].…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2009

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In this work, we focus our studies on the subject of nonlinear discrete self-trapping of S = 2 (doubly-charged) vortices in two-dimensional photonic lattices, including theoretical analysis, numerical computation and experimental demonstration. We revisit earlier findings about S = 2 vortices with a discrete model, and find that S = 2 vortices extended over eight lattice sites can indeed be stable (or only weakly unstable) under certain conditions, not only for the cubic nonlinearity previously used, but also for a saturable nonlinearity more relevant to our experiment with a biased photorefractive nonlinear crystal. We then use the discrete analysis as a guide towards numerically identifying stable (and unstable) vortex solutions in a more realistic continuum model with a periodic potential. Finally, we present our experimental observation of such geometrically extended S = 2 vortex solitons in optically induced lattices under both self-focusing and self-defocusing nonlinearities, and show clearly that the S = 2 vortex singularities are preserved during nonlinear propagation.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

et al. 2009

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“…This phenomenon, termed conical diffraction, was observed later by Lloyd [2]. Conical diffraction is possible in crystals with dispersion surfaces that intersect at a singular point where the group velocity is not uniquely defined [3]. This is often referred to as the Dirac point or diabolical point.…”

Section: Introductionmentioning

confidence: 99%

“…It has been shown in various contexts that conical diffraction is possible in systems with Dirac cones in the dispersion relation [1,3,9]. A suitable initial condition in order to observe the relevant phenomenology is a localized function (such as a Gaussian) that is modulating a Bloch wave with a wavenumber near the Dirac point.…”

Section: A Heuristic Argument For Conical Diffractionmentioning

confidence: 99%

“…a honeycomb symmetry and indeed emerges due to the special symmetry of the lattice. This has led to a burst of activity towards the study of Dirac points in other physical systems with the honeycomb and hexagonal symmetries, e.g., in photonics [3,[9][10][11][12][13][14][15][16][17] -giving also rise to the term "photonic graphene"-, where it has been shown that conical diffraction is possible [3,9]. More recently, Dirac points have started to be explored in phononic systems, where pressure waves are manipulated rather than light waves [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

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Conical wave propagation and diffraction in two-dimensional hexagonally packed granular lattices

et al. 2016

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Linear and nonlinear mechanisms for conical wave propagation in two-dimensional lattices are explored in the realm of phononic crystals. As a prototypical example, a statically compressed granular lattice of spherical particles arranged in a hexagonal packing configuration is analyzed. Upon identifying the dispersion relation of the underlying linear problem, the resulting diffraction properties are considered. Analysis both via a heuristic argument for the linear propagation of a wavepacket, as well as via asymptotic analysis leading to the derivation of a Dirac system suggests the occurrence of conical diffraction. This analysis is valid for strong precompression i.e., near the linear regime. For weak precompression, conical wave propagation is still possible, but the resulting expanding circular wave front is of a non-oscillatory nature, resulting from the complex interplay between the discreteness, nonlinearity and geometry of the packing. The transition between these two types of propagation is explored.

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Localized Modes in Nonlinear Fractional Systems with Deep Lattices

Liu

Malomed

Zeng

2022

Advcd Theory and Sims

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Solitons in the fractional space, supported by lattice potentials, have recently attracted much interest. The limit of deep 1D and 2D lattices in this system is considered, featuring finite bandgaps separated by nearly flat Bloch bands. Such spectra are also a subject of great interest in current studies. The existence, shapes, and stability of various localized modes, including fundamental gap and vortex solitons, are investigated by means of numerical methods; some results are also obtained with the help of analytical approximations. In particular, the 1D and 2D gap solitons, belonging to the first and second finite bandgaps, are tightly confined around a single cell of the deep lattice. Vortex gap solitons are constructed as four-peak "squares" and "rhombuses" with imprinted winding number S = 1. Stability of the solitons is explored by means of the linearization and verified by direct simulations.

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Conical Diffraction and Gap Solitons in Honeycomb Photonic Lattices

Cited by 353 publications

References 21 publications

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

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

Conical wave propagation and diffraction in two-dimensional hexagonally packed granular lattices

Localized Modes in Nonlinear Fractional Systems with Deep Lattices

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