Voltage-driven beam bistability in a reorientational uniaxial dielectric

Piccardi, Armando; Kravets, Nina; Alberucci, Alessandro; Buchnev, Oleksandr; Assanto, Gaetano

doi:10.1063/1.4945349

Cited by 6 publications

(5 citation statements)

References 37 publications

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“…Since the evolution of spatial solitary waves is essentially governed by their main wavevector, nematicons propagating across a graded-index or abrupt dielectric interface are subject to standard or anomalous refraction (depending on the angle of incidence and the orientation of the optic axis) [81,82,83], as well as total internal reflection and lateral beam displacement [84,85]. They also exhibit confinement bistability in cavityless geometries versus beam power [86,87,88], applied voltage [89] and angle of incidence [90] and are able to form multicolour, vector and cluster states [55,91,92,93,94,95]. Finally, reorientational solitons can coexist/compete with either electronic [65,96,97] or thermal responses in NLC [30,31,32,98,99,100,101], yielding novel features in suitably doped materials [67,102,103,104,105].…”

Section: Physical Backgroundmentioning

confidence: 99%

“…for −L ≤ y ≤ L was assumed, so that at y = ±L the electric field essentially vanishes. Hence, the background orientation resulting from this bias can, in principle, be calculated from the director equation (89) with u = 0. However, the resulting equation is a form of the parabolic cylinder equation [154], not useful to evaluate the integrals in the momentum equation (95).…”

Section: Modelling Experimentsmentioning

confidence: 99%

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Self-confined light waves in nematic liquid crystals

Assanto

Smyth

2020

Physica D: Nonlinear Phenomena

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The study of light beams propagating in the nonlinear, dispersive, birefringent and nonlocal medium of nematic liquid crystals has attracted widespread interest in the last twenty years or so. We review hereby the underlying physics, theoretical modelling and numerical approximations for nonlinear beam propagation in planar cells filled with nematic liquid crystals, including bright and dark solitary waves, as well as optical vortices. The pertinent governing equations consist of a nonlinear Schrödinger-type equation for the light beam and an elliptic equation for the medium response. Since the nonlinear and coupled nature of this system presents difficulties in terms of finding exact solutions, we outline the various approaches used to resolve them, pinpointing the good agreement obtained with numerical solutions and experimental results. Measurement and material details complement the theoretical narration to underline the power of the modelling.

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Section: Physical Backgroundmentioning

confidence: 99%

Section: Modelling Experimentsmentioning

confidence: 99%

Self-confined light waves in nematic liquid crystals

Assanto

Smyth

2020

Physica D: Nonlinear Phenomena

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“…As shown in Fig. 7(a), we investigated the propagation of a P = 2 mW beam for various applied voltages: selfconfinement occurred when all-optical and electric responses sufficed to overcome the FT [37]. This was observed above V = 1 V, when the beam width gradually reduced until it resulted into a spatial soliton.…”

Section: B Optical Bistability Versus Applied Voltagementioning

confidence: 99%

“…In this Paper we address, both experimentally and theoretically, OB between wave-propagation states corresponding to beam diffraction and spatial solitons, respectively, in an optically nonlinear as well as electro-optic reorientational medium, namely nematic liquid crystals (NLC), where either the optical power or the bias voltage can control light localization and its evolution/switching between different states. With respect to our previous works [36], [37], here we generalize the approach of Ref. [38] developing a general theory based upon the Green function, and accounting for the simultaneous presence of voltage and optical fields.…”

Section: Introductionmentioning

confidence: 99%

Bistable Beam Propagation in Liquid Crystals

Piccardi

Alberucci

Kravets

et al. 2017

IEEE J. Quantum Electron.

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Abstract-Light-controlling-light is one of the most advanced paradigms in optical signal processing, including light-induced waveguides as well as all-optical switching and routing. Other fundamental aspects of all-optical processing are optical memories and sequential elements, which require responses depending on the evolution history of the system, such as the hysteresis stemming from optical multistability. Hereby we report on optical bistability and hysteresis in cavity-less geometries and in the presence of self-localized beams, i.e., spatial optical solitons, exploiting the nonlocal reorientational nonlinearity of nematic liquid crystals. When the optic axis of NLC is initially orthogonal to the applied electric field, the molecular dipoles start to rotate above a threshold named after the Fréedericksz transition, usually second-order. Here we show that such transition becomes first-order via the intrinsic feedback provided by self-focusing, in turn leading to the appearance of a hysteresis loop between diffracting and self-confined beams. We report on hysteresis of the beam size versus the input power, as well as hysteresis versus applied voltage at a fixed beam power. Our findings introduce a novel kind of cavity-less optical bistability with propagating light beams and disclose a novel approach to information storage based on light self-localization.

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“…In liquid crystals such nonlinearities are already noticeable for milliwatt powers of an optical beam [2]. Optical reorientation in liquid crystals is commonly used for the generation of spatial optical solitons [3][4][5][6].…”

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confidence: 99%