Vortex Induction via Anisotropy Stabilized Light-Matter Interaction

R. Barboza; U. Bortolozzo; G. Assanto; E. Vidal-Henriquez; M. G. Clerc; S. Residori

doi:10.1103/PhysRevLett.109.143901

Vortex Induction via Anisotropy Stabilized Light-Matter Interaction

R. Barboza^*
, U. Bortolozzo
, G. Assanto
, E. Vidal-Henriquez
, M. G. Clerc
, S. Residori

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

97 Citations (Scopus)

Abstract

By sending circularly polarized light beams onto a homeotropic nematic liquid crystal cell with a photosensitive wall, we are able to locally induce spontaneous matter vortices that remain, each, stable and trapped at the chosen location. We discuss the dual light-matter nature of the created vortices and demonstrate the ability of the system to create optical vortices with opposite topological charges that, consistent with angular momentum conservation, both derive from the same defect created in the liquid crystal texture. Theoretically, we identify a self-stabilizing mechanism for the matter vortex, which is provided by the concurrency of light-induced gradients and anisotropy of the elastic constants that characterize the deformation of the liquid crystal medium.

Original language	English
Article number	143901
Journal	Physical Review Letters
Volume	109
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevLett.109.143901
Publication status	Published - 1 Oct 2012
Publication type	A1 Journal article-refereed

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.109.143901

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title = "Vortex Induction via Anisotropy Stabilized Light-Matter Interaction",

abstract = "By sending circularly polarized light beams onto a homeotropic nematic liquid crystal cell with a photosensitive wall, we are able to locally induce spontaneous matter vortices that remain, each, stable and trapped at the chosen location. We discuss the dual light-matter nature of the created vortices and demonstrate the ability of the system to create optical vortices with opposite topological charges that, consistent with angular momentum conservation, both derive from the same defect created in the liquid crystal texture. Theoretically, we identify a self-stabilizing mechanism for the matter vortex, which is provided by the concurrency of light-induced gradients and anisotropy of the elastic constants that characterize the deformation of the liquid crystal medium.",

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AU - Barboza, R.

AU - Bortolozzo, U.

AU - Assanto, G.

AU - Vidal-Henriquez, E.

AU - Clerc, M. G.

AU - Residori, S.

PY - 2012/10/1

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N2 - By sending circularly polarized light beams onto a homeotropic nematic liquid crystal cell with a photosensitive wall, we are able to locally induce spontaneous matter vortices that remain, each, stable and trapped at the chosen location. We discuss the dual light-matter nature of the created vortices and demonstrate the ability of the system to create optical vortices with opposite topological charges that, consistent with angular momentum conservation, both derive from the same defect created in the liquid crystal texture. Theoretically, we identify a self-stabilizing mechanism for the matter vortex, which is provided by the concurrency of light-induced gradients and anisotropy of the elastic constants that characterize the deformation of the liquid crystal medium.

AB - By sending circularly polarized light beams onto a homeotropic nematic liquid crystal cell with a photosensitive wall, we are able to locally induce spontaneous matter vortices that remain, each, stable and trapped at the chosen location. We discuss the dual light-matter nature of the created vortices and demonstrate the ability of the system to create optical vortices with opposite topological charges that, consistent with angular momentum conservation, both derive from the same defect created in the liquid crystal texture. Theoretically, we identify a self-stabilizing mechanism for the matter vortex, which is provided by the concurrency of light-induced gradients and anisotropy of the elastic constants that characterize the deformation of the liquid crystal medium.

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JO - Physical Review Letters

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IS - 14

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ER -

Vortex Induction via Anisotropy Stabilized Light-Matter Interaction

Abstract

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