Dynamic propagation of an Airy beam in metasurface-enabled gradiently-aligned liquid crystals

Gao, Meini; Wang, Jiawei; Cai, Wenfeng; Cheng, Ming; Hao, Xichen; Wang, Yuhan; Liu, Ying; Kong, Delai; Liu, Jianxun; Dai, Haitao; Liu, Yan Jun

doi:10.1515/nanoph-2023-0516

Nanophotonics

2023

DOI: 10.1515/nanoph-2023-0516

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Dynamic propagation of an Airy beam in metasurface-enabled gradiently-aligned liquid crystals

Meini Gao,

Jiawei Wang,

Wenfeng Cai

et al.

Abstract: Due to the unique self-acceleration, self-healing, and non-diffraction properties, Airy beams have been explored extensively and found applications in various fields. It has been proven as an essential aspect to tune the trajectory of Airy beams for extensive applications. In this paper, we propose a method based on liquid crystal (LC) alignment with metasurfaces, which enables dynamic tuning of the trajectory of Airy beams. Benefiting from both the tunable property of LCs and the compact alignment of metasurf… Show more

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2024

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Cited by 7 publications

References 67 publications

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When Structured Light Encounters Liquid Crystals

Zhou,

Zhong,

Liu

et al. 2024

Adv Funct Materials

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Structured light refers to the light field tailored by various degrees of freedom including intensity, phase, and polarization states in both spatial and temporal domains, which may greatly vitalize the technologies in both optics, such as the next‐generation optical communication as well as subwavelength imaging and the materials science in both fabrication and characterization. The structured characteristics of the structure light need materials also with structured optical properties that can generate or manipulate structured light in a straightforward way, which can be well satisfied by liquid crystals, a soft mater that can self‐assemble into tunable ordered structures through external stimuli. This review summarizes the research progress of the liquid crystal‐based devices used in structured light generations and modulations, including the well‐established techniques in the market, like the spatial light modulator, q‐plate and the liquid crystal integrated optical metasurfaces. Especially, light‐matter interactions are discussed from the topological view of both the structured light and the liquid crystal structures. Such a perfect matching in topology makes the liquid crystal a promising star together with structured light in future optic and photonic technologies.

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When Structured Light Encounters Liquid Crystals

Zhou,

Zhong,

Liu

et al. 2024

Adv Funct Materials

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Skin Effect of Electromagnetic Flux in Anisotropic Zero‐Index Metamaterials

Mei,

Xu,

Gao

et al. 2024

Advanced Optical Materials

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Skin effect in electromagnetism describes the tendency of alternating current to predominantly flow near the surface rather than through the center of a conductor. Here, another skin effect of electromagnetic flux is reported to occur in non‐conductive materials, specifically within 3D anisotropic zero‐index metamaterials, as well as its potential application in subwavelength wave manipulation. It is found that when a medium of near‐zero longitudinal permittivity and permeability is embedded with inclusions whose transverse permittivity and/or permeability approach zero, the electromagnetic flux therein is directed and extremely compressed beneath the surfaces of inclusions within a skin depth less than λ0/150. This unusual effect empowers arbitrary control of electromagnetic flux at deep subwavelength scale. Customized subwavelength pathways for electromagnetic flux are demonstrated in full‐wave simulations via practical implementations. The study opens a new avenue for extreme confinement and flexible control of electromagnetic flux at deep‐subwavelength scale.

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Dynamic Transition from Branched Flow of Light to Beam Steering in Disordered Nematic Liquid Crystal

Yu,

Chang,

Wang

et al. 2024

Laser & Photonics Reviews

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Orientational ordered soft matter possessing diverse microstructures has become a focal point of scientific research and technological exploration, thanks to its advancements in serving as an indispensable optical platform enabling propagation of light with multidimensional and manipulatable states. Herein, a facile way is developed to manipulate the in‐plane light beam transition dynamics by harnessing a time‐variable nematic liquid crystal (NLC) film through the electrical‐field‐induced topological defects. The results show that the dynamic change of optical branched flow is associated with the growth in the correlation length of optical potential and the reduction in the density of topological defects. The optical branching can continuously transform to deterministic and tunable beam steering at the low‐defect‐density regime through annihilation kinetics of defects. The explored soft matter system provides an excellent planar platform for the fundamental physics of light interacting with topological defects and may offer new perspectives for novel optics elements toward the applications of soft matter photonics.

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Dynamic propagation of an Airy beam in metasurface-enabled gradiently-aligned liquid crystals

Cited by 7 publications

References 67 publications

When Structured Light Encounters Liquid Crystals

When Structured Light Encounters Liquid Crystals

Skin Effect of Electromagnetic Flux in Anisotropic Zero‐Index Metamaterials

Dynamic Transition from Branched Flow of Light to Beam Steering in Disordered Nematic Liquid Crystal

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