Linear and Nonlinear Optical Field Manipulations with Multifunctional Chiral Coding Metasurfaces

Jiang, Yifan; Liu, Wenwei; Li, Zhancheng; Choi, Duk‐Yong; Zhang, Yuebian; Cheng, Hua; Tian, Jianguo; Chen, Shuqi

doi:10.1002/adom.202202186

Cited by 12 publications

(5 citation statements)

References 45 publications

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“…Localized surface plasmons (LSPs) refer to the collective oscillation phenomenon of free electrons in the conduction band of metallic nanoparticles excited by electromagnetic waves . The abilities of LSP to surpass the diffraction limit of conventional optics and enhance the light-matter interactions have attracted significant attentions. , These unique properties enable the transformation and manipulation of photonics, electronics, and nanotechnology, including biosensing, nonlinear optics, nanolasers, strong local field enhancement, and metamaterials. − However, the presence of huge nonradiative and radiative loss of metallic nanostructures results in a low quality factor ( Q ∼ 10 1 ) for LSPs. , Consequently, the performance of many applications of plasmonic-based nanodevices is limited . Current research focuses on addressing this issue by exploring various mechanisms to achieve high- Q plasmonic resonance, such as utilizing alternative plasmonic materials, reducing surface roughness, , incorporating gain media, , utilizing plasmonic Fano resonances , and employing lattice plasmon resonance (LPR). − …”

Section: Introductionmentioning

confidence: 99%

High-Q and Intense Lattice Plasmon Resonance in Hexagonal Nonclose Packed Thin Silver Nanoshells Array

Gu,

Yang,

et al. 2024

J. Phys. Chem. C

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We theoretically demonstrate a high-Q and intense lattice plasmon resonance supported by the hexagonal nonclose packed thin silver nanoshells array. By introducing the diffraction coupling mechanism, the high-Q and intense lattice plasmon mode stemmed from the coupling between the TM 1 cavity plasmon mode and the diffraction mode of the first-order Wood anomaly is obtained in the thin silver nanoshells array, successfully solving the trade-off between the Q-factor and the resonance intensity of the cavity plasmon mode existed in a single silver nanoshell. In particular, a maximum Q-factor up to 610 of the lattice plasmon resonance is successfully achieved at 870 nm in the silver nanoshell array with an optimal silver thickness of 20 nm.

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Section: Introductionmentioning

confidence: 99%

High-Q and Intense Lattice Plasmon Resonance in Hexagonal Nonclose Packed Thin Silver Nanoshells Array

Gu,

Yang,

et al. 2024

J. Phys. Chem. C

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“…The phase-matching condition of the nonlinear process is released in metasurfaces because of their nanoscale dimension. Furthermore, numerous nonlinear wavefront manipulations have been achieved, such as nonlinear holograms, [35,36,38,51] nonlinear optical vortexes, [5,52] and nonlinear metalenses. [53,54] Benefiting from the simple relationship between the phase and the rotation angle of structures, the nonlinear Pancharatnam-Berry (PB) phase has been extensively employed in engineering the wavefront of nonlinear signals.…”

Section: Introductionmentioning

confidence: 99%

“…[35,37] Nonlinear multichannel optical information multiplexing has also been successfully implemented in previous publications. [52,55] Moreover, optical information can be constructed in both linear and nonlinear regimes simultaneously, providing new possibilities for information encryption. [5] By expanding the PB phase and Malus's law to nonlinear optical regimes, different optical information can be encrypted into different frequency or polarization channels.…”

Section: Introductionmentioning

confidence: 99%

Multichannel Linear and Nonlinear Information Encryptions with Malus Metasurfaces

Sun,

Geng,

Wang

et al. 2024

Laser & Photonics Reviews

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The superior capability of wavefront manipulation makes metasurfaces a promising platform for implementing high‐density information storage and multifold optical encryption. Although some metasurfaces have realized information encryption, it is still challenging to implement polarization‐encrypted grayscale images in both linear and nonlinear channels. Here, a novel approach to realize multichannel linear and nonlinear information encryptions is proposed based on nonlinear Malus metasurfaces composed of single‐sized meta‐atoms, in which the polarization states of the linear and nonlinear signals can be decoupled. As a proof of concept, two distinct grayscale images with different polarizations have been encrypted in the fundamental and second harmonic wave channels simultaneously. Besides, by further introducing the nonlinear Pancharatnam‐Berry phase, a tri‐channel polarization encrypted metasurface with a multi‐level grayscale image in the near field and two holographic images in the far field has been experimentally demonstrated at the second harmonic frequency. This work provides more degrees of freedom for multichannel information storage and opens an avenue for optical information encryption in both linear and nonlinear regimes.

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“…chiral metasurfaces. Chiral metasurfaces have significant importance in various optical applications, including molecular recognition [1], biosensing [2], and optical information processing [3]. Additionally, chiral metasurfaces offer several advantages for refractive index sensing applications, such as high sensitivity, a broad operation wavelength range, fast response, and high selectivity [4], [5].…”

Section: Introductionmentioning

confidence: 99%

Multi-Objective Optimization of Chiral Metasurface for Sensing Based on a Distributed Algorithm

Liao,

Gui,

et al. 2024

IEEE Photonics J.

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We propose a distributed multi-objective optimization (DMO) method for designing chiral plasmonic metasurface that satisfies multiple objectives simultaneously. We aim to improve the refractive index sensitivity of the archetypical Born-Kuhn type chiral plasmonic metasurface while ensuring that circular dichroism (CD) is as pronounced as possible at a designated resonance wavelength. By leveraging distributed technology, the proposed method significantly improves the time efficiency of the optimization process. The simulation results demonstrate approximately 33% enhancement in sensitivity by DMO, as well as greater than 100% boost in time efficiency compared to stand-alone optimization approaches. These findings highlight the potential of the proposed method to guide the design of chiral plasmonic metasurface sensors, enabling the simultaneous optimization of multiple objectives and facilitating advancements in chiral optics and sensing applications.

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Linear and Nonlinear Optical Field Manipulations with Multifunctional Chiral Coding Metasurfaces

Cited by 12 publications

References 45 publications

High-Q and Intense Lattice Plasmon Resonance in Hexagonal Nonclose Packed Thin Silver Nanoshells Array

High-Q and Intense Lattice Plasmon Resonance in Hexagonal Nonclose Packed Thin Silver Nanoshells Array

Multichannel Linear and Nonlinear Information Encryptions with Malus Metasurfaces

Multi-Objective Optimization of Chiral Metasurface for Sensing Based on a Distributed Algorithm

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