Multiplexed Generation of Generalized Vortex Beams with On‐Demand Intensity Profiles Based on Metasurfaces

Zhang, Xue; Huang, Lingling; Zhao, Ruizhe; Wei, Qunshuo; Li, Xin; Geng, Guangzhou; Li, Junjie; Wang, Yongtian; Zhang, Shuang

doi:10.1002/lpor.202100451

Cited by 34 publications

(26 citation statements)

References 35 publications

(38 reference statements)

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“…Thus, the complex amplitude of the GVB can be expressed as e i φ(θ) . For GVB, the radius R of beam intensity profile in k space is proportional to the phase gradient as Rfalse(θkfalse)∝dnormalφfalse(normalθfalse)dnormalθ with θ k = θ + π/2, which determines the intensity profile ( 41 ).…”

Section: Resultsmentioning

confidence: 99%

“…Here, we propose and demonstrate a previously unexplored approach for diffraction-multiplexed generation of generalized vortex beams (GVBs) based on the linear combination of a few custom-defined basis patterns, by using Dammann vortex metasurface (DVM). As shown previously (41), GVBs have a custom-defined angular phase distribution, i.e., the local angular phase gradient is no longer a constant like the conventional vortex beams. The angular phase distribution directly controls the intensity profiles of the vortex beams.…”

Section: Introductionmentioning

confidence: 95%

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Basis function approach for diffractive pattern generation with Dammann vortex metasurfaces

et al. 2022

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In mathematics, general functions can be decomposed into a linear combination of basis functions. This principle can be used for creating an infinite number of distinct geometric patterns based on a finite number of basis patterns. Here, we propose a Dammann vortex metasurface (DVM) for optically generating an array of diverse, diffraction-multiplexed vortex patterns, based on three custom-defined basis patterns. The proposed DVM, with its capability of quantitatively correlating phase and intensity distribution in different diffraction orders, opens up doors for various applications including orbital angular momentum encryptions and quantum entanglement.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 95%

Basis function approach for diffractive pattern generation with Dammann vortex metasurfaces

et al. 2022

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“…By contrast, multichannel metasurfaces, which is implemented by multiplexing, can encrypt the information in different working modes, thus further enhancing the information security and capacity. For example, different information can be obtained by changing the incident beam's wavelength, [22][23][24] polarization, [25][26][27][28] incident angle, [29] or topological number. [30,31] In addition, some multiplexing works have showcased by encrypting information into different observation spaces [32,33] or spatial frequency.…”

Section: Introductionmentioning

confidence: 99%

Metasurface‐Assisted Indirect‐Observation Cryptographic System

Guan

Liu

et al. 2022

Laser & Photonics Reviews

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Metasurfaces provide a novel platform for information encryption due to their incomparable competence for the manipulation of different optical characteristics. Most current encryption schemes, however, decrypt the hidden information through a direct illumination of the metasurface, and the security of which cannot be fully guaranteed since the number of illumination condition is very limited and vulnerable for exhaustive attack. Herein, a cryptographic system based on the indirect‐observation decryption is proposed, the hidden information of which can only be decoded by combining the metasurface‐transformed ciphertext and particular decryption devices based on the digit‐shift images and spatial light modulator, thus possessing ultra‐high confidentiality. In addition, an anti‐counterfeiting label is designed to guarantee the information authenticity. This work builds a distinct bridge between metasurface and other light‐manipulation elements, nanoprint and hologram, and amplitude‐ and phase‐modulated information, thus opening up a new methodology for constructing cryptographic systems in an indirect‐observation way, which may promote the advanced exploration of optical multiplexing and steganography.

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“…Recently, generalized vortex beams, in which the corresponding intensity profiles have C N -fold discrete rotational symmetry instead of continuous rotational symmetry for conventional vortices, have been demonstrated in free space, because of unique properties in intensity and phase distribution, extending the study of vortex beam and providing a new perspective on controlling the properties of EM waves. For example, Yang et al, [58] have designed geometric metasurfaces encoded with noncanonical vortex phase profile to realize the free-space optical vortex with variable intensity profile, and Zhang et al, [59] have developed metasurfaces for generating multiplexed vortex beams with generated intensity profiles. However, these previous studies focus on the vortex with variable intensity profile in the far field, and the intensity profiles of these generalized vortices are limited to the C N -fold discrete rotational symmetry.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, generalized vortex beams, in which the corresponding intensity profiles have C N− fold discrete rotational symmetry instead of continuous rotational symmetry for conventional vortices, have been realized in free space, extending the study of vortex beam and providing a new perspective on controlling the properties of EM waves. [ 58,59 ] However, these previous studies focus on the vortex with variable intensity profiles in the far field, and the intensity profiles of these generalized vortices are limited to the C N− fold discrete rotational symmetry. Near‐field vortices (that are surface plasmonic vortices) generated by metal‐based structures enable an unprecedented capability in confining, manipulating, and enhancing EM fields at subwavelength mode volumes, and thus, they open a new avenue to significantly reduce the vortex size that can be applied in integrated nanophotonics.…”

Section: Introductionmentioning

confidence: 99%

Terahertz Near‐Field Vortex Beams with Variable Intensity Profiles Based on Geometric Metasurfaces

Zhu

Zhou

Fan

et al. 2022

Advanced Photonics Research

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Electromagnetic waves possessing orbital angular momentum, namely vortex beams, have attracted considerable attention in the fields ranging from optical communications to quantum science, due to their extraordinary information encoding capabilities. Vortex beams are traditionally exhibited with a donut-shaped intensity distribution, where a null intensity center surrounded by a bright ring, caused by the phase singularity. Here we propose and experimentally demonstrate geometric metasurface devices that can generate near-field vortex beams with variable intensity profiles. The generation of a vortex beam with tailored intensity profile is realized by integrating the azimuthal nonlinear phase and spiral phase into the ring-shaped anisotropic air-slit array. As proof-of-principle examples, multiple geometric metasurfaces that generate vortex beams with C N -fold rotational symmetric or asymmetric intensity profile in the near-field are demonstrated in the terahertz domain. This unique capability for terahertz near-field vortex transmutation based on geometric metasurface approach opens an avenue to develop multifunctional integrated systems and system-on-chip devices, holding potential applications in microscopy, integrated photonics, quantum information processing and optical communication.

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Multiplexed Generation of Generalized Vortex Beams with On‐Demand Intensity Profiles Based on Metasurfaces

Cited by 34 publications

References 35 publications

Basis function approach for diffractive pattern generation with Dammann vortex metasurfaces

Basis function approach for diffractive pattern generation with Dammann vortex metasurfaces

Metasurface‐Assisted Indirect‐Observation Cryptographic System

Terahertz Near‐Field Vortex Beams with Variable Intensity Profiles Based on Geometric Metasurfaces

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