Coherent Perfect Diffraction in Metagratings

Zhang, Ziying; Kang, Ming; Zhang, Xueqian; Feng, Xi; Xu, Yuehong; Chen, Xieyu; Zhang, Huifang; Xu, Quan; Tian, Zhen; Zhang, Weili; Krasnok, Alex; Han, Jiaguang; Alù, Andrea

doi:10.1002/adma.202002341

Cited by 37 publications

(27 citation statements)

References 45 publications

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“…[26][27][28] Currently, both BICs and EPs in metasurfaces have been mostly focused on the manipulation of the spectral/temporal properties of the impinging optical signals, namely, to control the zeroth diffraction-order transmission/reflection features for incident plane waves. [10][11][12][13][23][24][25] In parallel, few-diffraction-order (FDO) metagratings, capable of suppressing undesired diffraction orders and redirecting the incident power to preferred directions with unitary efficiency, have been developed for efficient and extreme wavefront engineering with less spatial resolution demand [29][30][31][32][33][34][35][36][37][38][39][40] when compared with conventional phase-gradient metasurfaces. [41,42] In this paper, we introduce a platform to control the emergence of BICs and EPs near the Brillouin edge of an FDO metagrating, tailoring the diffraction spectra in extreme ways.…”

Section: Introductionmentioning

confidence: 99%

Extreme Diffraction Control in Metagratings Leveraging Bound States in the Continuum and Exceptional Points

Deng

et al. 2022

Laser & Photonics Reviews

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Coupled resonances in non‐Hermitian systems can lead to exotic optical features, such as bound states in the continuum (BICs) and exceptional points (EPs), which have been recently emerged as powerful tools to control the propagation and scattering of light. Yet, similar tools to control diffraction and engineer spatial wavefronts have remained elusive. Here, it is shown that, by operating a metagrating around BICs and EPs, it is possible to achieve an extreme degree of control over coupling to different diffraction orders. Subwavelength metallic slit arrays stacked on a metal‐insulator‐metal waveguide, enabling a careful control of the coupling between localized and guided modes are explored. By tuning the coupling strength from weak to strong, the overall spectral response can be tailored and the emergence of singular features, like BICs and EPs can be enabled. Perfect unitary diffraction efficiency with large spectrum selectivity is achieved around these singular features, with promising applications for selective wavefront shaping, filtering, and sensing.

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Section: Introductionmentioning

confidence: 99%

Extreme Diffraction Control in Metagratings Leveraging Bound States in the Continuum and Exceptional Points

Deng

et al. 2022

Laser & Photonics Reviews

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“…However, more complicated designs are required to manage the diffraction of more propagating modes. Some researchers introduce more degrees of freedom with extra inclusions in each period [4], [30], [32], [43], which complicates the theory and structure, as the mutual couplings among the inclusions are difficult to rigorously analyze. Some researchers use iterative optimization methods to design metagratings based on multimode geometrical structures [18], [33], which needs a lot of simulation iterations, and the optimized performance may differ depending on the specific application and the optimization algorithm.…”

Section: Introductionmentioning

confidence: 99%

Discrete Huygens' Metasurface: Realizing Anomalous Reflection and Diffraction Mode Circulation with a Robust, Broadband and Simple Design

Chu¹,

Wong²

2022

Preprint

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Metasurfaces composed of subwavelength unit cells usually require a large number of unit cells which leads to complicated design and optimization. Aggressive discretization in a metasurface can significantly reduce the number of unit cells within a period, resulting in lower requirement for phase and/or surface impedance coverage. Additionally, the enlarged unit cells will encounter negligible mutual couplings when combined together, hence making straightforward the process of metasurface design. These advantages combine to allow the design of a novel class of metasurfaces which support the high efficiency redirection of electromagnetic (EM) waves over a wide bandwidth and operation angle. Moreover, an aggressively discretized metasurface may realize functionalities such as diffraction mode circulation, which are unsupported in its continuous counterparts. In this paper we propose a simple transmissive metasurface which can realize diffraction mode circulation by refracting plane waves with incident angles of −45 • , 0 • , 45 • to plane waves with refraction angles of 0 • , 45 • , −45 • respectively. The power efficiency of each anomalous refraction is more than 80% at the design frequency of 28 GHz, and the 3-dB power efficiency bandwidth is 11%. We fabricated and measured the metasurface, the experiment results agree well with simulation results.

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“…Coherent interference, as a fundamental phenomenon of electromagnetic waves, is utilized to construct the light intensity modulation and numerous optical devices rely on the interference operation, such as interferometers, optical antennae, spectrometers, coherent perfect absorption, etc. [1][2][3][4][5][6][7] During the last decade, ultrathin films stacks by metal−insulator−metal (MIM) has been proposed and extensively studied based on In addition to grayscale imaging encryption/concealment, such DFP nanocavity design also allows for near-field grayscale nanoprinting with far-field holographic multiplexing. By spatially designing the stepwise DFP cavity, it creates the simultaneous manipulation reflection intensity and phase shift, which essentially achieves the dual-channel for imaging information storage and multiplexing: a near-field grayscale image and a far-field holographic image.…”

Section: Introductionmentioning

confidence: 99%

Stepwise Dual‐Fabry–Pérot Nanocavity for Grayscale Imaging Encryption/Concealment with Holographic Multiplexing

Dai

Wan

et al. 2021

Advanced Optical Materials

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the interference effect from lossy Fabry− Pérot (FP) cavity, which achieves perfect absorption, [8,9] colorful transmission [10][11][12] and could be integrated into functional optic devices. [13][14][15][16][17][18] By tuning the core insulator thickness, such MIM cavity offers the customizability for operation wavelength. Comparing to the traditional lossless FP cavity, [19,20] the MIM nanocavity utilizes the boundary lossy characteristics, thus enabling destructive interference for perfect absorption. [21] The simple film stack provides cost-effective and large-area fabrication with satisfactory optical performance in comparison to the counterpart of complex-shaped photonic nanoresonators. [22][23][24] Despite the highlight of revealing different coloring for nanoprinting application, [25][26][27][28] such triple-layered nanocavity lacks the ability to bring in multiple intensity stepwise for grayscale imaging exhibition. When it comes to the grayscale imaging demand for continuous intensity modulation, the MIM nanocavity cannot perform but instead dramatically change its reflection intensity from zero to unity within only ≈30 nm cavity thickness change. Moreover, MIM stack has seldom been demonstrated with multiplexing functionality for both near-field nanoprinting and holographic imaging due to its close correlation and mutual dependence between its reflection intensity and phase shift.Here, we propose a stepwise design for dual-Fabry-Pérot (DFP) nanocavity constructed by multilayer metal-insulatormetal-insulator-metal (MIMIM) to achieve grayscale imaging encryption/concealment with holographic multiplexing functionality. By stacking DFP cavities with controlling each cavity thickness, we enable that the reflected intensity and resonant wavelength (coloring) could simultaneously be modulated. Specifically, the dimension of top FP cavity determines its operation wavelength, while the bottom FP cavity determines the reflection grayscale intensity. Our proposed DFP scheme is theoretically and experimentally demonstrated to enable encrypt or conceal a meticulous grayscale image via making stepwise DFP patterns, as shown in Figure 1.

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Coherent Perfect Diffraction in Metagratings

Cited by 37 publications

References 45 publications

Extreme Diffraction Control in Metagratings Leveraging Bound States in the Continuum and Exceptional Points

Extreme Diffraction Control in Metagratings Leveraging Bound States in the Continuum and Exceptional Points

Discrete Huygens' Metasurface: Realizing Anomalous Reflection and Diffraction Mode Circulation with a Robust, Broadband and Simple Design

Stepwise Dual‐Fabry–Pérot Nanocavity for Grayscale Imaging Encryption/Concealment with Holographic Multiplexing

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