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1. Recent Advances in Metasurface Design and Quantum Optics Applications with Machine Learning, Physics-Informed Neural Networks, and Topology Optimization Methods

Author

Ji, Wenye, Chang2, Jin, Xu, He-Xiu, Gao, Jian Rong, Gröblacher, Simon, Urbach, Paul, and Adam, Aurèle J. L.

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

As a two-dimensional planar material with low depth profile, a metasurface can generate non-classical phase distributions for the transmitted and reflected electromagnetic waves at its interface. Thus, it offers more flexibility to control the wave front. A traditional metasurface design process mainly adopts the forward prediction algorithm, such as Finite Difference Time Domain, combined with manual parameter optimization. However, such methods are time-consuming, and it is difficult to keep the practical meta-atom spectrum being consistent with the ideal one. In addition, since the periodic boundary condition is used in the meta-atom design process, while the aperiodic condition is used in the array simulation, the coupling between neighboring meta-atoms leads to inevitable inaccuracy. In this review, representative intelligent methods for metasurface design are introduced and discussed, including machine learning, physics-information neural network, and topology optimization method. We elaborate on the principle of each approach, analyze their advantages and limitations, and discuss their potential applications. We also summarise recent advances in enabled metasurfaces for quantum optics applications. In short, this paper highlights a promising direction for intelligent metasurface designs and applications for future quantum optics research and serves as an up-to-date reference for researchers in the metasurface and metamaterial fields.

Published
2023

3. Multichannel full-space coding metasurface with linearly-circularly-polarized wavefront manipulation

Author

Luo Huiling, Gao Huanhuan, Wang Yanzhao, Wang Chaohui, Zhang Fan, Shao Yanzhang, Liu Tong, Wang Zhengjie, and Xu He-Xiu

Subjects
multichannel coding metasurface, full space, wavefront control, shared aperture, linearly-circularly-polarized, Physics, QC1-999
Abstract

Achieving independent multitasked wavefront control by using an ultrathin plate is a challenge to increase information capacity in integration optics and radar applications. Transmission-reflection-integrated metasurface provides an efficient recipe primarily for multifunctional meta-device, however it is challenging to synergize both linear polarization (LP) and circular polarization (CP) using a single meta-plate. Here, a multichannel full-space coding metasurface composed of interleaved shared-aperture meta-atom is proposed to achieve large information capacity by capsulating judiciously engineered high efficiency triple sub-elements (modes) in four-layer scheme. By rotating dual-gap split ring resonator and varying size of “L” type structure insulating by a metallic ring with electrostatic-analogue shielding effect, both Pancharatnam–Berry (PB) and dynamic phases are independently realized under CP and LP waves, respectively. Such an extraordinary insulating strategy completely suppresses crosstalk among three modes and unprecedentedly increases the capability in yielding kaleidoscopic wavefront control. To verify the significance, a proof-of-concept metadevice is devised and experimentally demonstrated with tri-channel wavefront manipulations, exhibiting reflective dual-vortex beam and Bessel beam for forward and backward CP wave, respectively at high frequency, while transmissive polarization beam splitting for 45°-LP wave at low frequency. Our finding in polarization-direction multiplexing is expected to generate great interest in electromagnetic integration with emerging degree of freedoms.

Published
2024
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4. Holographic communication using programmable coding metasurface

Author

Zhang Fan, Wang Chaohui, Feng Weike, Liu Tong, Wang Zhengjie, Wang Yanzhao, Wang Mingzhao, and Xu He-Xiu

Subjects
holographic communication, spin-decoupled, programmable coding metasurface, near-field communication, Physics, QC1-999
Abstract

With rapid development of holography, metasurface-based holographic communication scheme shows great potential in development of adaptive electromagnetic function. However, conventional passive metasurfaces are severely limited by poor reconfigurability, which makes it difficult to achieve wavefront manipulations in real time. Here, we propose a holographic communication strategy that on-demand target information is firstly acquired and encoded via a depth camera integrated with modified YOLOv5s target detection algorithm, then transmitted by software defined radio modules with long term evolution at 5 GHz, and finally reproduced in the form of holographic images by spin-decoupled programmable coding metasurfaces at 12 GHz after decoding through modified Gerchberg–Saxton algorithm. Experiments are conducted to demonstrate the brand-new concept of optical information conversion to electromagnetic one via above intelligent scheme. Our strategy may open a novel avenue toward applications of near-field communication based on adaptive variation of electric field patterns (i.e. holographic images).

Published
2024
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5. Colored thermal camouflage and anti-counterfeiting with programmable In3SbTe2 platform

Author

Zhou Sihong, Dong Shikui, Guo Yanming, Shuai Yong, Xu He-Xiu, and Hu Guangwei

Subjects
ist phase change material, industry-friendly platform, resonance mode coupling, vis-ir compatible camouflage, thermal anti-counterfeiting, Physics, QC1-999
Abstract

Camouflage is an important technology in various scenarios. Usually, this involves the visible compatibility of the background, which however is facile under infrared thermal radiation detection. The simultaneous visible and thermal camouflage are challenging because it requires full and decoupled manipulations of visible reflection and infrared emissivity using one single device, let alone to its adaptivity to complex environments. Here, we report a programmable, colored thermal camouflage at 3–5 μm and 8–14 μm based on mode coupling in phase-change In3SbTe2 materials. A series of industry-friendly colored multilayer thermal emitters are designed consisting of an anti-reflectance layer for structure coloration above a coupled nanocavity for IR modulation, which easily realizes the complete decoupled control of visible color and infrared emissivity. Our solution features independent structural visible colors in the full visible range and continuously programmable dual-band emissivity modulation with up to 90 % absolute tuning range. Our work facilitates near optimal camouflage and anti-counterfeiting solution for visible-infrared multi-band compatibility of complex environments under different temperatures and colored appearances.

Published
2024
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7. Programmable metasurface for front-back scattering communication

Author

Li Haipeng, Xin Kewei, Ding Haiyang, Li Tangjing, Hu Guangwei, and Xu He-Xiu

Subjects
amplitude reconfigurability, front-back scattering communication, polarization conversion, programmable metasurface, Physics, QC1-999
Abstract

Achieving high-efficient and low-power communication is pivotal yet very challenging in the emerging technologies. Unlike conventional backscatter communication system, we propose and demonstrate an amplitude-reconfigurable metasurface loaded with PIN diodes to build a front-back scattering communication transmitter, which features the exclusive advantages of full-space secondary modulation of the ambient signals with high energy utilization efficiency. Meanwhile, this device can eliminate the interference originated from the ambient source by polarization conversion in the transmission channel. At a modulation rate of 800 kbps and a distance of 80 m, our system can achieve distortion-free transmission of a picture with size of 200 × 200 pixels. In addition, multiple amplitude-shift-keying modulation is also realized by segmenting the metasurface to further increase the communication rate. Due to the advantages of high spectral efficiency and low energy consumption, this system can be widely used in future engineering applications for the internet of things, especially for smart home, agriculture environmental monitoring, wearable sensing and others.

Published
2023
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8. Full-space spin-decoupled versatile wavefront manipulations using non-interleaved metasurface

Author

Wang Chaohui, Xu He-Xiu, Hu Guangwei, Liu Yi, Liu Tong, Wang Kun, Zhang Fan, Xu Shuo, Xu Jian, and Pang Zhichao

Subjects
full-space, multifunctional metasurface, spin-decoupled, transmission, wavefront manipulations, Physics, QC1-999
Abstract

Achieving multifunctional wavefront manipulations of waves with a flat and thin plate is pivotal for high-capacity communications, which however is also challenging. A multi-layer metasurface with suppressed mode crosstalk provides an efficient recipe primarily for circular polarization, but all multiple functionalities still are confined to locked spin states and modes. Here, a multifunctional metasurface with spin-decoupled full-space wavefront control is reported by multiplexing both linear momentum and frequency degree of freedom. We employed vertically cascaded quadrangular patches and crossbars to integrate both geometric and dynamic phases and realized four channels between two spin states and two frequencies in distinct scattering modes (transmission and reflection). For verification, a proof-of-concept metadevice with four-port wavefront manipulations is experimentally demonstrated, exhibiting distinct functionalities including spin- and frequency-dependent focusing, quad-beam radiation, anomalous reflections, and Bessel beam generation. Our finding of full-space spin-decoupled metasurfaces would be important for high-capacity communications, multifunctional radar detections, and other applications.

Published
2023
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14. Balanced-ternary-inspired reconfigurable vortex beams using cascaded metasurfaces

Author

Liu Ji, Qi Jurui, Yao Jin, Hu Wenman, Zhang Dajun, Xu He-Xiu, and Wang Xiong

Subjects
balanced ternary system, broadband vortex beams, cascaded metasurfaces, high-order vortex beams, reconfigurable generation of vortex beams, vortex beams, Physics, QC1-999
Abstract

Electromagnetic vortex carries the orbital angular momentum, one of the most fundamental properties of waves. The order of such vortex can be unbounded in principle, thus facilitating high-capability wave technologies for optical communications, photonic integrated circuits and others. However, it remains a key challenge to generate the high-order vortex beams in a reconfigurable, broadband and cost-effective manner. Here, inspired by the balanced-ternary concept, we demonstrate the reconfigurable generation of order-controllable vortices via cascaded N-layer metasurfaces. We theoretically showed that 3N−1${3}^{N}-1$ different vortex modes can be generated by cascading N metasurfaces, each one serving as an individual vortex beam generator for the order of 3k${3}^{k}$ (k = 0,1,2 …, N−1$N-1$). As a proof-of-concept demonstration, a reconfigurable generation of 26 different vortex beams, with orders from 1 to 13 and from −1 to −13, is showcased in a broad millimeter-wave region by a cascade of 3 metasurfaces. Our method can be easily extended to vortex beam generator of arbitrary orders in a reconfigurable and easily implementable manner, paving a new avenue towards tremendous practical applications.

Published
2022
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16. Metasurfaces for Polarization-Insensitive and Directional Backscatter Communications

Author

Li, Haipeng, Xin, Kewei, Han, Jiaqi, Ding, Haiyang, Liu, Chaoyang, Wang, Fei, Liu, Xiaowen, Wang, Letian, and Xu, He-Xiu

Abstract

Achieving low-power and polarization-insensitive communication is a crucial and challenging task in the Internet of Everything. In this communication, we propose and demonstrate the implementation of two amplitude-reconfigurable metasurfaces, loaded with p-i-n diodes and operated around 5.8 GHz, to develop a novel polarization-insensitive backscatter communication (BC) system. Both communication transmitters using uniform and gradient metasurfaces are able to achieve high-efficiency polarization conversion and thus can cooperate with the receiver end to mitigate the interference generated by environmental carrier sources. To achieve the directional information transmission, we design a corner reflector metasurface and a gradient metasurface, which, respectively, enhances the gain in the backward and fixed scattering directions. Due to the advantages of polarization insensitivity and low energy consumption, this system promises great potential for future engineering applications in the Internet of Things, particularly for smart homes, wearable sensing, and other related areas.

Published
2024
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18. Colored thermal camouflage and anti-counterfeiting with programmable In3SbTe2 platform.

Author

Zhou, Sihong, Dong, Shikui, Guo, Yanming, Shuai, Yong, Xu, He-Xiu, and Hu, Guangwei

Subjects
STRUCTURAL colors, INFRARED radiation, HEAT radiation & absorption, PHASE change materials, EMISSIVITY
Abstract

Camouflage is an important technology in various scenarios. Usually, this involves the visible compatibility of the background, which however is facile under infrared thermal radiation detection. The simultaneous visible and thermal camouflage are challenging because it requires full and decoupled manipulations of visible reflection and infrared emissivity using one single device, let alone to its adaptivity to complex environments. Here, we report a programmable, colored thermal camouflage at 3–5 μm and 8–14 μm based on mode coupling in phase-change In3SbTe2 materials. A series of industry-friendly colored multilayer thermal emitters are designed consisting of an anti-reflectance layer for structure coloration above a coupled nanocavity for IR modulation, which easily realizes the complete decoupled control of visible color and infrared emissivity. Our solution features independent structural visible colors in the full visible range and continuously programmable dual-band emissivity modulation with up to 90 % absolute tuning range. Our work facilitates near optimal camouflage and anti-counterfeiting solution for visible-infrared multi-band compatibility of complex environments under different temperatures and colored appearances. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Recent advances in metasurface design and quantum optics applications with machine learning, physics-informed neural networks, and topology optimization methods

Author

Ji, W. (author), Chang, J. (author), Xu, He Xiu (author), Gao, J.R. (author), Groeblacher, S. (author), Urbach, Paul (author), Adam, A.J.L. (author), Ji, W. (author), Chang, J. (author), Xu, He Xiu (author), Gao, J.R. (author), Groeblacher, S. (author), Urbach, Paul (author), and Adam, A.J.L. (author)

Abstract

As a two-dimensional planar material with low depth profile, a metasurface can generate non-classical phase distributions for the transmitted and reflected electromagnetic waves at its interface. Thus, it offers more flexibility to control the wave front. A traditional metasurface design process mainly adopts the forward prediction algorithm, such as Finite Difference Time Domain, combined with manual parameter optimization. However, such methods are time-consuming, and it is difficult to keep the practical meta-atom spectrum being consistent with the ideal one. In addition, since the periodic boundary condition is used in the meta-atom design process, while the aperiodic condition is used in the array simulation, the coupling between neighboring meta-atoms leads to inevitable inaccuracy. In this review, representative intelligent methods for metasurface design are introduced and discussed, including machine learning, physics-information neural network, and topology optimization method. We elaborate on the principle of each approach, analyze their advantages and limitations, and discuss their potential applications. We also summarize recent advances in enabled metasurfaces for quantum optics applications. In short, this paper highlights a promising direction for intelligent metasurface designs and applications for future quantum optics research and serves as an up-to-date reference for researchers in the metasurface and metamaterial fields., ImPhys/Adam group, QN/Groeblacher Lab, QN/Quantum Nanoscience, ImPhys/Urbach group

Published
2023
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33. Deterministic Approach to Achieve Full-Polarization Cloak

Author

Xu, He-Xiu, primary, Wang, Yanzhao, additional, Wang, Chaohui, additional, Wang, Mingzhao, additional, Wang, Shaojie, additional, Ding, Fei, additional, Huang, Yongjun, additional, Zhang, Xiaokuan, additional, Liu, Haiwen, additional, Ling, Xiaohui, additional, and Huang, Wei, additional

Published
2021
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39. Microstrip approach benefits quad splitter: the use of composite right/left-handed transmission line structure in the form of novel complementary split-ring resonators can help form a broadband, miniature quadrature power splitter

Author

Xu, He-Xiu, Wang, Guang-Ming, Zhang, Chen-Xin, and Hu, Yong

Subjects
Broadband transmission, Broadband Internet, Business, Electronics and electrical industries, Engineering and manufacturing industries
Abstract

Quadra power splitters with their 90-deg phase difference between output ports, are useful components in communitions. They can be used, for example, to realize amplifiers, phase shifters, and balanced mixers [...]

Published
2010

40. Reconfigurable linear polarization conversion based on spatial-order kirigami metasurfaces

Author

Xu He-Xiu, Wang Shao-Jie, and Wang Ming-Zhao

Subjects
Physics, business.industry, Linear polarization, Degrees of freedom (statistics), PIN diode, General Physics and Astronomy, Polarization (waves), law.invention, Split-ring resonator, law, Optoelectronics, business, Electrical tuning, Varicap, Electronic circuit
Abstract

With the development of intelligent technology, it is essential to develop polarization-conversion devices with adaptable electromagnetic (EM) performance for practical applications. Up to now, most of attempts have relied on PIN diodes and varactor diodes for electrical tuning, typically featuring simplicity and timelineness. However, the shortcomings are also notable, such as less degrees of freedom (DoFs), more complex circuits and more expensive. In view of this, here we propose a kind of spatial-order metasurface for reconfigurable polarization conversion based on kirigami concept. By adjusting the folding angle β, the interaction between neighboring dipoles can be progressively changed and thus the operation frequency of polarization conversion can be shifted. Such a mechanical reconfigurable strategy brings about more DoFs for tuning and is cheaper and extraordinary convenient in practice. To verify the feasibility of our concept, a proof-of-concept spatial-order kirigami metasurface is proposed for the dual-band reconfigurable linear polarization conversion based on asymmetric chiral split ring resonators (SRRs). Experimental results show that the linear polarization operates at 5 and 5.8 GHz when folding angle is β = 10°, these frequencies are shifted to 5.8 and 7.2 GHz when β = 45°: a tuning range is expanded by 18.5%. In addition, the Poisson’s ratio and relative density of proposed kirigami metasurface as a function of β are also theoretically analyzed. The results show that the Poisson’s ratio increases with the value of β increasing. The relative density can be reduced to 1.5% of its unfolded planar counterpart. Our spatial-order kirigami metasurface strategy paves the way for implementing the reconfigurable linear polarization conversion and multifunctional devices.

Published
2021

41. Research progress of electromagnetic metamaterial absorbers

Author

Xu He-Xiu, Wang Yan-Zhao, Wang Ming-Zhao, Wang Chao-Hui, and Wang Shao-Jie

Subjects
Computer science, Physics::Optics, General Physics and Astronomy, Metamaterial, Polarization (waves), 01 natural sciences, Engineering physics, Electromagnetic radiation, Wavelength, 0103 physical sciences, Broadband, Metamaterial absorber, 010306 general physics, Absorption (electromagnetic radiation), Focus (optics)
Abstract

Electromagnetic absorbing technology can effectively suppress the radiation of electromagnetic waves, and has been widely used in military and civilian fields. However, traditional absorbing technology cannot meet the new requirements for modern absorbing materials. The advent of metamaterials provides a solution for this problem Metamaterial absorber has the advantages of simple structure, light weight, high absorption rate, and can realize the flexible control of electromagnetic waves, which has led the electromagnetic absorption research to rapidly develop. In this paper, the research and development of using metamaterials to absorb electromagnetic wave is reviewed. Firstly, the principle, implementation, and presently existing bottlenecks of electromagnetic wave absorption in using metamaterials are outlined. Secondly, recent progress of the aforementioned key issues in three aspects is introduced, including multi-band and broadband, polarization and angle independence, and dynamic tunability. Several typical methods of making metamaterial absorbers are illustrated here. Generally speaking, the prerequisite of broadband metamaterial absorbers is to provide multiple resonances that are close enough to each other. The structure with multiple rotationally symmetric geometry is helpful in achieving polarization- and angle-insensitive properties. The flexible control of absorption performance can be realized by introducing lumped elements such as resistances, capacitances, and diodes. In addition, by means of composite traditional materials or new materials and other methods the dynamic adjustment of the absorption performance can be achieved. Although researchers have done a lot of work on the metamaterial absorbers, there remain many problems and challenges. For the future design, several promising directions are suggested from three perspectives: high performance, multifunctionality, and new structures. In terms of high performance, it is still a challenge to achieve ultra-thin broadband metamaterial absorber for low-frequency which can break through the limitation of wavelength. Integrated multifunctional metamaterials can adapt to the increasingly complex application scenarios and should gradually become the focus of attention. Since three-dimensional (3D) printing technology has proved to be applicable to the preparation of complex metamaterial structures, the new 3D metamerial absorbers will bring more vitality to the development of metamaterials. Finally, as regards the application of metamaterials in stealth, the future development of metamaterial absorbers is further summarized.

Published
2020

46. Ultra-Wideband RCS Reduction of Metasurface Antenna Based on Spoof Surface Plasmon Polariton and Transmission

Author

Li, Si-Jia, Cao, Xiang-Yu, Xu, He-Xiu, Zhang, Zhao, Zhou, Yu-Long, Han, Jiang-Feng, Zhang, Chen, Li, Si-Jia, Cao, Xiang-Yu, Xu, He-Xiu, Zhang, Zhao, Zhou, Yu-Long, Han, Jiang-Feng, and Zhang, Chen

Abstract

In this paper, a metasurface antenna with ultra-broadband radar cross section (RCS) reduction was systematically presented and evaluated based on the spoof surface plasmon polariton (SSPP) and transmission. A circular metasurface consisted of twelve gradually increasing two-sided metallic grooves and an ultra-thin dielectric film. The evolutions of dispersion characteristic and near electric-field distributions were adequately demonstrated based on SSPP in simulation. Furthermore, the SSPP metasurface had been loaded on a common waveguide slot antenna. The simulation and laboratory measurements were performed to characterize RCS reduction, radiation patterns and scattering performance. A prototype of metasurface antenna had been fabrication and measurement to demonstrate the characteristics. Experiment data were carried out to verify the simulation results and measured results showed that the metasurface antenna exhibited ultra-wideband RCS reduction from 1 GHz to 10 GHz.

Published
2018

47. Hilbert fractal curves form compact diplexer: by using fractal geometry to fashion transmission lines with composite left-handed and right-handed characteristics, it was possible to construct a compact microwave diplexer

Author

Xu, He-Xiu, Wang, Guang-Ming, and An, He-Ping

Subjects
Microwave devices, Business, Electronics and electrical industries, Engineering and manufacturing industries
Abstract

Metamaterials have shown great promise as substrates for compact RF and microwave filters. By forming composite right/left-handed (CRLH) transmission lines (TLs) on such materials, it is possible to take advantage [...]

Published
2010

49. Compact Metamaterials Induced Circuits and Functional Devices

Author

Xu, He-Xiu

Subjects
Technology & Engineering / Metallurgy
Abstract

In recent years, we have witnessed a rapid expansion of using metamaterials to manipulate light or electromagnetic (EM) wave in a subwavelength scale. Specially, metamaterials have a strict limitation on element dimension from effective medium theory with respect to photonic crystals and other planar structures such as frequency selective surface (FSS). In this chapter, we review our effort in exploring physics and working mechanisms for element miniaturization along with the resulting effects on element EM response. Based on these results, we afford some guidelines on how to design and employ these compact meta-atoms in engineering functional devices with high performances. We found that some specific types of planar fractal or meandered structures are particularly suitable to achieve element miniaturization. In what follows, we review our effort in Section 1 to explore novel theory and hybrid method in designing broadband and dual band planar devices. By using single or double such compact composite right-/left-handed (CRLH) atom, we show that many microwave/RF circuits, i.e., balun, rat-race coupler, power divider and diplexer, can be further reduced while without inducing much transmission loss from two perspectives of lumped and distributed CRLH TLs. In Section 2, we show that a more compact LH atom can be engineered by combining a fractal ring and a meandered thin line. Numerical and experimental results demonstrate that a subwavelength focusing is achieved in terms of smooth outgoing field and higher imaging resolution. Section 3 is devoted to a clocking device from the new concept of superscatterer illusions. To realize the required material parameters, we propose a new mechanism by combining both electric and magnetic particles in a composite meta-atom. Such deep subwavelength particles enable exact manipulation of material parameters and thus facilitate desirable illusion performances of a proof-of-concept sample constructed by 6408 gradually varying meta-atoms. Finally, we summarize our results in the last section.

Published
2017

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