Spectral imaging of flexible terahertz coding metasurface

Wang, Taofeng; Chen, Benwen; Wu, Jingbo; Yang, Shengxin; Shen, Ze Xiang; Cai, Jiacheng; Li, Weili; Zhang, Caihong; Jin, Biaobing; Chen, Jian; Wu, Peiheng

doi:10.1063/5.0043481

Cited by 13 publications

(7 citation statements)

References 41 publications

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“…In the first sample, the +1 and −1 diffraction orders share an energy ratio of 1:2, as illustrated in Figure d. Although they are the most common diffraction orders, the energy of the beams is usually equal in the current literature. ,,, According to eqs and , the number of unit cells in a period is set to s = 2|1 – (−1)| = 4. Then, we put the unit number and preset ratio together into eq and set the phase difference between the two beams to π/2.…”

Section: Resultsmentioning

confidence: 99%

“…This design method can also be regarded as a discrete continuous grating, but it is more straightforward and easy to accomplish. − However, it has some limitations in applications. Most studies focus only on the one single diffraction order where the incident wave can be reflected or refracted in a single target direction. − When multiple beams pointing in different directions are desired, the existing PGM-based method that only modulates a phase response is not capable of efficiently simulating different diffraction orders. , The excited beams are still in the same order mode, and their corresponding energy distribution cannot be arbitrarily controlled. , In addition, an excited low-order mode may produce a high-order mode in the opposite direction beyond the critical angle θ c which can be explained by the Fabry–Pérot resonator mechanism . Although introducing amplitude modulation in the PGM approach can allow achieving different diffraction orders and arbitrary energy ratios, a part of the incident energy will be inevitably lost in such a procedure due to the normalization of the superimposed complex reflection or transmission coefficients. − …”

Section: Introductionmentioning

confidence: 99%

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Perfect Control of Diffraction Patterns with Phase-Gradient Metasurfaces

Wang

Yuan

Yang

et al. 2022

ACS Appl. Mater. Interfaces

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Phase-gradient metasurfaces (PGMs) constitute an efficient platform for deflection of a beam in a desired direction. According to the generalized Snell's law, the direction of the reflected/refracted wave can be tuned by the spatial phase function provided by the PGMs. However, most studies on PGM focus only on a single diffraction order, that is, the incident wave can be reflected or refracted to a single target direction. Even in the case of multiple beams pointing in different directions, the beams are still in the same order mode, and the energy carried by different beams cannot be controlled. In addition, the energy ratio of multiple beams is generally uncontrollable. Here, we propose a general method to perfectly control diffraction patterns based on a multi-beam PGM. An analytical solution for arbitrarily controlling diffraction beams is derived through which the generation and energy distribution in high-order diffraction beams can be achieved. Three metasurfaces with different diffraction orders and energy ratios are designed and fabricated to demonstrate the proposed method. The efficiencies of diffraction for the desired channels are close to 100%. The simulated and measured far-field patterns are in good agreement with theoretical predictions, validating the proposed method that provides a new way to design multi-beam antennas and that has significance in wireless communication applications.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Perfect Control of Diffraction Patterns with Phase-Gradient Metasurfaces

Wang

Yuan

Yang

et al. 2022

ACS Appl. Mater. Interfaces

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“…proposed an H-shaped resonator metasurface that achieved effective and versatile control of spoof surface plasmon polaritons 19 . In recent years, coding metasurfaces have received significant attention in the terahertz frequency band, with applications including terahertz beam deflection, 20 – 24 spectral imaging, 25 – 27 polarization manipulation, 28 – 31 focusing, 32 – 34 and other functionalities. In 2020, Chen et al.…”

Section: Introductionmentioning

confidence: 99%

Multi-frequency terahertz coding metasurfaces based on vanadium dioxide

Li,

Qin,

Wang

et al. 2024

Opt. Eng.

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Drawing upon the principles of digital coding metasurfaces, we propose the double-split ring resonators coding metasurface that can switch between different frequency bands with varying amplitudes. Under transverse-magnetic (TM) polarized terahertz wave incidence, the same metasurface meta-atom structure utilizes amplitude coding to achieve spatial imaging functionality. Due to limitations in device size and fabrication techniques, actively controlled coding metasurfaces in the terahertz frequency range are rare. In order to enhance the flexibility of terahertz coding metasurfaces, a phase-change material, vanadium dioxide (VO 2 ), is introduced for active control within the metasurface structure. The imaging functionality can be switched by a single switching metasurface, achieved by the phase transition characteristics between the insulating and metallic states of VO 2 . Therefore, the designed coding metasurface, which is based on the influence of VO 2 on amplitude, provides a new approach for flexible control of terahertz waves. It holds great prospects for significant applications in terahertz transmission, communication, and other emerging terahertz-related fields.

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“…As such, flexible BIC metasurfaces offer a versatile platform for efficient light manipulation and open up a new range of applications. 25,26 To date, although much research has focused on the structure design of BIC metasurfaces, [27][28][29][30] much less effort has been made to explore flexible BIC metasurfaces, which promise great potential both for fundamental study and photonic applications.…”

Section: Introductionmentioning

confidence: 99%