Regenerated amplification of terahertz spoof surface plasmon radiation

Zhu, Juan‐Feng; Du, Chao‐Hai; Bao, Luyao; Liu, Pu-Kun

doi:10.1088/1367-2630/ab0aa4

Cited by 16 publications

(10 citation statements)

References 35 publications

(40 reference statements)

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“…As an important SSP waveguide and interaction circuit, a metallic grating formed by single rectangular groove arrays has been proposed to develop free-electron-driven high-power radiation or amplifier sources [ 34 , 35 , 36 , 37 ]. It is shown that the SSP mode can be effectively excited and gradually amplified by an injected electron beam both on uniform and gradient meta-structures.…”

Section: Introductionmentioning

confidence: 99%

Excitation of Terahertz Spoof Surface Plasmons on a Roofed Metallic Grating by an Electron Beam

Liu,

Zhang,

Wang

et al. 2024

Micromachines

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In this paper, both fundamental SSP modes on a roofed metallic grating and its effective excitation of the bounded SSP mode by an injected electron beam on the structure are numerically examined and investigated in the THz regime. Apart from the bounded SSP mode on the metallic grating with open space, the introduced roofed metallic grating can generate a closed waveguide mode that occupies the dispersion region outside the light line. The closed waveguide mode shifts gradually to a higher frequency band with a decreased gap size, while the bounded SSP mode line becomes lower. The effective excitation of the bounded SSP mode on this roofed metallic grating is also implemented and studied by using a particle-in-cell simulation studio. The output SSP power spectrums with various gap sizes by the same electron beam on this roofed metallic grating are obtained and analyzed. The simulation results reveal that the generated SSP spectra show a slight red shift with a decreased gap size. This work on the excitation of the SSP mode using an electron beam can benefit the development of high-power compact THz radiation sources by utilizing the strong near-field confinement of SSPs on metallic gratings.

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Section: Introductionmentioning

confidence: 99%

Excitation of Terahertz Spoof Surface Plasmons on a Roofed Metallic Grating by an Electron Beam

Liu,

Zhang,

Wang

et al. 2024

Micromachines

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“…Recently, extensive interest has also been attracted to its interaction with electron bunches for active applications. When a bunch of electrons parallelly fly over holy-structured metal surfaces (or various transformed structures), high-power coherent DSPP can be excited according to the Cherenkov condition [36][37][38], which is fundamentally different from that of Smith-Purcell radiation originating from zone folding [39][40][41][42]. The generated Cherenkov DSPP can only propagate along the metal surface, but has not been coupled out of the surface to form radiations.…”

Section: Introductionmentioning

confidence: 99%

Designer Surface Plasmons Enable Terahertz Cherenkov Radiation (Invited)

Zhang¹,

Hu²,

Chen³

et al. 2020

PIER

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Cherenkov radiation (CR) is a promising method to generate high-power terahertz (THz) electromagnetic (EM) waves, which are highly desired in numerous practical applications. For the purpose of economy energy, naturally occurred materials with flat surface (e.g., graphene), which can support highly-confined surface-plasmon-polariton (SPP) modes, have been proposed to construct high-efficiency terahertz CR source; however, these emerging materials cannot be easily fabricated nor flexibly designed. Here, we propose a designer-SPP metamaterial scheme to pursue terahertz CR. The metamaterial is a structure-decorated metal surface, which is compatible with planar fabrication and can support SPP-like EM modes in terahertz frequencies, also named as designer SPP. Due to the structure dependence of designer SPP, its dispersions can be flexibly designed by changing the structure geometries as well as choosing proper dielectric medias. Numerical results clearly demonstrated this scheme. Our proposal may promise future high-efficiency and intense THz source with design flexibilities.

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“…However, within their limited choices, natural plasmonic materials often suffer from intrinsic high loss. , Besides, when the frequency comes to microwave and terahertz regimes, plasmonic effects of most materials become negligible, and the metals behave as perfect electric conductors. − To develop the low-loss and flexible plasmons at low frequencies, the concepts of spoof surface plasmon polaritons (SSPPs) and effective surface plasmon polaritons (ESPPs), are respectively developed by periodically texturing the geometry of metals and tailoring the structural dispersion of electromagnetic (EM) modes in bounded waveguides. These methodologies have provided enormous possibilities in sensing, , focusing, , guiding, − on-chip sources, generating vortex beams, , and novel applications based on controlling waves in subwavelength scale. − Recently, we also proposed the spatial spectrum sampling by SSPPs, a method for retrieving the broadband evanescent information on targets and realizing subwavelength resolution imaging. Here, the SSPPs structure was employed as a sensitive spatial filter.…”

mentioning

confidence: 99%

“…23−25 To develop the low-loss and flexible plasmons at low frequencies, the concepts of spoof surface plasmon polaritons (SSPPs) 26 and effective surface plasmon polaritons (ESPPs), 27 are respectively developed by periodically texturing the geometry of metals and tailoring the structural dispersion of electromagnetic (EM) modes in bounded waveguides. These methodologies have provided enormous possibilities in sensing, 28,29 focusing, 30,31 guiding, 32−34 on-chip sources, 35 generating vortex beams, 36,37 and novel applications based on controlling waves in subwavelength scale. 38−41 Recently, we also proposed the spatial spectrum sampling by SSPPs, 42 a method for retrieving the broadband evanescent information on targets and realizing subwavelength resolution imaging.…”

mentioning

confidence: 99%

Amplifying Evanescent Waves by Dispersion-Induced Plasmons: Defying the Materials Limitation of the Superlens

et al. 2020

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Breaking the diffraction limit is always an appealing topic owing to the urge for a better imaging resolution in almost all the areas. As an efficient solution, the superlens based on the plasmonic effects can resonantly amplify evanescent waves, the lost treasure, and reach the subwavelength resolution. However, the natural plasmonic materials, within their limited choices, usually have inherently high loss and are only available from the infrared to visible wavelengths. In this work, we demonstrate that arbitrary materials, even air, can be applied to enhance the evanescent waves and build the superlens with low loss at desired frequency. The working mechanisms reside in the dispersion-induced effective plasmons in a bounded waveguide structure, where materials with only positive permittivity is used. By using the air as an effective plasmonic material in a parallel-plate waveguide, the broadband enhancement of evanescent waves and the ability to beat the diffraction limit are well verified at microwave frequency. As a specified realization, we further constructed and experimentally investigate the more practicable hyperbolic metamaterials (HMM) by stack of air and dielectric layers. The validity of HMM is verified by the directional

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Regenerated amplification of terahertz spoof surface plasmon radiation

Cited by 16 publications

References 35 publications

Excitation of Terahertz Spoof Surface Plasmons on a Roofed Metallic Grating by an Electron Beam

Excitation of Terahertz Spoof Surface Plasmons on a Roofed Metallic Grating by an Electron Beam

Designer Surface Plasmons Enable Terahertz Cherenkov Radiation (Invited)

Amplifying Evanescent Waves by Dispersion-Induced Plasmons: Defying the Materials Limitation of the Superlens

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