Loss Analysis of Plasmonic Metasurfaces Using Field-Network-Joint Method

Structured metallic surfaces, also called as plasmonic surfaces, have been proposed to support spoof surface plasmon polariton (SPP) modes, which can mimic natural SPPs at optical frequencies. Complex plasmonic surfaces can provide a large degree of freedom to engineer the characteristics of SPP dis...

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Veröffentlicht in:IEEE transactions on antennas and propagation 2019-05, Vol.67 (5), p.3521-3526
Hauptverfasser: Zhang, Hao Chi, He, Pei Hang, Gao, Xinxin, Lu, Jiayuan, Cui, Tie Jun, Luo, Yu
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container_issue 5
container_start_page 3521
container_title IEEE transactions on antennas and propagation
container_volume 67
creator Zhang, Hao Chi
He, Pei Hang
Gao, Xinxin
Lu, Jiayuan
Cui, Tie Jun
Luo, Yu
description Structured metallic surfaces, also called as plasmonic surfaces, have been proposed to support spoof surface plasmon polariton (SPP) modes, which can mimic natural SPPs at optical frequencies. Complex plasmonic surfaces can provide a large degree of freedom to engineer the characteristics of SPP dispersion. However, the analysis of complex plasmonic surfaces is difficult using the existing theoretical methods, such as the effective medium model and mode matching model. Recently, an accurate field-network-joint method has been introduced into the dispersion analysis of complex plasmonic surfaces, but it only works in the lossless case. In this communication, lossy complex plasmonic surfaces are investigated based on the modified field-network-joint method. The proposed method can predict not only the dispersion relationship between the frequency and the wavenumber, but also the lossy feature of the plasmonic surface with high efficiency and accuracy. As an example, a periodic structure with biforked slits filled by a lossy medium is fabricated and measured. The calculated attenuation constant (i.e., the imaginary part of the wavenumber) of the lossy structure is nearly identical to the measured result, demonstrating the superiority of the proposed analytical method.
doi_str_mv 10.1109/TAP.2019.2901123
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Complex plasmonic surfaces can provide a large degree of freedom to engineer the characteristics of SPP dispersion. However, the analysis of complex plasmonic surfaces is difficult using the existing theoretical methods, such as the effective medium model and mode matching model. Recently, an accurate field-network-joint method has been introduced into the dispersion analysis of complex plasmonic surfaces, but it only works in the lossless case. In this communication, lossy complex plasmonic surfaces are investigated based on the modified field-network-joint method. The proposed method can predict not only the dispersion relationship between the frequency and the wavenumber, but also the lossy feature of the plasmonic surface with high efficiency and accuracy. As an example, a periodic structure with biforked slits filled by a lossy medium is fabricated and measured. 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subjects Dielectric losses
Dispersion
Field-network joint solution
Impedance
loss
Metasurfaces
Model matching
Optical surface waves
Periodic structures
Polaritons
Propagation losses
Slits
structured plasmonic surface
surface plasmon polaritons (SPPs)
Surface waves
Wave attenuation
Wavelengths
title Loss Analysis of Plasmonic Metasurfaces Using Field-Network-Joint Method
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