Configurable metamaterial absorber with pseudo wideband spectrum

Zhu, Weiren; Huang, Yongjun; Rukhlenko, Ivan D.; Wen, Guangjun; Premaratne, Malin

doi:10.1364/oe.20.006616

Cited by 99 publications

(56 citation statements)

References 24 publications

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“…Here the metamaterial resonator is a typical electric-LC (ELC) resonator and has been widy used to design the MMAs. 24,25 Comparing with Fig. 1, layer 1 in Fig.…”

Section: Extended Interference Theory Modelmentioning

confidence: 85%

Analysis of metamaterial absorber in normal and oblique incidence by using interference theory

et al. 2013

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Metamaterial absorber (MMA), which is a kind of thin electromagnetic absorber consisting of sub-wavelength metamaterial resonators and can exhibit near-perfect absorption characteristics, has been widely investigated in recently years. The impedance matching theory was proposed to analyze the configuration of MMA in most literatures. Such theory, however, may not suitable to analyze the interactions of metamaterial resonators and the ground plane. The interference theory, on another hand, can play effective approach for this kind of problem presented in recent studies, whereas little attention has been paid on the oblique incidence conditions. In this paper, we firstly extend the interference theory model to make it applicable for oblique incident waves and analyze MMA using the extended interference theory model. Secondly, we further explore the sufficient condition for the maximum absorptivity at both normal and oblique incidence cases. Thirdly, with the sufficient condition, we can obtain the absorbing frequency directly if the thickness of MMA is given. These theoretical results have significant effects on the design and analyze of MMA. And lastly, we point out that absorptivity is not absolutely insensitive to the incidence angle in TM mode as what previous study claims, but insensitive when the dielectric slab is high loss, which can also be explained by interference theory

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“…Here the metamaterial resonator is a typical electric-LC (ELC) resonator and has been widy used to design the MMAs. 24,25 Comparing with Fig. 1, layer 1 in Fig.…”

Section: Extended Interference Theory Modelmentioning

confidence: 85%

Analysis of metamaterial absorber in normal and oblique incidence by using interference theory

et al. 2013

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“…Our previous researches [20,21] show that the added cover layer would contribute to decreasing the operating frequency. As shown in Fig.…”

Section: Figs 1(d) (E) and (I) (J)mentioning

confidence: 99%

“…These metamaterial absorbers can operate at almost arbitrary frequency spectra ranged from radio frequencies, microwave and terahertz frequencies, to even optical frequencies [8][9][10][11][12][13]. Moreover, strategies for expanding the operating bandwidths of MAs, such as dual-band [14,15], triple-band [16,17], multiband [18,19], band-tunable [20,21], broad-band [22,23], and ultra-broad-band [24,25] designs, have also been reported in recent years. Simultaneously, the theoretical analysis methods including classic electromagnetic theory [7], interference theory [26], and equivalent circuit/transmission line theory [27] are developed to analyze and guide the design procedures and explain the appeared exciting absorbing properties.…”

Section: Introductionmentioning

confidence: 99%

Ultra-Compact Metamaterial Absorber With Low-Permittivity Dielectric Substrate

Sun

Huang

et al. 2015

PIER M

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Abstract-We analyze and discuss an ultra-compact metamaterial absorber (MA) by introducing meander lines into the resonant cells and covering another dielectric layer onto the MA. The size reduction procedures are presented step by step and an ultra-compact metamaterial absorber with in-plane (lateral) dimension of λ/28 and vertical thickness of λ/37 is obtained. We further present two variations of MA configurations which can reach similar ultra-compact sizes. The proposed ultracompact MAs show near-unity absorption under a wide range of incident angles for both TE and TM radiations.

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“…In recent years, various structures, such as split rings [11], closed rings [12], and fishnet structures [13], have been proposed for MAs. A certain progress has been made in broadband MAs developing [14,15].…”

Section: Introductionmentioning

confidence: 99%

A Polarization-Dependent Frequency-Selective Metamaterial Absorber with Multiple Absorption Peaks

et al. 2017

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Abstract:A polarization-dependent, frequency-selective metamaterial (MM) absorber based on a single-layer patterned resonant structure intended for F frequency band is proposed. The design, fabrication, and measurement for the proposed absorber are presented. The absorber's absorption properties at resonant frequencies have unique characteristics of a single-band, dual-band, or triple-band absorption for different polarization of the incident wave. The calculated surface current distributions and power loss distribution provide further understanding of physical mechanism of resonance absorption. Moreover, a high absorption for a wide range of TE-polarized oblique incidence was achieved. Hence, the MM structure realized on a highly flexible polyimide film, makingthe absorber suitable for conformal geometry applications. The proposed absorber has great potential in the development of polarization detectors and polarizers.

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Configurable metamaterial absorber with pseudo wideband spectrum

Cited by 99 publications

References 24 publications

Analysis of metamaterial absorber in normal and oblique incidence by using interference theory

Analysis of metamaterial absorber in normal and oblique incidence by using interference theory

Ultra-Compact Metamaterial Absorber With Low-Permittivity Dielectric Substrate

A Polarization-Dependent Frequency-Selective Metamaterial Absorber with Multiple Absorption Peaks

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