Wide-band metamaterial perfect absorber through double arrow shape printed on a thin dielectric

Ali, Siti Adlina Md; Abu, Mohd Salleh; Zabri, Siti Normi; Hamzah, Shipun Anuar

doi:10.11591/eei.v10i5.3154

Cited by 4 publications

(1 citation statement)

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“…The reflection intensity declines when the frequency of the incident EM wave is closer to the resonance frequency of the surface plasma of the medium. Hence, the radiation energy is absorbed by the medium [30]. The reflection and transmission coefficients are the two essential parameters used to estimate the absorption efficiency A(ω) of any MA.…”

Section: Design Methodologymentioning

confidence: 99%

Royal Crown Shaped Polarization Insensitive Perfect Metamaterial Absorber for C-, X-, and Ku-Band Applications

Afsar¹,

Faruque²,

Abdullah³

et al. 2023

Computers, Materials &Amp; Continua

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This study proposed a new royal crown-shaped polarisation insensitive double negative triple band microwave range electromagnetic metamaterial absorber (MA). The primary purpose of this study is to utilise the exotic characteristics of this perfect metamaterial absorber (PMA) for microwave wireless communications. The fundamental unit cell of the proposed MA consists of two pentagonal-shaped resonators and two inverse C-shaped metallic components surrounded by a split ring resonator (SRR). The bottom thin copper deposit and upper metallic resonator surface are disjoined by an FR-4 dielectric substrate with 1.6 mm thickness. The CST MW studio, a highfrequency electromagnetic simulator has been deployed for numerical simulation of the unit cell in the frequency range of 4 to 14 GHz. In the TE mode, the offered MA structure demonstrated three different absorption peaks at 6.85 GHz (C-band), 8.87 GHz (X-band), and 12.03 GHz (Ku-band), with 96.82%, 99.24%, and 99.43% absorptivity, respectively. The electric field, magnetic field, and surface current distribution were analysed using Maxwell's-Curl equations, whereas the angle sensitivity was investigated to comprehend the absorption mechanism of the proposed absorber. The numerical results were verified using the Ansys HFSS (high-frequency structure simulator) and ADS (advanced design system) for equivalent circuit models. Moreover, the proposed MA is polarisation and incident angle independent. Hence, the application of this MA can be extended to a great extent, including airborne radar applications, defence, and stealth-coating technology.

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Section: Design Methodologymentioning

confidence: 99%