Negative refraction metamaterial with low loss property at millimeter wave spectrum

The design of the millimetre-wave (MMW) metamaterials (MMs) unit cell operates at 28 GHz is presented and numerically investigated. The proposed structure composed of a modified split ring resonator (MSRR) printed on both sides of the substrate layer. Popular MM structures such as S-shape, G-shape,...

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Main Authors: Esmail, Bashar Ali F., Majid, H. A., Saparudin, Faiz Asraf, Jusoh, M., Ashyap, Adel Y.I., Al-Fadhali, Najib, Abdul Rahim, Mohammad Kamal
Format: Article
Language:English
Published: Institute of Advanced Engineering and Science 2020
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Online Access:http://eprints.utm.my/id/eprint/90065/1/MohammadKamalAbdul2020_NegativeRefractionMetamaterialwithLowLoss.pdf
http://eprints.utm.my/id/eprint/90065/
http://dx.doi.org/10.11591/eei.v9i3.1853
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spelling my.utm.900652021-03-31T06:37:59Z http://eprints.utm.my/id/eprint/90065/ Negative refraction metamaterial with low loss property at millimeter wave spectrum Esmail, Bashar Ali F. Majid, H. A. Saparudin, Faiz Asraf Jusoh, M. Ashyap, Adel Y.I. Al-Fadhali, Najib Abdul Rahim, Mohammad Kamal TK Electrical engineering. Electronics Nuclear engineering The design of the millimetre-wave (MMW) metamaterials (MMs) unit cell operates at 28 GHz is presented and numerically investigated. The proposed structure composed of a modified split ring resonator (MSRR) printed on both sides of the substrate layer. Popular MM structures such as S-shape, G-shape, and ω-shape are adjusted to operate at the 28 GHz for comparison purpose. MSRR achieves a wide bandwidth of 1.1 GHz in comparison with its counterparts at the resonance frequency. Moreover, the proposed structure presents very low losses by providing the highest transmission coefficient, S21, at the corresponding frequency region. The radiation loss is substantially suppressed and the negativity of the constitutive parameters of the proposed MM structure is maintained. By applying the principle of the electromagnetically induced transparency (EIT) phenomenon, the MSRR unit cell induces opposite currents on both sides of the substrate which leads to cancelling out the scattering fields and suppresses the radiation loss. The constitutive parameters of the MM structures are retrieved using well-known retrieval algorithm. The proposed structure can be used to enhance the performance of fifth-generation (5G) antenna such as the gain and bandwidth. Institute of Advanced Engineering and Science 2020-06 Article PeerReviewed application/pdf en http://eprints.utm.my/id/eprint/90065/1/MohammadKamalAbdul2020_NegativeRefractionMetamaterialwithLowLoss.pdf Esmail, Bashar Ali F. and Majid, H. A. and Saparudin, Faiz Asraf and Jusoh, M. and Ashyap, Adel Y.I. and Al-Fadhali, Najib and Abdul Rahim, Mohammad Kamal (2020) Negative refraction metamaterial with low loss property at millimeter wave spectrum. Bulletin of Electrical Engineering and Informatics, 9 (3). pp. 1038-1045. ISSN 2089-3191 http://dx.doi.org/10.11591/eei.v9i3.1853 DOI:10.11591/eei.v9i3.1853
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
language English
topic TK Electrical engineering. Electronics Nuclear engineering
spellingShingle TK Electrical engineering. Electronics Nuclear engineering
Esmail, Bashar Ali F.
Majid, H. A.
Saparudin, Faiz Asraf
Jusoh, M.
Ashyap, Adel Y.I.
Al-Fadhali, Najib
Abdul Rahim, Mohammad Kamal
Negative refraction metamaterial with low loss property at millimeter wave spectrum
description The design of the millimetre-wave (MMW) metamaterials (MMs) unit cell operates at 28 GHz is presented and numerically investigated. The proposed structure composed of a modified split ring resonator (MSRR) printed on both sides of the substrate layer. Popular MM structures such as S-shape, G-shape, and ω-shape are adjusted to operate at the 28 GHz for comparison purpose. MSRR achieves a wide bandwidth of 1.1 GHz in comparison with its counterparts at the resonance frequency. Moreover, the proposed structure presents very low losses by providing the highest transmission coefficient, S21, at the corresponding frequency region. The radiation loss is substantially suppressed and the negativity of the constitutive parameters of the proposed MM structure is maintained. By applying the principle of the electromagnetically induced transparency (EIT) phenomenon, the MSRR unit cell induces opposite currents on both sides of the substrate which leads to cancelling out the scattering fields and suppresses the radiation loss. The constitutive parameters of the MM structures are retrieved using well-known retrieval algorithm. The proposed structure can be used to enhance the performance of fifth-generation (5G) antenna such as the gain and bandwidth.
format Article
author Esmail, Bashar Ali F.
Majid, H. A.
Saparudin, Faiz Asraf
Jusoh, M.
Ashyap, Adel Y.I.
Al-Fadhali, Najib
Abdul Rahim, Mohammad Kamal
author_facet Esmail, Bashar Ali F.
Majid, H. A.
Saparudin, Faiz Asraf
Jusoh, M.
Ashyap, Adel Y.I.
Al-Fadhali, Najib
Abdul Rahim, Mohammad Kamal
author_sort Esmail, Bashar Ali F.
title Negative refraction metamaterial with low loss property at millimeter wave spectrum
title_short Negative refraction metamaterial with low loss property at millimeter wave spectrum
title_full Negative refraction metamaterial with low loss property at millimeter wave spectrum
title_fullStr Negative refraction metamaterial with low loss property at millimeter wave spectrum
title_full_unstemmed Negative refraction metamaterial with low loss property at millimeter wave spectrum
title_sort negative refraction metamaterial with low loss property at millimeter wave spectrum
publisher Institute of Advanced Engineering and Science
publishDate 2020
url http://eprints.utm.my/id/eprint/90065/1/MohammadKamalAbdul2020_NegativeRefractionMetamaterialwithLowLoss.pdf
http://eprints.utm.my/id/eprint/90065/
http://dx.doi.org/10.11591/eei.v9i3.1853
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score 13.211869