Electric Dipole-Magnetic Quadrupole Resonant Coupling for Broadband Operating Metasurfaces

In this work, we have applied the multipole expansion method to analyze the transmission/reflection properties of allmetallic metasurfaces operating in the microwave regime. This analytical technique provides enhanced physical insights into the electromagnetic properties of these metasurfaces. We sh...

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Veröffentlicht in:	IEEE transactions on antennas and propagation 2024-12, p.1-1
Hauptverfasser:	Ribeiro, Jessica Abranches Pinto, Hernandez-Sarria, Jhon James, Pereira, Luiz Augusto Melo, Sodre, Arismar Cerqueira, Oliveira, Osvaldo N., Mendes, Luciano Leonel, Mejia-Salazar, Jorge Ricardo
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Schlagworte:	Antennas and propagation Couplings Current density Electromagnetic scattering Electromagnetics Magnetic resonance Mathematical models Metals Metasurfaces Microwave theory and techniques Multipole Analysis Multipole Resonances
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creator	Ribeiro, Jessica Abranches Pinto Hernandez-Sarria, Jhon James Pereira, Luiz Augusto Melo Sodre, Arismar Cerqueira Oliveira, Osvaldo N. Mendes, Luciano Leonel Mejia-Salazar, Jorge Ricardo
description	In this work, we have applied the multipole expansion method to analyze the transmission/reflection properties of allmetallic metasurfaces operating in the microwave regime. This analytical technique provides enhanced physical insights into the electromagnetic properties of these metasurfaces. We show that the sharp electric-dipole resonance in a metasurface composed of metallic squares can be resonantly coupled with the sharp magnetic-quadrupole resonance from a metasurface made of metallic circles. This coupling yields a significantly broadened operating band for the metasurface. Specifically, the metallic-square based metasurface operates under a fractional bandwidth of around 61%, while the operational bandwidth of a metallic-circle based metasurface is ca. 22%. In contrast, the resonantly-coupled electric dipole-magnetic quadrupole metasurface exhibits a fractional bandwidth of approximately 96% operating at the central frequency 5.7 GHz. The feasibility of the design was proven by fabricating metasurfaces over an FR4 substrate, whose electromagnetic properties were as predicted qualitatively using the analytical multipole expansion method.
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title	Electric Dipole-Magnetic Quadrupole Resonant Coupling for Broadband Operating Metasurfaces
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