Reflection and transmission properties of a metasurface composed of resonant loaded wire dipoles

Z. A. Awan

doi:10.1364/AO.55.004219

Applied Optics
Vol. 55,
Issue 15,
pp. 4219-4226
(2016)
•https://doi.org/10.1364/AO.55.004219

Reflection and transmission properties of a metasurface composed of resonant loaded wire dipoles

Z. A. Awan

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Z. A. Awan, "Reflection and transmission properties of a metasurface composed of resonant loaded wire dipoles," Appl. Opt. 55, 4219-4226 (2016)

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Abstract

A considered metasurface is assumed to consist of a two-dimensional periodic arrangement of inductively loaded wires. The effects of incident angles and inductive loads upon equivalent surface impedance, reflection, and transmission properties of this metasurface have been investigated using numerical simulations. It is shown that at a particular frequency and angle, a metasurface can be cloaked for the incoming incident wave with nearly zero reflection. It is further studied that this approximate zero reflection is independent of the inductances of the inductively loaded wire dipoles.

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Incident Angles	Frequency (GHz)	$\| R \|$	$\| T \|$
$θ = 40 °$	3.7262	0.0301	0.9995
$θ = 80 °$	3.0831	0.2510	0.9680

Incident Angles	$\| R \|$	Frequency (GHz)
$θ = 0 °$	1	2.8765
$θ = 40 °$	1	2.8161
$θ = 80 °$	1	2.7167

Inductance Values	Frequency (GHz)	$Im [Z_{s}]$	$\| R \|$
$L = 0 nH$	3.0850	0	1
$L = 1 nH$	3.0304	0	1
$L = 5 nH$	2.8161	0	1
$L = 10 nH$	2.5647	0	1

Incident Angles	Frequency (GHz)	$\| R \|$	$\| T \|$
$θ = 40 °$	3.7262	0.0301	0.9995
$θ = 80 °$	3.0831	0.2510	0.9680

Incident Angles	$\| R \|$	Frequency (GHz)
$θ = 0 °$	1	2.8765
$θ = 40 °$	1	2.8161
$θ = 80 °$	1	2.7167

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Applied Optics