Graphene-based dual functional metadevice in the THz gap

Sambit Kumar Ghosh; Sambit Kumar Ghosh; Santanu Das; Santanu Das; Somak Bhattacharyya

doi:10.1364/AO.444873

Applied Optics
Vol. 60,
Issue 36,
pp. 11247-11255
(2021)
•https://doi.org/10.1364/AO.444873

Graphene-based dual functional metadevice in the THz gap

Sambit Kumar Ghosh, Santanu Das, and Somak Bhattacharyya

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Sambit Kumar Ghosh, Santanu Das, and Somak Bhattacharyya, "Graphene-based dual functional metadevice in the THz gap," Appl. Opt. 60, 11247-11255 (2021)

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- Surface Optics and Plasmonics
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About this Article
History
- Original Manuscript: September 30, 2021
- Revised Manuscript: November 15, 2021
- Manuscript Accepted: November 15, 2021
- Published: December 14, 2021

Abstract

This paper presents a graphene-metal dual functional metadevice to provide two separate applications simultaneously, viz., absorption and cross-polarization conversion (CPC) of the electromagnetic (EM) wave without any structural deformations in the terahertz (THz) gap under two different biasing conditions. The meta-atom of the device bears stacked layers of metallic elliptical-shaped split rings, a thin zinc oxide (ZnO) layer, a slotted graphene layer printed over another ZnO layer backed by a continuous gold plate. It provides more than 70% absorptivity over a bandwidth of 3.40 THz (4.25 THz and 7.65 THz), with 90% absorptivity peak at 6.84 THz when the externally applied static electric field ($\xi$) on the patterned graphene surface is 8.52 V/nm. The change of the $\xi$ to a value of 0.44 V/nm enables the device to produce a CPC ratio (CPCR) above 90% over a bandwidth of almost 3.87 THz (2.22 THz and 6.09 THz), with near unity polarization conversion ratio peaks occurring at 2.38 THz, 3.80 THz, and 5.82 THz. Both findings have been validated using an exhaustive equivalent circuit analysis. The design possesses ultrathin properties (${\lambda _0}/{12.49}$), along with compactness (${\lambda _0}/{{5}}$), which has been improved significantly compared to their microwave counterparts. The proposed metadevice finds useful applications in THz sensing, stealth technology, THz communication, detection, polarization manipulation of EM waves, etc.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Dual Functional Devices	Frequency Range	Thickness	Periodicity	Configuration of the Device	Angular Stability (°)
[20] Dutta et. al.	15 GHz, 17 GHz	$\sim λ_{0} / 6.05$	$\sim λ_{0} / 1.99$	Metal-dielectric-metal-dielectric-metal (lumped component used)	Not discussed
[21] Wang et. al.	2.56–7.62 GHz	$\sim λ_{0} / 11.15$	$\sim λ_{0} / 4.88$	Metal-dielectric-air spacer-metal (lumped component used)	30
[22] Li et. al.	3.7–10.7 GHz	$\sim λ_{0} / 9.13$	$\sim λ_{0} / 4.05$	Metal-dielectric-air spacer-metal (lumped component used)	30
Proposed work	1–9 THz	$\sim λ_{0} / 12.49$	$\sim λ_{0} / 5$	Metal-dielectric-graphene-dielectric-metal (no lumped component used)	40

Proposed Metadevice [Mode I] (RLC Components)	Optimized Values for the RLC Components [Mode I]	Proposed Metadevice [Mode II] (RLC Components)	Optimized Values for the RLC Components [Mode II]
$C_{1}$	1.2 pF	$C_{1}^{'}$	0.0642 fF
$C_{2}$	0.5117 fF	$C_{2}^{'}$	0.0535 fF
$C_{3}$	169.9646 fF	$C_{3}^{'}$	0.0642 fF
$L_{1}$	$5 \times 10^{- 5} n H$	$C_{4}^{'}$	120.1012 fF
$L_{2}$	7.16 pH	$L_{1}^{'}$	0.1 pH
R	172.316 Ω	$L_{2}^{'}$	21.793 pH
Z	264 Ω	$L_{3}^{'}$	55.483 pH
E	90°	$R_{1}^{'}$	120 Ω
F	5 THz	$R_{2}^{'}$	235.3 Ω
		$R_{3}^{'}$	319.7 Ω
		$Z^{'}$	264 Ω
		$E^{'}$	90.1°
		$F^{'}$	5 THz

Dual Functional Devices	Frequency Range	Thickness	Periodicity	Configuration of the Device	Angular Stability (°)
[20] Dutta et. al.	15 GHz, 17 GHz	$\sim λ_{0} / 6.05$	$\sim λ_{0} / 1.99$	Metal-dielectric-metal-dielectric-metal (lumped component used)	Not discussed
[21] Wang et. al.	2.56–7.62 GHz	$\sim λ_{0} / 11.15$	$\sim λ_{0} / 4.88$	Metal-dielectric-air spacer-metal (lumped component used)	30
[22] Li et. al.	3.7–10.7 GHz	$\sim λ_{0} / 9.13$	$\sim λ_{0} / 4.05$	Metal-dielectric-air spacer-metal (lumped component used)	30
Proposed work	1–9 THz	$\sim λ_{0} / 12.49$	$\sim λ_{0} / 5$	Metal-dielectric-graphene-dielectric-metal (no lumped component used)	40

Proposed Metadevice [Mode I] (RLC Components)	Optimized Values for the RLC Components [Mode I]	Proposed Metadevice [Mode II] (RLC Components)	Optimized Values for the RLC Components [Mode II]
$C_{1}$	1.2 pF	$C_{1}^{'}$	0.0642 fF
$C_{2}$	0.5117 fF	$C_{2}^{'}$	0.0535 fF
$C_{3}$	169.9646 fF	$C_{3}^{'}$	0.0642 fF
$L_{1}$	$5 \times 10^{- 5} n H$	$C_{4}^{'}$	120.1012 fF
$L_{2}$	7.16 pH	$L_{1}^{'}$	0.1 pH
R	172.316 Ω	$L_{2}^{'}$	21.793 pH
Z	264 Ω	$L_{3}^{'}$	55.483 pH
E	90°	$R_{1}^{'}$	120 Ω
F	5 THz	$R_{2}^{'}$	235.3 Ω
		$R_{3}^{'}$	319.7 Ω
		$Z^{'}$	264 Ω
		$E^{'}$	90.1°
		$F^{'}$	5 THz

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Tables (2)

Equations (7)

Applied Optics