Active modulation of electromagnetically induced transparency analogue in terahertz hybrid metal-graphene metamaterials

Xiao, Shuyuan; Wang, Tao; Liu, Tingting; Yan, Xicheng; Li, Zhong; Xu, Chen

doi:10.1016/j.carbon.2017.10.035

Cited by 399 publications

(162 citation statements)

References 105 publications

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“…In the lower THz range, the interband contributions can be completely ignored. Because of Pauli exclusion principle, the surface conductivity can be approximated as a Drude-like model [41,42].…”

Section: The Geometric Structure and Numerical Modelmentioning

confidence: 99%

Plasmonic absorption characteristics based on dumbbell-shaped graphene metamaterial arrays

Cen

Chen

Liang

et al. 2018

Physica E: Low-dimensional Systems and Nanostructures

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In this paper, we proposed a theoretical model in the far-infrared and terahertz (THz) bands, which is a dumbbell-shaped graphene metamaterial arrays with a combination of graphene nanorod and two semisphere-suspended heads. We report a detailed theoretical investigation on how to enhance localized electric field and the absorption in the dumbbell-shaped graphene metamaterial arrays. The simulation results show that by changing the geometrical parameters of the structure and the Fermi level of graphene, we can change the absorption characteristics. Furthermore, we have discovered that the resonant wavelength is insensitive to TM polarization. In addition, we also find that the double-layer graphene arrays have better absorption characteristics than single-layer graphene arrays. This work allows us to achieve tunable terahertz absorber, and may also provide potential applications in optical filter and biochemical sensing.

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Section: The Geometric Structure and Numerical Modelmentioning

confidence: 99%

Plasmonic absorption characteristics based on dumbbell-shaped graphene metamaterial arrays

Cen

Chen

Liang

et al. 2018

Physica E: Low-dimensional Systems and Nanostructures

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“…Recent studies have shown that the EIT effect can be mimicked by a series of classical optical systems, such as on-chip plasmonic structures [2], photonic crystals [3][4][5] and meta-surfaces [6][7][8][9][10]. Apart from its fundamental significance, meta-surface-induced transparency in subwavelength structures is the most recent and promising addition to the existing classical EIT schemes [11][12][13]. Terahertz bandpass devices, such as the THz modulators and sensing devices [14], have been developed by applying the transparency window of the EIT.…”

Section: Introductionmentioning

confidence: 99%

“…Gu et al observed the excitation and tuning of EIT by the interference between different excitation pathways of the dark mode in a planar terahertz metamaterial [10]. Xiao et al realize a complete modulation in the resonance strength of the EIT analog via manipulating the conductivity of graphene [11].…”

Section: Introductionmentioning

confidence: 99%

Enhanced THz EIT resonance based on the coupled electric field dropping effect within the undulated meta-surface

et al. 2019

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In this paper, the enhanced terahertz (THz) electromagnetically induced transparency (EIT) resonance is achieved based on the coupled electric field dropping effect within the undulated meta-surface. It is found that the height difference between the inner ring and the outer split ring could lead to a significant coupled mode with electric field dropping distribution. When the height of the inner ring increases, the electric field of the inner ring gradually cascades to the outer ring just as a waterfall so that the coupling between the two rings in a unit cell and two adjacent units is enhanced. Both the simulation and experimental results show that a nearly 95% transparency window which is twice that of traditional EIT can be observed by applying such coupled electric field dropping effect, which may provide a promising way to develop the high resonance intensity meta-surface in the THz region.

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“…Compared with the conventional EIT, which requires severe experimental conditions [18], MM-based EIT analogue is easier to be produced and more stable, therefore suitable for practical chipscale applications [15].At the same time, for THz communication systems, THz devices with active tunability are required [19]. Therefore, various active optical materials have been utilized to turn passive MMs to be active, including liquid crystals [20,21], semiconductors [19,22,23], two-dimension (2D) materials [24][25][26] and phase-change materials (PCMs) [27]. PCMs, such as chalcogenide GeSbTe (GST) and vanadium dioxide (VO2), possess significantly different optical properties in different phase states, i.e., amorphous and crystalline states [28].…”

mentioning

confidence: 99%

Actively tunable terahertz electromagnetically induced transparency analogue based on vanadium-oxide-assisted metamaterials

Zhang¹,

Yang²,

Han³

et al. 2020

Appl. Phys. A

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Recently, phase-change materials (PCMs) have drawn more attention due to the dynamically tunable optical properties. Here, we investigate the active control of electromagnetically induced transparency (EIT) analogue based on terahertz (THz) metamaterials integrated with vanadium oxide (VO2). Utilizing the insulator-to-metal transition of VO2, the amplitude of EIT peak can be actively modulated with a significant modulation depth. Meanwhile the group delay within the transparent window can also be dynamically tuned, achieving the active control of slow light effect. Furthermore, we also introduce independently tunable transparent peaks as well as group delay based on a double-peak EIT with good tuning performance. Finally, based on broadband EIT, the active tuning of quality factor of the EIT peak is also realized. This work introduces active EIT control with more degree of freedom by employing VO2, and can find potential applications in future wireless and ultrafast THz communication systems as multi-channel filters, switches, spacers, logic gates and modulators. Keywords: terahertz metamaterials; phase-change materials; vanadium oxide; electromagnetically induced transparency 1. Introduction Over the past decades, Metamaterials (MMs) have been focused continually due to the capability to manipulate electromagnetic (EM) waves in an unnatural way [1]. By designing artificial meta-resonators of MMs and arranging them appropriately, MMs can tailor lightwaves in subwavelength scale, consequently providing optical responses with desirable properties. In recent years, MMs have come to the terahertz (THz) regime [2]. Located between infrared and microwave band, THz radiations have enjoyed a rise of interest and are promising for security scanning [3], future wireless communications as well as the sixth-generation (6G) networks [3-5]. Now, MMshave been regarded as ideal platforms to achieve chipscale THz devices, such as THz sources [6,7], modulators [8,9], sensors [10,11] and absorbers [12,13].Recently, electromagnetically induced transparency (EIT) analogue in THz MMs have attracted more attention [14][15][16]. EIT refers to a sharp transparent window within a broad absorption spectrum, which comes from the quantum interference between two distinct excitation pathways in the natural three-level atom system [17]. Due to the dispersion properties, EIT has potential applications in slow light, optical data storage, nonlinear process enhancement and signal processing [18]. Mimicking EIT in the classical system, MMs can reproduce such effect via the near-field coupling between bright and dark modes supported on meta-resonators [14]. Compared with the conventional EIT, which requires severe experimental conditions [18], MM-based EIT analogue is easier to be produced and more stable, therefore suitable for practical chipscale applications [15].At the same time, for THz communication systems, THz devices with active tunability are required [19]. Therefore, various active optical materials have been utilized to turn passive MMs...

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Active modulation of electromagnetically induced transparency analogue in terahertz hybrid metal-graphene metamaterials

Cited by 399 publications

References 105 publications

Plasmonic absorption characteristics based on dumbbell-shaped graphene metamaterial arrays

Plasmonic absorption characteristics based on dumbbell-shaped graphene metamaterial arrays

Enhanced THz EIT resonance based on the coupled electric field dropping effect within the undulated meta-surface

Actively tunable terahertz electromagnetically induced transparency analogue based on vanadium-oxide-assisted metamaterials

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