Tunable Mid IR focusing in InAs based semiconductor Hyperbolic Metamaterial

Desouky, Mai; Mahmoud, Ahmed M.; Swillam, Mohamed A.

doi:10.1038/s41598-017-15493-4

Cited by 32 publications

(13 citation statements)

References 30 publications

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“…The mid-IR is an interesting wavelength range for applications in infrared imaging, biomedical diagnostics, and chemo- and biosensing applications. − Sensing biomolecules exhibiting weak vibrational/rotational modes in the mid-IR regime are difficult due to the lack of suitable mid-IR absorbing materials as labels . Although plasmonics are widely used in optical biosensors, their natural plasmonic resonance occurs mostly in the visible regime. , Researchers have been on a hunt for alternative materials with tunable plasmonic response extending to the mid-IR wavelength range, , which is a useful window for gas and biological sensing applications …”

Section: Introductionmentioning

confidence: 99%

“…6 Although plasmonics are widely used in optical biosensors, their natural plasmonic resonance occurs mostly in the visible regime. 7,8 Researchers have been on a hunt for alternative materials with tunable plasmonic response extending to the mid-IR wavelength range, 9,10 which is a useful window for gas and biological sensing applications. 2 In the realm of new emerging plasmonic materials, graphene has gained a strong reputation.…”

Section: Introductionmentioning

confidence: 99%

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Near-Field Mapping of Localized Plasmon Resonances in Metal-Free, Nanomembrane Graphene for Mid-Infrared Sensing Applications

Desouky

Anisur

Alba

et al. 2018

ACS Appl. Nano Mater.

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Graphene, as an optically transparent material, typically defies any attempt for mid-infrared (mid-IR) absorption, which limits its applications in mid-IR biosensing. Although remarkable evidence for mid-IR nanopatterned graphene plasmons has been reported via the induction of free charge carriers, no study so far has investigated plasmonic excitation in nanopatterned graphene without employing induced voltage, high chemical doping, or metallic reflectors. In this work, we show that localized plasmon resonance (LSPR) can be probed in metal-free, naturally doped, nanomembrane graphene (NMG) without induced voltage or using metallic layers. We rely on facile, lithography-free, fabrication methodology to pattern nanoscale holes in a single sheet of graphene using Au nanoislands with hole dimensions as small as 10 nm. We image the LSPR at the graphene membrane edges via scanning near-field optical microscopy. Our experimental findings are confirmed by theoretical electromagnetic field mapping at the graphene membrane edges leading to noticeable absorption. We demonstrate the dependence of this absorption wavelength on the hole diameter and interhole distance; hence, we present a new avenue to fundamentally boost light harvesting with naturally doped NMG which is pivotal for mid-IR sensors. We show that our designed NMG can be used as a mid-IR biosensor with theoretically calculated sensitivity of 825 nm/RIU.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Near-Field Mapping of Localized Plasmon Resonances in Metal-Free, Nanomembrane Graphene for Mid-Infrared Sensing Applications

Desouky

Anisur

Alba

et al. 2018

ACS Appl. Nano Mater.

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“…Nevertheless, the fabrication of these kinds of devices is still a big challenge at current state-of-the-art. Semiconductor 20,21 and superconductor 22,23 were also adopted in tunable metamaterials, but the modulation of these devices requires harsh environment, which restricted their practical applications.…”

Section: Introductionmentioning

confidence: 99%

Electrically tunable terahertz dual-band metamaterial absorber based on a liquid crystal

Yin

Xia

et al. 2018

RSC Adv.

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In this paper, a liquid crystal (LC) based tunable metamaterial absorber with dual-band absorption is presented. The proposed absorber is analysed both numerically and experimentally. The analysis shows that the two absorption peaks, originating from the new resonant structure, are experimentally detected at 269.8 GHz and 301.4 GHz when no bias voltage is applied to the LC layer. In order to understand the absorption mechanisms, simulation results for the surface current and power loss distributions are presented. Since liquid crystals are used as the dielectric layer to realize the electrically tunable absorber, a frequency tunability of 2.45% and 3.65% for the two absorption peaks is experimentally demonstrated by changing the bias voltage of the LC layer from 0 V to 12 V. Furthermore, the absorber is polarization independent and a high absorption for a wide range of oblique incidence is achieved. The designed absorber provides a way forward for the realization of tunable metamaterial devices that can be applied in multi-band detection and imaging.

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“…Due to the openness of the hyperbola, HMMs can support electromagnetic modes with arbitrarily large wave vectors that would otherwise become evanescent waves in free space. These unique properties make the HMMs ubiquitous in different areas including subwavelength resolution imaging, − negative refraction, − focusing, − thermal emission engineering, , and spontaneous emission enhancement. − …”

mentioning

confidence: 99%

Constructing Hyperbolic Metamaterials with Arbitrary Medium

et al. 2021

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Recent advances in hyperbolic metamaterials have spurred many breakthroughs in the field of manipulating light propagation. However, the unusual electromagnetic properties also put extremely high demands on its compositional materials. Limited by the finite relative permittivity of the natural materials, the effective permittivity of the constructed hyperbolic metamaterials is also confined to a narrow range. Here, based on the proposed concept of structure-induced spoof surface plasmon, we prove that arbitrary materials can be selected to construct the hyperbolic metamaterials with independent relative effective permittivity components. Besides, the theoretical achievable ranges of the relative effective permittivity components are unlimited. As proofs of the method, three novel hyperbolic metamaterials are designed with their functionalities validated numerically and experimentally by specified directional propagation. To further illustrate the superiority of the method, an all-metal low-loss hyperbolic metamaterial filled with air is proposed and demonstrated. The proposed methodology effectively reduces the design requirement for hyperbolic metamaterials and provides new ideas for the scenarios where large permittivity coverage is needed such as microwave and terahertz focus, super-resolution imaging, electromagnetic cloaking, and so on.

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Tunable Mid IR focusing in InAs based semiconductor Hyperbolic Metamaterial

Cited by 32 publications

References 30 publications

Near-Field Mapping of Localized Plasmon Resonances in Metal-Free, Nanomembrane Graphene for Mid-Infrared Sensing Applications

Near-Field Mapping of Localized Plasmon Resonances in Metal-Free, Nanomembrane Graphene for Mid-Infrared Sensing Applications

Electrically tunable terahertz dual-band metamaterial absorber based on a liquid crystal

Constructing Hyperbolic Metamaterials with Arbitrary Medium

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