A silicene-based plasmonic electro-optical switch in THz range

Emami-Nejad, Hamed; Mir, Ali; Farmani, Ali; Talebzadeh, Reza

doi:10.1088/1402-4896/aca448

Cited by 3 publications

(2 citation statements)

References 54 publications

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“…Elsewhere, two optical switches have recently been proposed based on silicene. The first one was a plasmonic electro-optical switch based on a silicene waveguide encapsulated between layers of Al 2 O 3 39 , providing a better performance compared to its graphene counterpart. The second switch was designed based on metamaterials, utilizing graphene-silicene-graphene (G-S-G) structure to control the switching of the transmitted light 40 .…”

Section: Introductionmentioning

confidence: 99%

First designing of a silicene-based optical MOSFET with outstanding performance

Emami-Nejad

Mir

Lorestaniweiss

et al. 2023

Sci Rep

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Miniaturized integrated optical devices with low power consumption have long been considered hot candidates for plasmonic applications. While 2D materials such as graphene have been proposed for this purpose, they suffer from large propagation loss and low controllability at room temperature. Here, a silicene-based optical MOSFET with excellent performance is designed to achieve integrated circuit optical technology. The designed device is comprised of a silicene optical waveguide whose switching operation is performed by a gate and has a structure similar to an enhancement MOSFET with a formed channel. Unlike graphene, the surface conductivity of silicene can be controlled by both chemical potential and an electric field perpendicular to its surface. This unique feature of silicene is used to design and simulate an optical-MOSFET with transverse electric polarization at 300 K. The salient characteristics of the optical device include its nanoscale dimensions, ultra-low insertion loss of 0.13 dB, infinite extinction ratio, and quality factor of 688, proposing it as a promising tool for optical integration.

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Section: Introductionmentioning

confidence: 99%

First designing of a silicene-based optical MOSFET with outstanding performance

Emami-Nejad

Mir

Lorestaniweiss

et al. 2023

Sci Rep

Self Cite

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“…It is a matter of importance to improve the current photoelectronic systems, widening the response spectrum, reducing the production cost, and enhancing efficiency, via novel materials and ideas. As a promising candidate for future nano/optoelectronic components, silicene has attracted tremendous attention during the last decades, because of its compatibility with the present semiconductor industry [4,5]. Silicene as a buckled 2D material, fabricated from silicon atoms, which exhibits many excellent properties like quantum Hall effect, halfmetallicity, ferromagnetism, giant magnetoresistance, superconductivity [6], and applications such as molecule sensing, hydrogen purification, hydrogen storage, and solar cells [7][8][9][10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Non-equilibrium Green’s function approach for simulation asymmetric source-drain silicene-based photodetectors

Alaee,

Sadeghzadeh,

Ostovari

2023

Phys. Scr.

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Employing tight-binding approximation coupling to Non-Equilibrium Green’s Function (NEGF) approach, we have simulated three photodetectors based on 20 nm Armchair-Silicene-Nanoribbons (ASiNR) with asymmetric source (Ir-doped silicene) and drain (Cu-, Ag-, or Au-doped silicene) contacts. In this study, monochromatic illumination in the range of 0.1-10 eV with the intensity of 1kW cm-2 is used for the simulation of the photocurrent, photoresponsivity, quantum efficiency, and detectivity. It is shown that the highest peak in the photocurrent spectrum occurs at the 273 nm incident wavelength for all devices under consideration, where the Ir-Cu device has presented enhanced photodetector characteristics than Ir-Ag and Ir-Au devices. It is also found that only transitions between two subbands with the same index are allowed. Moreover, the first peak in the photocurrent spectrum is related to the main band gap of ASiNR. Additionally, the simulated dark and total currents versus source-drain voltage reveal that photocurrent caused a negative shift in the total current proportional to incident light intensity. The proposed photodetector has the advantage that it is fully compatible with established silicon technology.

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