Hyperbolic Bismuth–Dielectric Structure for Terahertz Photonics

Zaitsev, Anton D.; Demchenko, Petr; Makarova, E. S.; Tukmakova, A. S.; Kablukova, N. S.; Asach, Aleksei V.; Khodzitsky, Mikhail K.

doi:10.1002/pssr.202000093

Cited by 5 publications

(4 citation statements)

References 48 publications

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“…The study [14] showed, that the charge carrier plasma frequency, which determines the upper frequency limit of the possibility of detecting radiation, in bulk bismuth lies within the range from 93 to 99 THz (depending on the radiation polarization) at the temperature of 300 K. In case of cooling to the temperature of 80 K the plasma frequency decreases to the values of 59−62 THz, that is in good agreement with the results of the study [15], in which the features of the reflection spectra of doped bismuth−antimony crystals were studied in the long-wave infrared spectrum. However, as shown in the study [16], with a decrease in the bismuth film thickness up to the values of 40 to 150 nm at a temperature of 300 K a decrease in the plasma frequency (compared to bulk samples) up to 55 THz at a thickness of 40 nm and up to 67 THz at a thickness of 150 nm is also observed. Consequently, under the effect of monochromatic radiation of 0.14 THz in Bi 88 Sb 12 at 300 K the radiation absorption will be observed, and to describe the processes the theory of internal photoeffect for semiconductors may be used.…”

Section: Expected Effects and Phenomenasupporting

confidence: 64%

Terahertz radiation detector based on thermoelectric material Bi-=SUB=-88-=/SUB=-Sb-=SUB=-12-=/SUB=--=SUP=-*-=/SUP=-

et al. 2022

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Terahertz radiation is very promising for visualization, detection and data transfer. Searching for sensitive, fast and compact THz detector that operates at room temperature is a common subject for these applications. Hence, there is still an issue of searching for new materials for THz radiation detection. Solid solutions based on thermoelectric bismuth and antimony appear to have significant potential for these applications. In this paper photoresponse of thermoelectric material Bi88Sb12 has been studied for the first time. Films with thicknesses of 70 and 150 nm were studied under influence of radiation at frequency of 0.14 THz. Keywords: terahertz radiation, photoresponse, bismuth, antimony, thermoelectric materials, thin films.

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Section: Expected Effects and Phenomenasupporting

confidence: 64%

Terahertz radiation detector based on thermoelectric material Bi-=SUB=-88-=/SUB=-Sb-=SUB=-12-=/SUB=--=SUP=-*-=/SUP=-

et al. 2022

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“…The thickness of the bismuth film was chosen toachieve high conductivity and to provide transmission at the same time [37,38]. A thin, almost transparent mica substrate was chosen for THz waves due to its stable geometry and its ability to grow a high-quality bismuth film with a large average crystallit size.…”

Section: Sample Preparationmentioning

confidence: 99%

Frequency-Selective Surface Based on Negative-Group-Delay Bismuth–Mica Medium

et al. 2023

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Negative group delay may be observed in dispersive media with anomalous dispersion in a certain frequency range. The fact that an outgoing wave packet precedes an incoming one does not violate the causality principle but is only a consequence of a waveform reshaping. This effect is observed in media such as photonic crystals, hyperbolic and epsilon-near-zero metamaterials, undersized waveguides, subwavelength apertures, side-by-side prisms, and resonant circuits at various frequencies. The current work is devoted to the design of a simple negative-group-delay medium with tunable properties in the THz frequency range. This medium consists of a bismuth-based frequency-selective surface on a dielectric substrate and may be tuned both statically and dynamically. While a geometry variation defines a main form of an effective permittivity dispersion and group delay/group velocity spectra, an external voltage allows one to adjust them with high precision. For the configuration proposed in this work, all frequency regions with noticeable change in group delay/group velocity lie within atmospheric transparency windows, which are to be used in 6G communications. This medium may be applied to THz photonics for a tunable phase-shift compensation, dispersion management in systems of THz signal modulation, and for encoding in next-generation wireless communication systems.

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“…The dispersion of the HMM conforms to a hyperboloid shape [63], with one directional component of permittivity (ε) extending infinitely in the direction where ε is negative. Effective metamaterials with hyperbolic dispersion have been experimentally realized using layered metal-dielectric structures in a repeated stack, or via nanowire arrays, in the terahertz regime [64], generally achieved using a semiconductor such as graphene as opposed to a metal in the layered structure [65], and also in the optical range [66], for sub-wavelength imaging [67,68], focusing [69], and other applications [70][71][72]. A common approach is to use highly conductive metals, such as gold or silver, for the metallic component, and dielectrics such as SiO 2 for the dielectric component.…”

Section: Hyperbolic Metamaterialsmentioning

confidence: 99%

On-Chip Integration of a Plasmonic FET Source and a Nano-Patch Antenna for Efficient Terahertz Wave Radiation

Crabb,

Cantos-Roman,

Aizin

et al. 2023

Nanomaterials

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Graphene-based Field-Effect Transistors (FETs) integrated with microstrip patch antennas offer a promising approach for terahertz signal radiation. In this study, a dual-stage simulation methodology is employed to comprehensively investigate the device’s performance. The initial stage, executed in MATLAB, delves into charge transport dynamics within a FET under asymmetric boundary conditions, employing hydrodynamic equations for electron transport in the graphene channel. Electromagnetic field interactions are modeled via Finite-Difference Time-Domain (FDTD) techniques. The second stage, conducted in COMSOL Multiphysics, focuses on the microstrip patch antenna’s radiative characteristics. Notably, analysis of the S11 curve reveals minimal reflections at the FET’s resonant frequency of 1.34672 THz, indicating efficient impedance matching. Examination of the radiation pattern demonstrates the antenna’s favorable directional properties. This research underscores the potential of graphene-based FETs for terahertz applications, offering tunable impedance matching and high radiation efficiency for future terahertz devices.

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Hyperbolic Bismuth–Dielectric Structure for Terahertz Photonics

Cited by 5 publications

References 48 publications

Terahertz radiation detector based on thermoelectric material Bi-=SUB=-88-=/SUB=-Sb-=SUB=-12-=/SUB=--=SUP=-*-=/SUP=-

Terahertz radiation detector based on thermoelectric material Bi-=SUB=-88-=/SUB=-Sb-=SUB=-12-=/SUB=--=SUP=-*-=/SUP=-

Frequency-Selective Surface Based on Negative-Group-Delay Bismuth–Mica Medium

On-Chip Integration of a Plasmonic FET Source and a Nano-Patch Antenna for Efficient Terahertz Wave Radiation

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