Comparative Efficiency and Power Assessment of Optical Photoconductive Material-Based Terahertz Sources for Wireless Communication Systems

Yazgan, Ayhan; Jofre, L.; Romeu, J.

doi:10.1142/s0218126619500051

Cited by 4 publications

(3 citation statements)

References 85 publications

(83 reference statements)

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“…While substantial research has been concentrated on integrated circular-polarization detectors in the visible-to-mid-infrared range, the THz band remains relatively underexplored. The THz band, noted for its low photon energy [24,25], robust penetration capabilities [26,27], expansive communication bandwidth [28,29], and superior spatial and temporal resolution [30][31][32] compared to microwaves, holds significant potential for advancing imaging, spectroscopy, and wireless communication [33]. Thus, the development of miniaturized THz circular-polarization detectors, which addresses the challenges posed by bulky non-integrated detectors and the scarcity of suitable polarization optics in the THz range, is not only of great significance but also imminent.…”

Section: Introductionmentioning

confidence: 99%

Enhanced THz Circular-Polarization Detection in Miniaturized Chips with Chiral Antennas

Li,

Zhou,

Deng

et al. 2024

Photonics

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Recent advancements in terahertz (THz) wave technology have highlighted the criticality of circular-polarization detection, fostering the development of more compact, efficient on-chip THz circular-polarization detectors. In response to this technological imperative, we presented a chiral-antenna-integrated GaAs/AlGaAs quantum well (QW) THz detector. The chiral antenna selectively couples the incident light of a specific circular-polarization state into a surface-plasmon polariton wave that enhances the absorptance of the QWs by a factor of 12 relative to a standard 45° faceted device, and reflects a significant amount of the incident light of the orthogonal circular-polarization state. The circular-polarization selectivity is further enhanced by the QWs with a strong intrinsic anisotropy, resulting in a circular-polarization extinction ratio (CPER) as high as 26 at 6.52 THz. In addition, the operation band of the device can be adjusted by tuning the structural parameters of the chiral structure. Moreover, the device preserves a high performance for oblique incidence within a range of ±5°, and the device architecture is compatible with a focal plane array. This report communicates a promising approach for the development of miniaturized on-chip THz circular-polarization detectors.

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Section: Introductionmentioning

confidence: 99%

Enhanced THz Circular-Polarization Detection in Miniaturized Chips with Chiral Antennas

Li,

Zhou,

Deng

et al. 2024

Photonics

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“…Due to recent progress in the development of carbon nanotubes and graphene, the nano-communications have wide application area in biomedical, intra-body communications, military, vehicular networks and nano-satellite applications. [1][2][3][4] The nano-communications ¯eld has been separated into two sub-areas 5 as: I. Electromagnetic nano-communications, II. Molecular communications.…”

Section: Introductionmentioning

confidence: 99%

Covert Electromagnetic Nanoscale Communication System in the Terahertz Channel

Ahmed

Savacı

2019

J CIRCUIT SYST COMP

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In this paper, an electromagnetic nano random communication system (EM-nRCS) has been proposed which ensures covert communication in the terahertz (THz) band. In the proposed system, the skewed alpha-stable noise shift keying method has been used to transmit random noise signals (RNSs) from the nano-transmitter (NT) by utilizing single-walled/carbon nanotubes-based true random number generator (SWCNTs-TRNG) and a graphene-based nano-antenna. A line-of-sight THz transparency window between 0.1[Formula: see text]THz and 0.5[Formula: see text]THz in the THz channel with spreading loss, molecular absorption loss and molecular absorption noise has been considered. Due to the broadband nature of the RNSs, the proposed EM-nRCS provides efficient transmission by overcoming the high path loss and intense channel noise arising from random fluctuations in the THz band. Non-coherent nano-receiver (NR) consisting of the modified extreme value method (MEVM) estimator has been proposed to extract the hidden binary information in the received RNSs. The bit error rate performance shows that the proposed EM-nRCS ensures high performance and covertness for future EM nanoscale communication devices.

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“…The operating frequency located at this terahertz gap is too high for solid-state electronics, while being too low for optical circuits. 19 (2) The scaled CMOS transistor model in THz frequency range is not completely accurate, which makes the design of the CMOS signal generator more di±cult. Meanwhile, the e®ective transistor transconductance becomes lower and lower as the operating frequency of the ICs increases.…”

Section: Introductionmentioning

confidence: 99%

A 217.6–227-GHz CMOS Signal Generator with Injection Locking Technique

Cheng

Qian

Luo

et al. 2019

J CIRCUIT SYST COMP

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This paper proposes a 217.6–227-GHz signal generator with injection locking technique in 65-nm CMOS process. The injection locking technique is exploited to synchronize the phases of the two individual voltage control oscillators (VCOs) and improve the output power. The phase noise of the proposed signal generator is improved. The full-layout electromagnetic (EM) simulation in collaboration with the post-layout simulation is utilized to verify the proposed signal generator. The simulation results show that the frequency tuning range is 9.4[Formula: see text]GHz, and the output power is larger than [Formula: see text]14.25[Formula: see text]dBm. The phase noise at 1[Formula: see text]MHz off the carrier is better than [Formula: see text]92.12[Formula: see text]dBc/Hz. The signal generator occupies a compact silicon area of 0.23[Formula: see text]mm2 including all testing pads.

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Comparative Efficiency and Power Assessment of Optical Photoconductive Material-Based Terahertz Sources for Wireless Communication Systems

Cited by 4 publications

References 85 publications

Enhanced THz Circular-Polarization Detection in Miniaturized Chips with Chiral Antennas

Enhanced THz Circular-Polarization Detection in Miniaturized Chips with Chiral Antennas

Covert Electromagnetic Nanoscale Communication System in the Terahertz Channel

A 217.6–227-GHz CMOS Signal Generator with Injection Locking Technique

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