Terahertz radiation enhancement based on LT-GaAs by optimized plasmonic nanostructure

Jiang, Rui; Cheng, Shuang; Li, Quanyong; Wang, Qishu; Xin, Yinjie

doi:10.1088/1555-6611/abd935

Cited by 2 publications

(1 citation statement)

References 31 publications

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“…These advancements are a culmination of interdisciplinary collaborations involving multiple fields, including low-dimensional substances [6][7][8], electronic semiconductors and photonic devices [9,10], heterogeneous integration [11,12] and system packaging [13,14]. Moreover, recent research has been directed towards miniaturizing THz technology through the utilization of plasmonic nanostructures [15][16][17], quantum-cascade lasers and spasers [18][19][20][21], quantum thermal devices [22][23][24], nanowires [25,26], plasmonic waveguides [27][28][29], and novel metamaterials [6,[30][31][32].…”

Section: Introductionmentioning

confidence: 99%

Floquet engineering-based frequency demodulation method for wireless THz short-range communications

Herath,

Nirmalathas,

Gunapala

et al. 2023

Phys. Scr.

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This study introduces a novel theoretical framework for detecting and decoding wireless communication signals in the nanoscale range operating at terahertz (THz) frequencies. Initially, we investigate the Floquet states in a dressed 2D semiconductor quantum well and derive an analytical expression to determine its longitudinal conductivity. The results indicate that the longitudinal conductivity of a dressed 2D semiconductor can be tailored to specific requirements by manipulating the frequency of the external dressing field. Furthermore, carefully selecting the intensity and polarization type of the external dressing field enables fine-tuning and optimization of the conductivity. To evaluate the effectiveness of each dressing field configuration, we present a Figure of Merit (FoM) assessment that determines the maximum possible change in conductivity within the considered frequency range. The proposed theory introduces a mechanism capable of identifying frequency-modulated communication signals in the THz range and performing frequency demodulation. We comprehensively analyze of the demodulator's transfer function in the receiver. Consequently, we establish that the transfer function exhibits linear behavior over a specific frequency range, rendering it suitable for frequency demodulation. Finally, we provide a numerical illustration of a frequency demodulation scenario. The breakthrough uncovered in this study opens up possibilities for the development of high-efficiency, lightweight, and cutting-edge chip-scale wireless communication devices, circuits, and components.

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