Multi-resonance terahertz (THz) generation from magnetized cylindrical and spherical nanoclusters of AlAs and InP nanoparticles

We report a theoretical model for THz generation from the interaction of Gaussian laser beams with semiconductor nanoparticles suspended in argon gas in the presence of a DC magnetic field. Our investigations include two different shapes of nanoparticles [spherical (SNPs) and cylindrical (CNPs)]. Th...

Full description

Saved in:
Bibliographic Details
Published in:Physics of plasmas 2024-10, Vol.31 (10)
Main Authors: Manendra, Sharma, Mukesh Kumar, Gautam, Yogendra K., Jewariya, Mukesh, Malik, Anil K.
Format: Article
Language:English
Subjects:
Aluminum arsenides
Amplitudes
Argon
Beat frequencies
Cylindrical plasmas
Cylindrical waves
Electron beams
Electron density profiles
Gaussian beams (optics)
Indium phosphides
Laser beams
Lasers
Magnetic fields
Magnetic properties
Magnetic resonance
Magnetic semiconductors
Material properties
Nanoclusters
Nanoparticles
Resonance
Spherical plasmas
Spherical waves
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We report a theoretical model for THz generation from the interaction of Gaussian laser beams with semiconductor nanoparticles suspended in argon gas in the presence of a DC magnetic field. Our investigations include two different shapes of nanoparticles [spherical (SNPs) and cylindrical (CNPs)]. The laser fields ionize nanoparticles converting them into plasma, which takes the form of spherical and cylindrical periodic nanoclusters with the electron density profile n=n0+nqeiqz, where q is the wave number of the density ripple and nq is the amplitude of density modulation. In our investigations, nanoparticles of AlAs and InP semiconductors are considered. Resonance condition is obtained when the laser beat frequency matches with the surface plasmon frequency of nanoparticles. We obtain resonances at two different frequencies when we apply a DC magnetic field. The resonance frequencies of THz fields shift with the nanoparticles' shape and orientation. THz field amplitude varies with material properties, spacing, size, and orientation of the nanoparticles. The applied magnetic field enhances the THz field and also helps in controlling the field profile. A THz field ∼0.1GV/cm with ∼2% efficiency is obtained for an optimized set of parameters for CNPs.
ISSN:1070-664X
1089-7674
DOI:10.1063/5.0211237