Intense Terahertz Radiation Effect on Electronic and Intraband Optical Properties of Semiconductor Quantum Rings

“…Many studies have shown that nanoparticle size can be controlled by varying the laser photon energy (wavelength), where the particle size decreases as the number of irradiations of laser pulses increases [27][28][29][30]. Moreover, the intense laser (ILF) and electric fields (EF) induce repulsive effects that counteract the attractive Coulomb interaction between the correlated pair, reducing the overall E b , and therefore affecting the physical properties of these nanomaterials [31][32][33][34][35][36][37][38][39]. The influence of these two applied fields on some nanostructures has been widely investigated in the literature [40][41][42][43][44].…”

Intense Laser Field Effect on the Photo-Ionization Cross-Section of the First Exciton Transition in a Core/Shell Quantum Dot Submitted to an Applied Electric Field

“…Many studies have shown that nanoparticle size can be controlled by varying the laser photon energy (wavelength), where the particle size decreases as the number of irradiations of laser pulses increases [27][28][29][30]. Moreover, the intense laser (ILF) and electric fields (EF) induce repulsive effects that counteract the attractive Coulomb interaction between the correlated pair, reducing the overall E b , and therefore affecting the physical properties of these nanomaterials [31][32][33][34][35][36][37][38][39]. The influence of these two applied fields on some nanostructures has been widely investigated in the literature [40][41][42][43][44].…”

Intense Laser Field Effect on the Photo-Ionization Cross-Section of the First Exciton Transition in a Core/Shell Quantum Dot Submitted to an Applied Electric Field

Electronic and Magnetic Properties of Laser Dressed Quantum Dot and Ring with Rashba Spin-Orbit Coupling

Fine-tuning a few nonlinear optical properties of doped GaAs quantum dot by spatial spread of impurity under the aegis of noise