Adjustment of Terahertz Properties Assigned to the First Lowest Transition of (D+, X) Excitonic Complex in a Single Spherical Quantum Dot Using Temperature and Pressure

Aghoutane, N.; Pérez, Laura M.; Tiutiunnyk, A.; Laroze, David; Baskoutas, Sotirios; Dujardin, F.; Fatimy, A. El; El-Yadri, M.; Feddi, E.

doi:10.3390/app11135969

Cited by 4 publications

(1 citation statement)

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“…Furthermore, the effects of the external fields on the optical properties of QDs with different shapes and sizes have been reported in several studies [27][28][29][30][31][32][33][34][35][36]. J. Wang et al investigated the effect of temperature on the exciton lifetime of PbS colloidal QDs [37].…”

Section: Introductionmentioning

confidence: 99%

Optical Gain of a Spherical InAs Quantum Dot under the Effects of the Intense Laser and Magnetic Fields

et al. 2023

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In quantum dots, where confinement is strong, interactions between charge carriers play an essential role in the performance of semiconductor materials for optical gain. Therefore, understanding this phenomenon is critical for achieving new devices with enhanced features. In this context, the current study examines the optical properties of an exciton confined in a spherical InAs quantum dot under the influence of magnetic and intense laser fields. We investigate the oscillator strength, exciton lifetime, and optical gain, considering the effects of both external fields. We also pay particular attention to the influence of quantum dot size on the results. Our calculations show that the two external fields have opposite effects on our findings. Specifically, the applied magnetic field increases the oscillator strength while the intense laser reduces it. In addition, the optical gain peaks are redshifted under the application of the intense laser, whereas the magnetic field causes a blueshift of the peak threshold. We also find that both external perturbations significantly influence the exciton lifetime. Our study considers the outcomes of both the exciton’s ground (1s) and first excited (1p) states. The theoretical results obtained in this study have promising implications for optoelectronic devices in the ∼3–4 μm wavelength range only through the control of quantum dot sizes and external perturbations.

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