使用多层圆柱形量子点的UV发光器件中的受控激子特性:通过静水压力、温度和应变效应改善

IF 3.1 3区 物理与天体物理 Q2 Engineering Optik Pub Date : 2025-04-01 Epub Date: 2025-01-22 DOI:10.1016/j.ijleo.2025.172229
M. Hbibi , S. Chouef , R. Boussetta , A. El Moussaouy , O. Mommadi , F. Falyouni , C.A. Duque
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引用次数: 0

摘要

我们研究了被困在多层圆柱形量子点中的激子的光学特性,考虑了外部扰动和有限势垒约束势的影响。我们计算了发射波长、振荡器强度、结合能、激子辐射寿命和带间跃迁能(光致发光)。结合有效质量近似,采用变分方法计算这些能量。此外,我们还研究了第一势垒材料浓度和岩心半径和高度等几何参数的影响。我们还研究了温度和压力如何影响光激子特性,无论是否有应变效应。结果表明,几何参数不仅影响基态结合能和带间跃迁能,而且影响振荡器强度和辐射寿命。压力的施加增加了激子的结合能、辐射寿命和带间跃迁能,同时降低了振荡器强度和发射波长。我们还证明了变形显著地改变了导价带的边缘。
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Controlled exciton properties in UV light-emitting devices using multilayer cylindrical quantum dots: Improvement through hydrostatic pressure, temperature and strain effects
We have examined the optical characteristics of an exciton trapped in a multilayer cylindrical quantum dot, taking into account the impact of external perturbations and finite barrier confinement potentials. We compute the emission wavelength, oscillator strength, binding energy, exciton radiative lifetime, and interband transition energy (photoluminescence). Together with the effective mass approximation, a variational approach is used to calculate these energies. Furthermore, we investigate the impact of first barrier material concentration and geometric parameters like core radius and height. We also investigate how temperature and pressure affect opto-excitonic characteristics, both with and without strain effects. Our results show that the geometrical parameters influence not only the ground-state binding energy and the interband transition energy, but also affect the oscillator strength and the radiative lifetime. The application of pressure increases the exciton binding energy, radiative lifetime and interband transition energy, while reducing the oscillator strength and emission wavelength. We also demonstrate that deformation significantly modifies the edges of the conduction and valence bands.
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来源期刊
Optik
Optik 物理-光学
CiteScore
6.90
自引率
12.90%
发文量
1471
审稿时长
46 days
期刊介绍: Optik publishes articles on all subjects related to light and electron optics and offers a survey on the state of research and technical development within the following fields: Optics: -Optics design, geometrical and beam optics, wave optics- Optical and micro-optical components, diffractive optics, devices and systems- Photoelectric and optoelectronic devices- Optical properties of materials, nonlinear optics, wave propagation and transmission in homogeneous and inhomogeneous materials- Information optics, image formation and processing, holographic techniques, microscopes and spectrometer techniques, and image analysis- Optical testing and measuring techniques- Optical communication and computing- Physiological optics- As well as other related topics.
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