Properties of optical bipolaron in symmetric quantum dot

IF 3.3 3区 物理与天体物理 Q2 PHYSICS, CONDENSED MATTER
J.-R.D. Djomou, A.J. Fotue, S.C. Kenfack, L.C. Fai
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引用次数: 0

Abstract

Optical bipolaron properties in the symmetric quantum dot were investigated using the Lee-Low-Pines-Huybrechts method and the Tokuda linear combination operator method. Algebraic expressions are derived for the energies of the fundamental and first excited states, the effective mass, mobility, binding energy and oscillation period of the optical bipolaron. Results prove that the energies of fundamental and first excited states increase with the coupling constant. Another point is that the strong coupling method dominates the weak coupling and the intermediate one when the electron-phonon coupling enhances. We also observe that the binding energy becomes always positive when confinement strength is above 5. In other points, the binding energy of optical bipolaron is well studied in all coupling, especially in weak coupling. It is also noticed that energies are increasing the function of the dielectric ratio and the oscillation period is reducing with the dielectric ratio. This proves that the electron-electron interaction is strengthened in a quantum dot. The stronger the coupling, the higher mobility in the case of low temperature.

对称量子点中光学双极化子的性质
利用Lee-Low-Pines-Huybrechts方法和Tokuda线性组合算子方法研究了对称量子点的光学双极化子性质。导出了光学双极化子的基本激发态和第一激发态能量、有效质量、迁移率、结合能和振荡周期的代数表达式。结果表明,基本态和第一激发态的能量随耦合常数的增大而增大。另一点是,当电子-声子耦合增强时,强耦合方法优于弱耦合方法和中间耦合方法。我们还观察到,当约束强度大于5时,结合能总是正的。在其他方面,光学双极化子的结合能在所有耦合,特别是弱耦合中得到了很好的研究。能量随介电比的增大而增大,振荡周期随介电比的增大而减小。这证明了电子-电子相互作用在量子点中得到加强。在低温条件下,耦合越强,迁移率越高。
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来源期刊
Superlattices and Microstructures
Superlattices and Microstructures 物理-物理:凝聚态物理
CiteScore
6.10
自引率
3.20%
发文量
35
审稿时长
2.8 months
期刊介绍: Micro and Nanostructures is a journal disseminating the science and technology of micro-structures and nano-structures in materials and their devices, including individual and collective use of semiconductors, metals and insulators for the exploitation of their unique properties. The journal hosts papers dealing with fundamental and applied experimental research as well as theoretical studies. Fields of interest, including emerging ones, cover: • Novel micro and nanostructures • Nanomaterials (nanowires, nanodots, 2D materials ) and devices • Synthetic heterostructures • Plasmonics • Micro and nano-defects in materials (semiconductor, metal and insulators) • Surfaces and interfaces of thin films In addition to Research Papers, the journal aims at publishing Topical Reviews providing insights into rapidly evolving or more mature fields. Written by leading researchers in their respective fields, those articles are commissioned by the Editorial Board. Formerly known as Superlattices and Microstructures, with a 2021 IF of 3.22 and 2021 CiteScore of 5.4
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