Linear and Nonlinear Optical Properties of Symmetric and Asymmetric Double Triangular Quantum Dots Withinside the Presence of Magnetic Field

IF 2.9 4区工程技术 Q1 MULTIDISCIPLINARY SCIENCES

Advanced Theory and Simulations Pub Date : 2024-10-07 DOI:10.1002/adts.202400554

Emre Bahadir AL, Norshamsuri Ali, Rosdisham Endut, Syed Alwee Aljunid, Norshah Rizal Ali, Nor Roshidah Yusof

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引用次数: 0

Abstract

Linear and third‐order nonlinear optical absorption coefficients and relative refractive index changes in symmetric and asymmetric double triangular quantum dots are examined theoretically. The dependence of these optical properties on the magnetic field is examined. After calculating energies and wave functions within the effective mass and parabolic band approaches, analytical expressions of linear and nonlinear optical properties are obtained using the compact density matrix approach and iterative method. Numerical calculations are presented for typical GaAs/AlGaAs material. The results show that the magnetic field causes different effects on the and transitions. Moreover, the calculated results also reveal that the resonance frequency and nonlinear contribution are different in symmetric and asymmetric structures. As a result, it is concluded that the magnetic field plays a vital and important role in the electronic and optical properties of the system and can be used to tune the inter‐subband transitions and change the corresponding optical sensitivities.

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对称和不对称双三角形量子点在磁场中的线性和非线性光学特性

从理论上研究了对称和非对称双三角形量子点的线性和三阶非线性光学吸收系数以及相对折射率变化。研究了这些光学特性对磁场的依赖性。在有效质量和抛物线带方法中计算能量和波函数后，利用紧凑密度矩阵方法和迭代法获得了线性和非线性光学特性的分析表达式。对典型的砷化镓/砷化镓材料进行了数值计算。结果表明，磁场会对和跃迁产生不同的影响。此外，计算结果还显示，对称结构和非对称结构的共振频率和非线性贡献是不同的。因此，结论是磁场对系统的电子和光学特性起着至关重要的作用，可用于调整子带间的转变并改变相应的光学灵敏度。

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来源期刊

Advanced Theory and Simulations Multidisciplinary-Multidisciplinary

CiteScore

5.50

自引率

3.00%

发文量

221

期刊介绍： Advanced Theory and Simulations is an interdisciplinary, international, English-language journal that publishes high-quality scientific results focusing on the development and application of theoretical methods, modeling and simulation approaches in all natural science and medicine areas, including: materials, chemistry, condensed matter physics engineering, energy life science, biology, medicine atmospheric/environmental science, climate science planetary science, astronomy, cosmology method development, numerical methods, statistics