石墨烯负载锑化铟平面结构支持的随温度变化的电磁表面波

IF 1.8 4区 物理与天体物理 Q3 OPTICS
M. Z. Yaqoob, Ahtisham Ali, Majeed A. S. Alkanhal, A. Ghaffar, Y. Khan, M. Umair
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引用次数: 0

摘要

本研究对石墨烯涂层锑化铟(InSb)平面波导支持的电磁表面波的传播特性进行了理论和数值研究。石墨烯的建模使用了 Kubo 公式,而锑化铟的相对介电常数则使用 Drude 模型计算。横向电(TE)和横向磁(TM)极化表面波的结果是通过分析和数值计算得出的。主要的挑战在于对 InSb 接地平板上原子厚度的石墨烯薄片进行建模。为了得到与温度相关的电磁表面波特征方程,我们采用了表面电流边界条件方法。计算了 TE 和 TM 偏振态的数值结果,结果表明 TE 不支持表面波的传播。我们在 Mathematica 中计算了 TM 极化条件下的色散关系、有效模式指数、相位速度、传播长度和场剖面。研究发现,石墨烯和锑化铟分别在低太赫兹和高太赫兹区域具有活力。随着温度的升高,锑化铟的等离子体频率也随之升高。此外,随着温度的升高,横向磁极化表面波的有效波数也会增加。因此,由石墨烯负载的 InSb 支持的这种表面波的约束性增加了。研究表明,随着锑化铟温度的变化,跨界面传播的表面波可以在太赫兹区域进行调整,并可用于热光学传感、近场通信波导和基于石墨烯的温度传感器设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Temperature-Dependent Electromagnetic Surface Wave Supported by Graphene-Loaded Indium Antimonide Planar Structure
In this study, the propagation characteristics of EM surface waves supported by the graphene-coated indium antimonide (InSb) planar waveguide have been investigated theoretically and numerically. The modeling of graphene has been performed by use of Kubo formalism whereas the relative permittivity of indium antimonide has been calculated using Drude’s model. The results for transverse electric (TE) and transverse magnetic (TM) polarized surface waves have been computed analytically and numerically. The major challenge is to model the atomically thick graphene sheet over the InSb grounded slab. To get the temperature-dependent characteristic equation for the electromagnetic surface waves, the surface current boundary conditions’ approach has been employed. The numerical results have been computed for both the TE and TM polarization states and reported that the TE does not support the propagation of surface waves. The dispersion relation, effective mode index, phase speed, propagation length, and field profile have been computed in Mathematica under TM polarization. The graphene and indium antimonide have been found active for low and high Terahertz regions, respectively. As temperature increases, the plasma frequency of the InSb increases due to this reason with the increase of temperature and the resonance frequency, leading to a shift in the dispersion curve. Moreover, with the increase of temperature, the effective wave number of transverse magnetic polarized surface waves also increases. Resultantly, the confinement of such surface waves supported by graphene-loaded InSb increases. It is shown that with the variation of temperature of indium antimonide, the surface waves propagating across the interface can be tuned in the Terahertz region and can be exploited for thermo-optical sensing, near-field communications waveguides, and graphene-based temperature sensor designing.
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来源期刊
International Journal of Optics
International Journal of Optics Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
3.40
自引率
5.90%
发文量
28
审稿时长
13 weeks
期刊介绍: International Journal of Optics publishes papers on the nature of light, its properties and behaviours, and its interaction with matter. The journal considers both fundamental and highly applied studies, especially those that promise technological solutions for the next generation of systems and devices. As well as original research, International Journal of Optics also publishes focused review articles that examine the state of the art, identify emerging trends, and suggest future directions for developing fields.
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