Thermally tunable wideband and bifunctional plasmonic-VO2 metasurface in THz region

2022 6th International Conference on Millimeter-Wave and Terahertz Technologies (MMWaTT) Pub Date : 2022-12-13 DOI:10.1109/MMWaTT58022.2022.10172118

Navid Naghshpour, T. Pakizeh

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Abstract

In this paper, a thermally tunable plasmonic-VO2 metasurface with wideband bifunctionality is introduced and studied. This planar structure can be a wideband polarization converter and absorber based on insulator to metal phase change of VO2. In room temperature, the introduced metasurface is a linear (LP) to circular (CP) polarization converter for which the ellipticity is more than 95% and its operating bandwidth is 36.55 % in the wavelength range of 1.91 to 2.77 (μm). By increasing temperature up to 358 (K), VO2 faces phase change to metallic state and then the proposed metasurface acts as an absorber of electromagnetic waves for which the absorbance is more than 80% and its operating bandwidth is ~ 71%, in the wavelength range of 1.68 to 3.5 (μm). For this bifunctional metasurface, its ellipticity for the converter and absorbance for the absorber is almost insensitive to incident angle (θ°) up to 25° and 30° respectively for the both TE and TM modes. The effects of the polarization angle (φ°) is also studied and shown that by increasing polarization angle up to 90° in the absorber case, the working bandwidth of absorber is unaltered.

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太赫兹区热可调谐宽带双功能等离子体- vo2超表面

本文介绍并研究了一种具有宽带双功能的热可调谐等离子体- vo2超表面。这种平面结构可以作为基于绝缘体到金属的VO2相变的宽带极化变换器和吸收体。在室温下，引入的超表面是一个线性(LP)到圆(CP)偏振转换器，其椭圆率大于95%，工作带宽为36.55%，波长范围为1.91 ~ 2.77 (μm)。当温度升高至358 (K)时，VO2相变为金属态，该超表面在1.68 ~ 3.5 (μm)波长范围内吸收电磁波，吸光度大于80%，工作带宽为~ 71%。对于这种双功能超表面，其转换器的椭圆率和吸收器的吸光度对入射角(θ°)(分别为25°和30°)几乎不敏感。研究了极化角(φ°)对吸波器工作带宽的影响，结果表明，将吸波器的极化角增加到90°时，吸波器的工作带宽不变。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 6th International Conference on Millimeter-Wave and Terahertz Technologies (MMWaTT)

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