Superconducting Complementary Metamaterial‐Based Switchable Device for Terahertz Wave Manipulation

physica status solidi (b) Pub Date : 2023-07-18 DOI:10.1002/pssb.202300203

Chun Li, Yan Teng, Hao-Chung Chen, R. Su, Hancong Sun, Ling Jiang

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Abstract

Herein, a tunable superconducting switch that can modulate terahertz waves is designed and experimentally demonstrated. The switchable device consists of two symmetrical split ring resonator antistructures made from niobium nitride film in one unit cell. The relatively high modulation depths of 88.5% can be obtained at resonance peaks of 0.328 THz by applying a very low bias voltage of 0.8 V. Due to the presence of higher‐order resonance modes, the superconducting device also demonstrates a multiband tuning ability at 1.03 and 1.16 THz. To further analyze the modulation mechanism of the superconducting device, the temperature dependence of the switchable device is also measured. The trends of conductivity change are calculated based on the Bardeen–Cooper–Schrieffer theory and the simulations agree well with the experimental results. During the experiment, this device not only owns a good switching capability but also shows significant frequency selective bandpass characteristics. This study delivers a promising approach for designing active and miniaturized devices, especially for applications in THz cryogenic systems.

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基于超导互补超材料的太赫兹波操纵开关器件

本文设计了一种可调谐的超导开关，并进行了实验验证。该开关装置由两个对称的分裂环谐振器反结构组成，该结构由氮化铌薄膜制成。在0.328 THz的谐振峰处，施加0.8 V的极低偏置电压，可以获得88.5%的调制深度。由于高阶共振模式的存在，超导器件在1.03和1.16太赫兹也表现出多波段调谐能力。为了进一步分析超导器件的调制机制，还测量了可开关器件的温度依赖性。基于Bardeen-Cooper-Schrieffer理论计算了电导率的变化趋势，模拟结果与实验结果吻合较好。在实验中，该器件不仅具有良好的开关性能，而且具有显著的频率选择性带通特性。这项研究为设计有源和小型化器件提供了一种有前途的方法，特别是在太赫兹低温系统中的应用。

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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physica status solidi (b)

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