Terahertz Plasmonic Metamaterial Based Multi-band Band-Pass Filter Using Micro-Ring Resonator

2019 USNC-URSI Radio Science Meeting (Joint with AP-S Symposium) Pub Date : 2019-07-01 DOI:10.1109/USNC-URSI.2019.8861742

R. Jaiswal, Nidhi Pandit, N. Pathak

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Abstract

This paper reports the design and theoretical analysis of the spoof plasmonic metamaterial based multi-band band-pass filter (BPF) using corrugated planar micro-ring resonator at THz frequency. Plasmonic metamaterial i.e. spoof surface plasmon polaritons structures support EM mode at the interface of the metal-dielectric and thus highly confined and localized E-field can be obtained. Due to this sub-wavelength field confinement, spoof SPP structures show low-loss, low crosstalk and low mutual coupling and is being used for developing the compact integrated circuits. Sub-wavelength rectangular grooves are corrugated on the metallic planar ring is fed through the spoof SPP transmission line at its input and output ports to provide a band-pass response. The detailed mathematical analysis is provided for the designed band-pass filter. The Full wave EM simulation is performed to obtain the reflection and transmission coefficient. The designed spoof plasmonic ring resonator will provide a path to design and development of the plasmonic sensors.

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基于太赫兹等离子体超材料的微环谐振器多带通滤波器

本文报道了基于欺骗等离子体超材料的多带带通滤波器(BPF)的设计和理论分析，该滤波器采用波纹平面微环谐振器在太赫兹频率下工作。等离子体超材料即欺骗表面等离子体激元结构在金属-介电介质界面处支持EM模式，从而可以获得高度受限和局域化的电磁场。由于这种亚波长场约束，欺骗SPP结构具有低损耗、低串扰和低互耦的特点，可用于开发小型集成电路。亚波长矩形槽在金属平面环上波纹，通过欺骗SPP传输线在其输入和输出端口馈送，以提供带通响应。对所设计的带通滤波器进行了详细的数学分析。进行了全波电磁仿真，得到了反射系数和透射系数。所设计的欺骗等离子体环形谐振器将为等离子体传感器的设计和开发提供一条途径。

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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2019 USNC-URSI Radio Science Meeting (Joint with AP-S Symposium)

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