Graphene-coated terahertz photonic crystal fiber for refractive index sensor applications

International Conference on Photonics and Optical Engineering and the Annual West China Photonics Conference Pub Date : 2021-01-15 DOI:10.1117/12.2586728

Chenyu Guo, Doudou Wang, Jiaoxia Wei, Yue Zhang

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Abstract

A graphene-coated terahertz photonic crystal fiber (G-PCF) for refractive index (RI) sensing is proposed and numerically simulated by the finite element method (FEM). To enhance the sensitivity and produce birefringence, two larger air-holes are introduced in the innermost ring of holes around the solid core. Inner surface of the larger air-holes is coated with multilayer graphene and used for analyte filling. The guided modes of the designed G-PCF are distributed mainly in the larger air-holes as a result of the high permittivity and carrier mobility of graphene. The relative sensitivity coefficient can be improved more than 5 times by introducing the graphene coating for analytes with a RI in the range of 1.00 to 1.50. The highest relative sensitivity coefficient about 90% is obtained when RI is equal to 1.37. The relative sensitivity coefficient can be improved more than 15 times with RI equals to 1.03. The propagation properties and RI sensitivities of the G-PCF can be electrically and thermally controlled. Our results provide references for RI sensor applications of the designed GPCF in terahertz range.

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用于折射率传感器的石墨烯涂层太赫兹光子晶体光纤

提出了一种用于折射率传感的石墨烯涂层太赫兹光子晶体光纤(G-PCF)，并用有限元法对其进行了数值模拟。为了提高灵敏度和产生双折射，在实心周围孔的最内环中引入了两个较大的空气孔。较大的气孔内表面涂有多层石墨烯，用于分析物填充。由于石墨烯的高介电常数和载流子迁移率，所设计的G-PCF的导模主要分布在较大的气孔中。对于RI在1.00 ~ 1.50范围内的分析物，引入石墨烯涂层可使相对灵敏度系数提高5倍以上。当RI = 1.37时，相对灵敏度系数最高，约为90%。当RI = 1.03时，相对灵敏度系数可提高15倍以上。G-PCF的传播特性和RI灵敏度可以通过电和热控制。研究结果为设计的GPCF在太赫兹范围内的RI传感器应用提供了参考。

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International Conference on Photonics and Optical Engineering and the Annual West China Photonics Conference

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