Technology and research on the influence of liquid crystal cladding doped with magnetic Fe3O4 nanoparticles on light propagation in an optical taper sensor

IF 2.3 Q2 OPTICS
Michał Niewczas, K. Stasiewicz, N. Przybysz, Anna Pakuła, Jan Paczesny, Rafał Zbonikowski, Jerzy Dziaduszek, Przemysław Kula, L. Jaroszewicz
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Abstract

The results obtained for new dual-cladding optical fiber tapers surrounded by liquid crystal (LC) doped with Fe3O4 nanoparticles in a specially developed glass cell are presented. The created structures are sensitive to changes in refractive index values in the surrounding medium caused by modifying external environment parameters. In this investigation, cells are filled with nematic LCs 6CHBT and with the same mixture doped with 0.1 wt% and 0.5 wt% of magnetic nanoparticles (Fe3O4 NPs). The taper is made on a standard single-mode telecommunication fiber, stretched out to a length of 20.0 ± 0.5 mm, and the diameter of the tapers is approximately 15.0 ± 0.3 μm, with a loss lower than 0.5 dB @ 1,550 nm. Measurements are carried out in a wide range covering the visible and infrared ranges in two setups: 1) without a magnetic field, with steering only by voltage and 2) with an applied magnetic field. The presented spectrum results are divided into two ranges according to the parameters of optical spectrum analyzers: 350–1,200 nm and 1,200–2,400 nm. For all investigations, a steering voltage is chosen from the range of 0 to 200 V, which allows for establishing the influence of dopants on transmitted power and time response at different arrangements. Due to the sensitivity of LCs to temperature changes, this paper focuses on measuring at room temperature the effect of the magnetic field on propagation in a fiber optic taper. The proposed solution demonstrates the technology for creating advanced components as a combination of fiber optic technology, LCs, and nanoparticles. The presented results show the possibility of creating new sensors of various external factors such as magnetic or electric fields in miniaturized dimensions.
掺杂磁性 Fe3O4 纳米粒子的液晶包层对光学锥形传感器中光传播影响的技术与研究
本文介绍了在专门开发的玻璃池中,由掺有 Fe3O4 纳米粒子的液晶(LC)包围的新型双包层光纤锥体所获得的结果。所创建的结构对外部环境参数的改变所引起的周围介质折射率值的变化非常敏感。在这项研究中,电池中填充了向列低聚物 6CHBT 和掺杂了 0.1 wt% 和 0.5 wt% 磁性纳米粒子(Fe3O4 NPs)的相同混合物。锥形光纤是在标准单模电信光纤上制作的,拉伸长度为 20.0 ± 0.5 mm,锥形光纤的直径约为 15.0 ± 0.3 μm,波长为 1,550 nm 时的损耗低于 0.5 dB。测量在可见光和红外线范围内进行,有两种设置:1) 无磁场,仅通过电压转向;2) 有外加磁场。根据光学光谱分析仪的参数,所呈现的光谱结果分为两个范围:350-1,200 纳米和 1,200-2,400 纳米。在所有研究中,都从 0 到 200 V 的范围内选择了一个转向电压,以确定掺杂剂在不同排列下对传输功率和时间响应的影响。由于低通滤波器对温度变化的敏感性,本文侧重于在室温下测量磁场对光纤锥中传播的影响。所提出的解决方案展示了结合光纤技术、低浓光学元件和纳米粒子来制造先进元件的技术。所展示的结果表明,有可能以微型尺寸制造出针对各种外部因素(如磁场或电场)的新型传感器。
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来源期刊
CiteScore
4.40
自引率
0.00%
发文量
23
期刊介绍: Advanced Optical Technologies is a strictly peer-reviewed scientific journal. The major aim of Advanced Optical Technologies is to publish recent progress in the fields of optical design, optical engineering, and optical manufacturing. Advanced Optical Technologies has a main focus on applied research and addresses scientists as well as experts in industrial research and development. Advanced Optical Technologies partners with the European Optical Society (EOS). All its 4.500+ members have free online access to the journal through their EOS member account. Topics: Optical design, Lithography, Opto-mechanical engineering, Illumination and lighting technology, Precision fabrication, Image sensor devices, Optical materials (polymer based, inorganic, crystalline/amorphous), Optical instruments in life science (biology, medicine, laboratories), Optical metrology, Optics in aerospace/defense, Simulation, interdisciplinary, Optics for astronomy, Standards, Consumer optics, Optical coatings.
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