Plastic Optical Fiber Sensors and Magnetic Fluids: Plasmonic Tunability and Sensing properties for Measurements

2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Pub Date : 2020-05-01 DOI:10.1109/I2MTC43012.2020.9129524

N. Cennamo, F. Arcadio, L. Zeni, B. Andò, S. Baglio, V. Marletta

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Abstract

The optical properties of multimode plastic optical fibers (POFs) could be used for both the monitoring of magnetic field and for the tuning of plasmonic phenomenon, when a magnetic fluid was deposited on its cladding and it is connected in input to a plasmonic POF sensor. In this case, a magnetic field exerts a bending force on the POF covered with magnetic fluid, thus producing a variation of light in input to the plasmonic POF sensor and changing the plasmonic phenomenon. In particular, the focus of this work is the assessment of the tuning mechanism for the plasmonic phenomenon, which has been performed through a dedicated measurement approach. Preliminary experimental results are here presented to demonstrate how this approach can be used to change several plasmonic parameters, such as the sensitivity and the signal-to-noise ratio (SNR). This approach could be used in biosensing applications, where even smaller variation of the plasmonic response can significantly improve the detection of substances.

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塑料光纤传感器和磁流体:用于测量的等离子体可调性和传感特性

当磁性流体沉积在多模塑料光纤的包层上，并将其作为输入端连接到等离子体POF传感器时，该光纤的光学特性可用于磁场监测和等离子体现象的调谐。在这种情况下，磁场对被磁性流体覆盖的POF施加弯曲力，从而使输入等离子体POF传感器的光发生变化，从而改变等离子体现象。特别是，这项工作的重点是对等离子体现象的调谐机制的评估，这是通过专门的测量方法进行的。初步的实验结果表明，这种方法可以用来改变几个等离子体参数，如灵敏度和信噪比(SNR)。这种方法可用于生物传感应用，其中即使等离子体响应的较小变化也可以显着提高对物质的检测。

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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2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)

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