Optical steelyard: high-resolution and wide-range refractive index sensing by synergizing Fabry–Perot interferometer with metafibers

IF 15.7 Q1 OPTICS
Lei Zhang, Xinggang Shang, Simin Cao, Qiannan Jia, Jiyong Wang, Wei Yan, Min Qiu
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Abstract

Refractive index (RI) sensors play an important role in various applications including biomedical analysis and food processing industries. However, developing RI sensors with both high resolution and wide linear range remains a great challenge due to the tradeoff between quality (Q) factor and free spectral range (FSR) of resonance mode. Herein, the optical steelyard principle is presented to address this challenge by synergizing resonances from the Fabry–Perot (FP) cavity and metasurface, integrated in a hybrid configuration form on the end facet of optical fibers. Specifically, the FP resonance acting like the scale beam, offers high resolution while the plasmonic resonance acting like the weight, provides a wide linear range. Featuring asymmetric Fano spectrum due to modal coupling between these two resonances, a high Q value (~ 3829 in liquid) and a sensing resolution (figure of merit) of 2664 RIU−1 are experimentally demonstrated. Meanwhile, a wide RI sensing range (1.330–1.430 in the simulation and 1.3403–1.3757 in the experiment) is realized, corresponding to a spectral shift across several FSRs (four and two FSRs in the simulation and experiment, respectively). The proposed steelyard RI sensing strategy is promising in versatile monitoring applications, e.g., water salinity/turbidity and biomedical reaction process, and could be extended to other types of sensors calling for both high resolution and wide linear range.

Abstract Image

光学秤砣:通过法布里-珀罗干涉仪与金属纤维的协同作用实现高分辨率和宽范围折射率传感
折射率(RI)传感器在生物医学分析和食品加工业等各种应用中发挥着重要作用。然而,由于共振模式的质量(Q)系数和自由光谱范围(FSR)之间的权衡,开发高分辨率和宽线性范围的 RI 传感器仍然是一项巨大的挑战。本文提出了光学秤砣原理,通过将法布里-珀罗(Fabry-Perot,FP)腔和元表面的共振协同作用,以混合配置形式集成到光纤端面,从而解决这一难题。具体来说,法布里-珀罗共振就像刻度光束,可提供高分辨率,而等离子共振就像砝码,可提供宽线性范围。由于这两种共振之间的模态耦合作用,产生了不对称的法诺谱,实验证明了高 Q 值(液体中约为 3829)和 2664 RIU-1 的传感分辨率(优点值)。同时,还实现了较宽的 RI 传感范围(模拟中为 1.330-1.430,实验中为 1.3403-1.3757),与跨越多个 FSR(模拟和实验中分别为四个和两个 FSR)的光谱偏移相对应。所提出的秤砣 RI 传感策略在水的盐度/湍流度和生物医学反应过程等多种监测应用中大有可为,并可扩展到要求高分辨率和宽线性范围的其他类型传感器。
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来源期刊
CiteScore
25.70
自引率
0.00%
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审稿时长
13 weeks
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