Optimizing and Predicting Performance of Dual-Side Polished SPR Photonic Crystal Fiber using MLR and ANN Models

IF 3.3 4区物理与天体物理 Q2 CHEMISTRY, PHYSICAL

Plasmonics Pub Date : 2024-09-12 DOI:10.1007/s11468-024-02534-8

Lamia Guedri-Knani, Sameh Kaziz, Cherif Dridi

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Abstract

This research presents a surface plasmon resonance (SPR) biosensor that incorporates a dual-side polished photonic crystal fiber (PCF). The biosensor uses an external gold (Au) coating as the plasmonic layer to identify changes in the refractive index (RI) of various analytes. Five critical design parameters, including the diameters of the air holes and the thicknesses of both the analyte and gold layers, were optimized using the Taguchi L₈(2⁵) orthogonal array method. The optimization resulted in outstanding spectral and amplitude sensitivities, achieving 1000 nm/RIU and 98.422 RIU⁻¹, respectively. Additionally, Multiple Linear Regression (MLR) and Multi-Layer Perceptron Artificial Neural Network (MLP-ANN) models were employed to predict the sensor’s confinement loss. The findings demonstrate the efficacy of artificial neural networks in providing quick and accurate predictions for various geometric configurations, showcasing their potential in this advanced application. The designed sensor can detect a wide range of analytes (RI range of 1.28–1.44), making it suitable for applications in organic chemical detection, pharmaceutical analysis, and biosensing.

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利用 MLR 和 ANN 模型优化和预测双面抛光 SPR 光子晶体光纤的性能

这项研究提出了一种表面等离子体共振（SPR）生物传感器，它采用了双面抛光光子晶体光纤（PCF）。该生物传感器使用外部金（Au）涂层作为等离子体层，以识别各种分析物的折射率（RI）变化。利用田口 L8(25) 正交阵列法优化了五个关键设计参数，包括气孔直径以及分析物层和金层的厚度。优化后的光谱灵敏度和振幅灵敏度都非常出色，分别达到了 1000 nm/RIU 和 98.422 RIU-1。此外，还采用了多重线性回归（MLR）和多层感知器人工神经网络（MLP-ANN）模型来预测传感器的封闭损失。研究结果表明，人工神经网络能对各种几何配置进行快速、准确的预测，展示了其在这一先进应用中的潜力。所设计的传感器可检测多种分析物（RI 范围为 1.28-1.44），因此适合应用于有机化学检测、药物分析和生物传感。

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来源期刊

Plasmonics 工程技术-材料科学：综合

CiteScore

5.90

自引率

6.70%

发文量

164

审稿时长

2.1 months

期刊介绍： Plasmonics is an international forum for the publication of peer-reviewed leading-edge original articles that both advance and report our knowledge base and practice of the interactions of free-metal electrons, Plasmons. Topics covered include notable advances in the theory, Physics, and applications of surface plasmons in metals, to the rapidly emerging areas of nanotechnology, biophotonics, sensing, biochemistry and medicine. Topics, including the theory, synthesis and optical properties of noble metal nanostructures, patterned surfaces or materials, continuous or grated surfaces, devices, or wires for their multifarious applications are particularly welcome. Typical applications might include but are not limited to, surface enhanced spectroscopic properties, such as Raman scattering or fluorescence, as well developments in techniques such as surface plasmon resonance and near-field scanning optical microscopy.