基于等离子 MIM 波导的 FR 传感器用于人体血红蛋白的折射率检测

IF 2.5 3区 物理与天体物理 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Lokendra Singh , Bukya Balaji , Yogesh Tripathi , Roshan Kumar , Sameer Yadav
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引用次数: 0

摘要

法诺共振(FR)是一种普遍现象,可用于实现电磁诱导透明(EIT)、高吸收和高灵敏度以及低功耗光子器件。本研究在等离子金属-绝缘体-金属 (MIM) 波导系统上提出了双 FR 折射率 (RI) 传感器模型。通过在总线波导中加入圆形和椭圆形纳米棒缺陷,实现了 FR 现象。共振源于缺陷的窄离散性和矩形谐振器的宽状态。分析方法包括有限差分时域(FDTD)和多模干涉耦合模式理论。通过控制缺陷直径、缺陷间距和耦合(谐振器与总线波导之间)距离,可以独立调整法诺线的形状和谐振峰幅度。此外,所提出的结构还能检测总线波导和谐振器中的 RI(人体血红蛋白)变化。使用圆形纳米棒缺陷获得的结果验证了 99.92 % 的自相关系数,确保了设备的线性和高性能。然而,通过使用两个椭圆形纳米棒缺陷,自相关系数达到了 99.7%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Plasmonic MIM waveguide based FR sensors for refractive index sensing of human hemoglobin
Fano resonance (FR) is a universal phenomenon that is used to attain electromagnetic-induced transparency (EIT), high absorption and sensitivity, and low-power photonic devices. This work presents dual FR refractive index (RI) sensor models on a plasmonic metal-insulator-metal (MIM) waveguide system. The FR phenomenon is attained by including circular and elliptic nanorod defects in the bus waveguides. The resonances originate from the defect's narrow discreteness and the rectangular resonator's broad state. Analytical methods such as finite difference time domain (FDTD) and multimode interference coupled mode theory are adopted to analyze the FRs. The shapes of the Fano line and resonance peak amplitude can be tuned independently by controlling the diameter of the defects, the separation between the defects, and the coupling (between the resonator and the bus waveguide) distance. Moreover, the proposed structures detect the RI (human hemoglobin) variation in the bus waveguide and resonator. The obtained results with circular nanorod defect verify the autocorrelation coefficient of 99.92 %, ensuring the device's linearity and high performance. However, an autocorrelation of 99.7 % is attained by using two elliptic nanorod defects.
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来源期刊
CiteScore
5.00
自引率
3.70%
发文量
77
审稿时长
62 days
期刊介绍: This journal establishes a dedicated channel for physicists, material scientists, chemists, engineers and computer scientists who are interested in photonics and nanostructures, and especially in research related to photonic crystals, photonic band gaps and metamaterials. The Journal sheds light on the latest developments in this growing field of science that will see the emergence of faster telecommunications and ultimately computers that use light instead of electrons to connect components.
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