High-efficiency refractive index sensor based on the metallic nanoslit arrays with gain-assisted materials-Reference-Cited by-同舟云学术

High-efficiency refractive index sensor based on the metallic nanoslit arrays with gain-assisted materials

Published:2016-09-01 Issue:4 Volume:5 Page:548-555
ISSN:2192-8614
Container-title:Nanophotonics
language:
Short-container-title:

Author:

Luo Linbao¹,Ge Caiwang¹,Tao Yifei²,Zhu Lie²,Zheng Kun¹,Wang Wei²,Sun Yongxuan²,Shen Fei¹,Guo Zhongyi¹²

Affiliation:

1. 1School of Electronics Science and Applied Physics, Hefei University of Technology, Hefei, 230009, China

2. 2School of Computer and Information, Hefei University of Technology, Hefei, 230009, China

Abstract

AbstractWe have designed and investigated a three-band refractive index (RI) sensor in the range of 550–900 nm based on the metal nanoslit array with gain-assisted materials. The underlying mechanism of the three-band and enhanced characteristics of the metal nanoslit array with gain-assisted materials, have also been investigated theoretically and numerically. Three resonant peaks in transmission spectra are deemed to be in different plasmonic resonant modes in the metal nanoslit array, which leads to different responses for the plasmonic sensor. By embedding the structure into the CYTOP with proper gain-assisted materials, the sensing performances can be greatly enhanced due to a dramatic amplification of the extraordinary optical transmission (EOT) resonance by the gain medium. When the gain values reach their corresponding thresholds for the three plasmonic modes, the ultrahigh sensitivities in three bands can be obtained, and especially for the second resonant wavelength (λ2), the FOM=128.1 and FOM* = 39100 can be attained at the gain threshold of k =0.011. Due to these unique features, the designing scheme of the proposed gain-assisted nanoslit sensor could provide a powerful approach to optimize the performance of EOT-based sensors and offer an excellent platform for biological sensing.

Publisher

Walter de Gruyter GmbH

Subject

Electrical and Electronic Engineering,Atomic and Molecular Physics, and Optics,Electronic, Optical and Magnetic Materials,Biotechnology

Link

https://www.degruyter.com/document/doi/10.1515/nanoph-2016-0028/pdf

Reference36 articles.

1. Sub - nm photolithography based on plasmon resonance Sub - nm photolithography based on plasmon resonanceJap;Luo;Appl Phys Appl Phys,2004

2. Sensitivity enhancement of nanoplasmonic sensors in low refractive index substrates Sensitivity enhancement of nanoplasmonic sensors in low refractive index substratesOpt;Brian;Opt Express Express,2009

3. Dispersed and encapsulated gain medium in plasmonic nanoparticles : a multipronged approach to mitigate optical losses Dispersed and encapsulated gain medium in plasmonic nanoparticles : a multipronged approach to mitigate optical lossesACSnano;Luca;ACSnano,2011

4. Surface plasmon resonance sensors : review Sensors and Actuators B : Chemical Surface plasmon resonance sensors : reviewSensors and Actuators;Homola;Chemical,1999

5. Light passing through subwavelength apertures Light passing through subwavelength aperturesRev;Garcia;Rev Mod Phys Mod Phys,2010

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