Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays

Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays

Here we propose a novel high <i>Q</i> ultra-narrow-band filter in the optical regime. Multiple high <i>Q</i> resonances are achieved in ultra-thin metallic nanoslit arrays on stacked low index–high index dielectric (LID–HID) substrate. Based on the cooperative effect of suppr...

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Bibliographic Details
Main Authors: Ling Guo, Mengran Guo, Hongyan Yang, Jun Ma, Shouhong Chen
Format: Article
Language:English
Published: MDPI AG 2020-09-01
Series:Sensors
Subjects:
surface plasmon
nonlinear optics
hybrid SP resonance
high <i>Q</i> resonance
Online Access:https://www.mdpi.com/1424-8220/20/18/5205
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spelling doaj-c830067576344594a99a420bbb2b06482020-11-25T01:56:08ZengMDPI AGSensors1424-82202020-09-01205205520510.3390/s20185205Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit ArraysLing Guo0Mengran Guo1Hongyan Yang2Jun Ma3Shouhong Chen4School of Electronic Engineering and Automation, Guilin University of Electronic Technology, Guilin 541004, ChinaSchool of Electronic Engineering and Automation, Guilin University of Electronic Technology, Guilin 541004, ChinaSchool of Electronic Engineering and Automation, Guilin University of Electronic Technology, Guilin 541004, ChinaSchool of Electronic Engineering and Automation, Guilin University of Electronic Technology, Guilin 541004, ChinaSchool of Electronic Engineering and Automation, Guilin University of Electronic Technology, Guilin 541004, ChinaHere we propose a novel high <i>Q</i> ultra-narrow-band filter in the optical regime. Multiple high <i>Q</i> resonances are achieved in ultra-thin metallic nanoslit arrays on stacked low index–high index dielectric (LID–HID) substrate. Based on the cooperative effect of suppressed modes and transmission modes, the high spectral resolution of transmission peaks is obtained. The number and <i>Q</i> factor of transmission peaks can be freely manipulated by a simple combination of the stacked LID–HID. It is demonstrated that the linewidths of the transmission peaks can be reduced down to the extreme limit of 1 nm and the <i>Q</i> factor is up to 700 by optimizing the structure parameter of the three-layer LID–HID. The results provide a theoretical basis to design a multi-band nanophotonic device with a high <i>Q</i> factor and have potential applications in the next generation of high-resolution plasmonic biosensing and filtering.https://www.mdpi.com/1424-8220/20/18/5205surface plasmonnonlinear opticshybrid SP resonancehigh <i>Q</i> resonance
collection DOAJ
language English
format Article
sources DOAJ
author Ling Guo
Mengran Guo
Hongyan Yang
Jun Ma
Shouhong Chen
spellingShingle Ling Guo
Mengran Guo
Hongyan Yang
Jun Ma
Shouhong Chen
Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays
Sensors
surface plasmon
nonlinear optics
hybrid SP resonance
high <i>Q</i> resonance
author_facet Ling Guo
Mengran Guo
Hongyan Yang
Jun Ma
Shouhong Chen
author_sort Ling Guo
title Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays
title_short Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays
title_full Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays
title_fullStr Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays
title_full_unstemmed Ultra-Narrow-Band Filter Based on High Q Factor in Metallic Nanoslit Arrays
title_sort ultra-narrow-band filter based on high q factor in metallic nanoslit arrays
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2020-09-01
description Here we propose a novel high <i>Q</i> ultra-narrow-band filter in the optical regime. Multiple high <i>Q</i> resonances are achieved in ultra-thin metallic nanoslit arrays on stacked low index–high index dielectric (LID–HID) substrate. Based on the cooperative effect of suppressed modes and transmission modes, the high spectral resolution of transmission peaks is obtained. The number and <i>Q</i> factor of transmission peaks can be freely manipulated by a simple combination of the stacked LID–HID. It is demonstrated that the linewidths of the transmission peaks can be reduced down to the extreme limit of 1 nm and the <i>Q</i> factor is up to 700 by optimizing the structure parameter of the three-layer LID–HID. The results provide a theoretical basis to design a multi-band nanophotonic device with a high <i>Q</i> factor and have potential applications in the next generation of high-resolution plasmonic biosensing and filtering.
topic surface plasmon
nonlinear optics
hybrid SP resonance
high <i>Q</i> resonance
url https://www.mdpi.com/1424-8220/20/18/5205
work_keys_str_mv AT lingguo ultranarrowbandfilterbasedonhighqfactorinmetallicnanoslitarrays
AT mengranguo ultranarrowbandfilterbasedonhighqfactorinmetallicnanoslitarrays
AT hongyanyang ultranarrowbandfilterbasedonhighqfactorinmetallicnanoslitarrays
AT junma ultranarrowbandfilterbasedonhighqfactorinmetallicnanoslitarrays
AT shouhongchen ultranarrowbandfilterbasedonhighqfactorinmetallicnanoslitarrays
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