Ultra-efficient diamond plasmonic band-stop filter with enhanced effect

Zuoxin Zhang; Hengli Feng; Dongchao Fang; Jincheng Wang; Jingyu Zhang; Chang Liu; Guan Wang; Lehui Wang; Lingling Ran; Yang Gao; Yang Gao

doi:10.1364/AO.465299

Applied Optics
Vol. 61,
Issue 26,
pp. 7644-7652
(2022)
•https://doi.org/10.1364/AO.465299

Ultra-efficient diamond plasmonic band-stop filter with enhanced effect

Zuoxin Zhang, Hengli Feng, Dongchao Fang, Jincheng Wang, Jingyu Zhang, Chang Liu, Guan Wang, Lehui Wang, Lingling Ran, and Yang Gao

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Zuoxin Zhang, Hengli Feng, Dongchao Fang, Jincheng Wang, Jingyu Zhang, Chang Liu, Guan Wang, Lehui Wang, Lingling Ran, and Yang Gao, "Ultra-efficient diamond plasmonic band-stop filter with enhanced effect," Appl. Opt. 61, 7644-7652 (2022)

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Table of Contents Category
- Surface Optics and Plasmonics
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About this Article
History
- Original Manuscript: May 30, 2022
- Revised Manuscript: August 9, 2022
- Manuscript Accepted: August 9, 2022
- Published: September 6, 2022

Abstract

In this paper, a band-stop filter based on a surface plasmon polariton metal–insulator–metal is designed and studied. The relationship between wavelength and filter transmittance is simulated using the finite difference time domain method and coupled mode theory. Compared with a single-diamond resonator, the minimum transmittances of the double-diamond resonator and double-rectangular resonator at a fixed wavelength are increased by 11.33% and 14.25%, respectively, achieving an enhancement effect. The research results also show that the sensitivity of the filter can reach 860 nm/RIU. The structure has good application prospects in optical integration, optical communication, and optical information processing.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Parameter	Dip 1	Dip 2	Unit
$ε_{m}$	$- 17.72 + 0.208 i$	$- 34.57 + 0.469 i$
$ε_{i}$	1	1
$k_{0}$	9.772	7.436	$µ m^{- 1}$
$w$	50	50	nm
$k_{s p p} (ω)$	25.133	12.566	$µ m^{- 1}$
$L_{e f f}$	500	500	nm
$N$	2	1
$n_{e f f}$	2.572	1.69
$λ_{m}$	643	845	nm

Filters of Different Configurations	Resonance Wavelength $λ_{1}$	Transmittance at $λ_{1}$ (dB)	Resonance Wavelength $λ_{2}$	Transmittance at $λ_{2}$ (dB)
Filter 1	643	−18.055	845	−16.924
Filter 3	643	−17.951	845	−55.391
Filter 4	643	−38.711	845	−38.562
Filter 5	643	−38.562	845	−111.244

Reference	Waveguide Width $w$ (nm)	Resonance Wavelength (nm)	Transmittance (dB)	Wavelength Range (nm)
[13]	50	1300	−26.021	500–1800
[20]	50	626	−67.959	400–1000
[25]	50	642	−21.938	500–2000
[32]	50	780	−30.458	500–4000
Filter 5	50	845	−111.244	500–1000

Different Materials	Refractive Index	Resonance Wavelength (nm)	Sensitivity (nm/RIU)
Air	1.00	845	860
Blood plasma	1.35	1139	840
Hemoglobin	1.38	1161	832
Glucose	1.40	1179	835
Sylgard184	1.43	1203	833

Parameter	Dip 1	Dip 2	Unit
$ε_{m}$	$- 17.72 + 0.208 i$	$- 34.57 + 0.469 i$
$ε_{i}$	1	1
$k_{0}$	9.772	7.436	$µ m^{- 1}$
$w$	50	50	nm
$k_{s p p} (ω)$	25.133	12.566	$µ m^{- 1}$
$L_{e f f}$	500	500	nm
$N$	2	1
$n_{e f f}$	2.572	1.69
$λ_{m}$	643	845	nm

Abstract

Data availability

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Figures (7)

Tables (4)

Equations (12)

Applied Optics