Comprehensive field pattern analysis for tailoring of reflectance in a hybrid subwavelength plasmonic grating refractive index sensor and its potential for noninvasive salivary glucose monitoring

Taban Qayoom; Taban Qayoom; Hakim Najeeb-ud-din

doi:10.1364/AO.474204

Applied Optics
Vol. 61,
Issue 32,
pp. 9429-9438
(2022)
•https://doi.org/10.1364/AO.474204

Comprehensive field pattern analysis for tailoring of reflectance in a hybrid subwavelength plasmonic grating refractive index sensor and its potential for noninvasive salivary glucose monitoring

Taban Qayoom and Hakim Najeeb-ud-din

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Taban Qayoom and Hakim Najeeb-ud-din, "Comprehensive field pattern analysis for tailoring of reflectance in a hybrid subwavelength plasmonic grating refractive index sensor and its potential for noninvasive salivary glucose monitoring," Appl. Opt. 61, 9429-9438 (2022)

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Table of Contents Category
- Surface Optics and Plasmonics
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.

About this Article
History
- Original Manuscript: August 29, 2022
- Revised Manuscript: October 20, 2022
- Manuscript Accepted: October 20, 2022
- Published: November 4, 2022

Abstract

A compact hybrid two-dimensional plasmonic subwavelength grating composed of gold and semiconductor ZnS is proposed. By implementing the finite-difference time-domain numerical technique, detailed field pattern analysis and reflectance characteristics of the grating structure are comprehensively investigated, tailored, and improved. An unfamiliar phenomenon of exponential decrease in resonance wavelength with an increase in groove width is observed, validated, and empirically modeled. This confirms that the reflectance resonance dip is because of the surface plasmon resonance in the grating structure, unlike the resonance dip obtained in the diffraction grating because of the Fabry–Perot resonance. A rigorous sensitivity analysis is performed for both generalized bulk and surface analyte detection. The surface sensitivity is observed to be 100.5 nm/RIU at dip 1 for 10-nm-surface analyte thickness. The bulk sensitivity for dip 1 and dip 2 was 104.3 nm/RIU and 800 nm/RIU, respectively. The refractive index range variation of dip 1 for the surface analyte is correlated with the refractive index of the blood by using the linear refractive index model and Gladstone–Dale law for blood. A linear regression analysis correlating blood glucose and salivary glucose with a surface analyte is used. The proposed sensor is observed to be promising for noninvasive salivary glucose monitoring with high surface sensitivity of 1.104 nm/mg/dl with a compact footprint of about $0.5\,\,\unicode{x00B5}\rm m \times 0.2\,\,\unicode{x00B5}\rm m$ in $x {-} z$ dimensions.

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Case	Grating Design Parameter Values (µm)	Resonance Wavelength (µm) $λ_{r e s} = P + Q e^{- \frac{(W - 0.02)}{R}}$
C1	$D 1 = 0$ , $D 2 = 0.05$	$λ_{r e s} = 0.905 + 0.352 e^{- \frac{(W - 0.02)}{0.032}}$
C2	$D 1 = 0$ , $D 2 = 0.1$ , Dip 1	$λ_{r e s} = 0.672 + 0.168 e^{- \frac{(W - 0.02)}{0.02}}$
C3	$D 1 = 0$ , $D 2 = 0.1$ , Dip 2	$λ_{r e s} = 1.467 + 0.662 e^{- \frac{(W - 0.02)}{0.035}}$
C4	$D 1 = 0$ , $D 2 = 0.15$ , Dip 1	$λ_{r e s} = 0.756 + 0.291 e^{- \frac{(W - 0.02)}{0.031}}$
C5	$D 1 = 0$ , $D 2 = 0.15$ , Dip 2	$λ_{r e s} = 2.035 + 0.869 e^{- \frac{(W - 0.02)}{0.024}}$
C6	$D 1 = 0.02$ , $D 2 = 0.05$	$λ_{r e s} = 1.06 + 0.32 e^{- \frac{(W - 0.02)}{0.036}}$
C7	$D 1 = 0.02$ , $D 2 = 0.1$ , Dip 1	$λ_{r e s} = 0.68 + 0.215 e^{- \frac{(W - 0.02)}{0.028}}$
C8	$D 1 = 0.02$ , $D 2 = 0.1$ , Dip 2	$λ_{r e s} = 1.65 + 0.646 e^{- \frac{(W - 0.02)}{0.032}}$
C9	$D 1 = 0.02$ , $D 2 = 0.15$ , Dip 1	$λ_{r e s} = 0.803 + 0.283 e^{- \frac{(W - 0.02)}{0.034}}$
C10	$D 1 = 0.02$ , $D 2 = 0.15$ , Dip 2	$λ_{r e s} = 2.15 + 0.92 e^{- \frac{(W - 0.02)}{0.031}}$

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Applied Optics