Ultra-high-Q and ultra-sensitive refractive index sensing in low refractive index dielectric gratings based on bound states in the continuum

Ze-Zhou Fang; Han-Lei Xu; Jin-Yue Su; Jin-Yun Zhou; Jin-Yun Zhou; Zi-Ming Meng; Zi-Ming Meng

doi:10.1364/JOSAB.506368

Journal of the Optical Society of America B
Vol. 41,
Issue 1,
pp. 98-104
(2024)
•https://doi.org/10.1364/JOSAB.506368

Ultra-high-Q and ultra-sensitive refractive index sensing in low refractive index dielectric gratings based on bound states in the continuum

Ze-Zhou Fang, Han-Lei Xu, Jin-Yue Su, Jin-Yun Zhou, and Zi-Ming Meng

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Ze-Zhou Fang, Han-Lei Xu, Jin-Yue Su, Jin-Yun Zhou, and Zi-Ming Meng, "Ultra-high-Q and ultra-sensitive refractive index sensing in low refractive index dielectric gratings based on bound states in the continuum," J. Opt. Soc. Am. B 41, 98-104 (2024)

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Abstract

The realization of a high quality factor ($Q$-factor) and strong local optical fields has long been of great interest in the field of nanophotonics. Unfortunately, it is still challenging to achieve high-$\!Q$ and strong localized fields in nanostructures made of low refractive index materials. In this study, drawing upon the concept of bound states in the continuum (BICs), an asymmetric dielectric grating composed of low refractive index materials is demonstrated to generate an ultra-high-$\!Q$ symmetry-protected quasi-BIC in the visible wavelength. Importantly, the design of BIC (quasi-BIC) mode enables the strong localized confinement of light in air. By leveraging this property, we realize ultra-sensitive refractive index sensing with a remarkable sensitivity of 669 nm/RIU and a high figure of merit (FOM) of $45,\!314\,\,{\rm RIU}^{-1}$. This study offers an approach to achieve highly sensitive and high precision refractive index sensing with potential applications in the practical realization of strong light–matter interactions using low index materials.

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The data that support the findings of this study are available from the corresponding author upon reasonable request.

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Structure	Working Waveband	$Q$ -Factor	RI Sensitivity (nm/RIU)	FOM ( ${R I U}^{- 1}$ )	Year and Reference
${T i O}_{2}$ dimers on gold	Visible light and near-infrared waveband	1540	80.6	80.6	2020 [32]
Si asymmetric dielectric gratings	Infrared waveband	—	1506	$\sim 5000$	2021 [26]
${S i}_{3} N_{4}$ Sub-wavelength high contrast gratings	Visible light waveband	—	221	4420	2021 [27]
${S i}_{3} N_{4}$ asymmetrical holes	Visible light and near-infrared waveband	$\sim 10^{8}$	425.9	$> 10^{6}$	2018 [24]
${T i O}_{2}$ grating on porous ${S i O}_{2}$	Visible light and near-infrared waveband	—	546	—	2017 [33]
Two silicon bars and quartz substrate	Near-infrared waveband	750	440	677	2020 [34]
${S i}_{3} N_{4}$ grating on ${S i O}_{2}$ substrate	Visible light	49,030	669	45,314	This work

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Journal of the Optical Society of America B