Graphene-based tunable dual symmetric bound states in the continuum metasurface- implications in nanoscale high sensitivity sensing

In this paper, we have proposed a graphene-based dual symmetric bound states in the continuum (BIC) metasurface. On an all-graphene platform, we have shown that by breaking the symmetry in two ways, one can simultaneously access dual quasi-BIC (Q-BIC) spectra. The unit cell of the metasurface consis...

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Bibliographic Details
Published in:Applied physics. A, Materials science & processing Materials science & processing, 2025, Vol.131 (2), Article 119
Main Author: Roy, Shuvajit
Format: Article
Language:English
Subjects:
Asymmetry
Characterization and Evaluation of Materials
Chemical potential
Condensed Matter Physics
Graphene
Machines
Manufacturing
Metasurfaces
Methane
Nanotechnology
Nitrobenzene
Optical and Electronic Materials
Physics
Physics and Astronomy
Processes
Spectra
Surfaces and Interfaces
Symmetry
Thin Films
Unit cell
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Summary:In this paper, we have proposed a graphene-based dual symmetric bound states in the continuum (BIC) metasurface. On an all-graphene platform, we have shown that by breaking the symmetry in two ways, one can simultaneously access dual quasi-BIC (Q-BIC) spectra. The unit cell of the metasurface consists of the graphene etch patterned circles of equal radius on a dielectric substrate. The placement of the pattern is such that the structure is symmetric. By perturbing the radius of the circle at these symmetric positions, the asymmetry is introduced to access the first Q-BIC. Another way of accessing the Q-BIC spectra is to perturb the symmetric positions, maintaining the equal radii of the etched circles. Combining these two strategies, one can access the dual QBIC spectra based on the wavelength range of interest. Moreover, graphene is tunable with the control of its chemical potential. We have demonstrated our tunable structure at the MID-IR region in the transmission mode of operation. All the device dimensions are in the sub-wavelength range. The Q-factor of these plasmonic Q-BIC transmission dips has moderate values that hold wide prospects in sensing applications. For our proposed structure, we have shown application in nanoscale sensing of hazardous solvents like nitrobenzene and hazardous gases like methane, considering the experimental dispersion data. A minimum limit of detection (LOD) of 0.025 RIU and 0.0068 RIU has been reported for nitrobenzene and methane.
ISSN:0947-8396
1432-0630
DOI:10.1007/s00339-024-08225-9