AI Article Synopsis
- Metasurfaces have unique optical properties influenced by their refractive index ratio, making them suitable for sensing changes in refractive index in various environments.
- When used in biosensing, the presence of biomolecules creates refractive index gradients on the metasurface, leading to complex reflective spectra but distinct localized optical enhancements.
- The proposed metasurface design uses silicon nanopillars with a central nanotrench to achieve tunable resonances for detecting different refractive indices, and simulations demonstrate that these enhancements correspond to the refractive index distribution across the surface.
Article Abstract
Metasurfaces exhibit unique optical properties that depend on the ratio of their refractive index and that of their surroundings. As such, they are effective for sensing global changes in refractive index based on the shifts of resonances in their reflectivity spectra. However, when used as a biosensor, the metasurface can be exposed to a spatial distribution of biomolecules that brings about gradients in refractive index along the plane of the metasurface. Such gradients produce complex global reflectivity spectrum but with distinct optical enhancements in localized areas along the metasurface. Here, we propose a unique sensing paradigm that images and maps out the optical enhancements that are correlated with the spatial distribution of the refractive index. Moreover, we designed a metasurface whose resonances can be tuned to detect a range of refractive indices. Our metasurface consists of silicon nanopillars with a cylindrical nanotrench at their centers and a metal plane at the base. To assess its feasibility, we performed numerical simulations to show that the design effectively produces the desired reflectivity spectrum with resonances in the near-infrared. Using an incident light tuned to one of its resonances, our simulations further show that the field enhancements are correlated with the spatial mapping of the gradients of refractive indices along the metasurface.
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| http://dx.doi.org/10.1364/OE.402259 | DOI Listing |
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