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Improved refractive-index sensing performance in medium contrast gratings by asymmetry engineering

Hardik Vyas, Ravi S. Hegde

2020Optical Materials Express25 citationsDOIOpen Access PDF

Abstract

Silicon nitride (Si 3 N 4 ) subwavelength medium contrast gratings (MCGs) directly integrated with CMOS photodetectors are a promising option for on-chip label-free biosensing. The narrow spectral features required for sensing are often realized in Si 3 N 4 nanostructures by weakly corrugated gratings which limit design flexibility. We numerically investigate the optical properties of asymmetry-engineered MCG gratings and predict the formation of ultra-sharp spectral features via the excitation of quasi-bound states in continuum (QBIC) resonances. Systematic investigation of the design parameter space shows that sharp spectral features are obtained for a wide range of parameters without requiring ultrathin grating profiles. Transmission-mode refractive index sensing simulations for bulk and surface sensing, considering both wavelength-shift and intensity-shift modalities, indicate performance gains using these structures.

Topics & Concepts

Materials scienceGratingRefractive indexOpticsRigorous coupled-wave analysisOptoelectronicsCoupled mode theoryRefractive index contrastPhotonicsWavelengthAsymmetryFree spectral rangeGuided-mode resonanceDiffraction gratingFabricationPhysicsMedicinePathologyAlternative medicineQuantum mechanicsPhotonic and Optical DevicesOptical Coatings and GratingsPhotonic Crystals and Applications
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