Design Optimized CMOS Compatible Hybrid Silicon MIM Waveguide Cavity for Label Free Sensing

TL;DR

This paper presents a numerically optimized hybrid silicon MIM waveguide cavity sensor with high sensitivity and figure of merit, suitable for label-free biochemical and medical diagnostics.

Contribution

It introduces a genetic algorithm-based optimization of a hybrid plasmonic dielectric biosensor for enhanced sensitivity and performance.

Findings

Sensitivity of 1276 nm/RIU achieved

FWHM of 11.89 nm and Q factor of 221

Figure of merit of 107 RIU^-1

Abstract

We numerically design a hybrid plasmonic dielectric refractive index biosensor comprising ametal insulator metal (MIM) bus waveguide evanescently coupled to a silicon core resonator. The geometry is optimized with a genetic algorithm (GA) using Ansys Lumerical FDTD simulations, targeting maximal sensitivity and figure of merit while minimizing the resonance linewidth. The optimized device achieves a sensitivity of 1276 nm/RIU, a full width at half maximum (FWHM) of 11.89nm, a quality factor of 221, and a figure of merit of 107 RIU1 (defined as S/FWHM). These results demonstrate precise discrimination of small refractive index variations and support the sensors applicability to label free biochemical and medical diagnostics.