Full-Control and Switching of Optical Fano Resonance by Continuum State Engineering

Fano resonance, known for its unique asymmetric line shape, has gained significant attention in photonics, particularly in sensing applications. However, it remains difficult to achieve controllable Fano parameters with a simple geometric structure. Here, a novel approach of using a thin-film optical Fano resonator with a porous layer to generate entire spectral shapes from quasi-Lorentzian to Lorentzian to Fano is proposed and experimentally demonstrated. The glancing angle deposition technique is utilized to create a polarization-dependent Fano resonator. By altering the linear polarization between s- and p-polarization, a switchable Fano device between quasi-Lorentz state and negative Fano state is demonstrated. This change in spectral shape is advantageous for detecting materials with a low-refractive index. A bio-particle sensing experiment is conducted that demonstrates an enhanced signal-to-noise ratio and prediction accuracy. Finally, the challenge of optimizing the film-based Fano resonator due to intricate interplay among numerous parameters, including layer thicknesses, porosity, and materials selection, is addressed. The inverse design tool is developed based on a multilayer perceptron model that allows fast computation for all ranges of Fano parameters. The method provides improved accuracy of the mean validation factor (MVF = 0.07, q-q') compared to the conventional exhaustive enumeration method (MVF = 0.37). An optical Fano resonator with a porous layer allows for full control of spectral shapes from quasi-Lorentzian to Lorentzian to Fano. The resonator exhibits switchable behavior between quasi-Lorentz and negative Fano states through polarization changes. Enhanced bio-particle sensing capabilities are demonstrated, and an inverse design tool based on a multilayer perceptron model is developed to optimize Fano parameters efficiently.image

Automated summary

A novel approach of using a thin-film optical Fano resonator with a porous layer allows for controllable Fano parameters and adjustable spectral shapes. By manipulating the polarization, the Fano device exhibits switchable behavior between quasi-Lorentzian and negative Fano states. Enhanced bio-particle sensing capabilities are demonstrated and an inverse design tool based on a multilayer perceptron model is developed for efficient optimization.