# Controlling Fano resonance using the Geometrical Phase of light in   spatially tailored waveguided plasmonic crystals

**Authors:** Subir K. Ray, Ankit K. Singh, Ajmal, Shubham Chandel, Partha Mitra,, Nirmalya Ghosh

arXiv: 1905.01636 · 2019-09-11

## TL;DR

This paper demonstrates how the geometric phase of polarized light can be used to control the spectral asymmetry of Fano resonance in a spatially tailored waveguided plasmonic crystal, enabling new polarization-based photonic applications.

## Contribution

It introduces a method to manipulate Fano resonance line shape via geometric phase control in a specially designed plasmonic crystal, linking phase and spectral asymmetry.

## Key findings

- Controlled Fano resonance spectral asymmetry through geometric phase manipulation.
- Experimental validation using a waveguided plasmonic crystal with spatially varying orientation.
- Theoretical model connecting geometric phase changes to the Fano q-parameter.

## Abstract

Fano resonance exhibiting an asymmetric spectral line shape is a universal phenomenon observed in diverse physical systems. Here we experimentally establish a direct link between the spectral asymmetry parameter and a physically realizable phase factor of interference between a continuum and a discrete mode that leads to Fano resonance. Using a specially designed metamaterial, namely waveguided plasmonic crystal with a spatially varying orientation axis of plasmonic grating, we demonstrate control on the spectral asymmetry of the Fano resonance through changes in the geometric phase of polarized light. In this scenario, the changes in the geometric phase for input left, and right circular polarized light arises due to varying orientation angle of the grating axis. The systematic changes in the geometric phase and the resulting q-parameter of Fano resonance is interpreted by an appropriate theoretical model connecting the two physical entities. The demonstrated control over the spectral line shape of Fano resonance achieved by tailoring geometric phase may open up novel routes for polarization-based photonic applications.

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Source: https://tomesphere.com/paper/1905.01636