Plasmon resonances in multilayer Fanoshells

TL;DR

This paper presents a theoretical model for predicting localized surface plasmon resonances in multilayer Fanoshells with symmetry-breaking, validated by simulations, and identifies optimal configurations for sensing applications.

Contribution

The study introduces a multipole, quasi-static theoretical framework for multilayer Fanoshells and systematically analyzes the effects of symmetry-breaking offsets on plasmon resonances.

Findings

Good agreement between theory and electrodynamic simulations.

Offsetting the outer shell optimizes sensing performance.

Symmetry-breaking influences resonance suppression and coupling.

Abstract

We develop a theoretical framework, based on a multipole, quasi-static approach, for the prediction of the localized surface plasmon resonances in Fanoshells formed via geometrical symmetry-breaking in multilayer nanoshells consisting of a metallic core, a dielectric inner shell, and a metallic outer shell. By tuning the core and shell offsets of a gold-silica-gold multilayer nanoshell, we show that the theoretical model is in good agreement with electrodynamic simulations. The dipolar resonances are more suppressed when the core and the outer shell are concurrently offset, and less suppressed when either the core, the inner shell, or the outer shell is offset. We attribute the former to coupling constants arising from dual symmetry-breaking, and the latter to coupling constants due to single symmetry-breaking. Using three performance parameters, we propose the outer shell offset as the optimal Fanoshell for sensing applications. This study systematically investigates all types of offset-based, symmetry-broken, metal-dielectric-metal multilayer nanoshells within the Rayleigh regime.