# Hybridization-induced resonances with high quality factor in a plasmonic   concentric ring-disk nanocavity

**Authors:** Zhaojian Zhang, Junbo Yang, Heng Xu, Siyu Xu, Yunxin Han, Xin He,, Jingjing Zhang, Jie Huang, Dingbo Chen

arXiv: 1904.09437 · 2020-03-20

## TL;DR

This paper proposes a novel plasmonic nanocavity design that achieves ultra-high Q factors and narrow resonance linewidths through hybridization effects, enabling advanced on-chip sensing and photonic applications.

## Contribution

It introduces a new concentric ring-disk plasmonic resonator with hybridization-induced high Q factors and ultra-narrow linewidths, surpassing traditional limitations of plasmonic resonators.

## Key findings

- Q factor exceeds 400
- FWHM nearly 1 nm
- Enhanced refractive index sensing performance

## Abstract

Plasmonic resonators have drawn more attention due to the ability to confine light into subwavelength scale. However, they always suffer from a low quality (Q) factor owing to the intrinsic loss of metal. Here, we numerically propose a plasmonic resonator with ultra-high Q factor based on plasmonic metal-insulator-metal (MIM) waveguide structures. The resonator consists of a disk cavity surrounded by a concentric ring cavity, possessing an ultra-small volume. Arising from the plasmon hybridization between plasmon modes in the disk and ring cavity, the induced bonding hybridized modes have ultra-narrow full wave at half maximum (FWHM) as well as ultra-high Q factors. The FWHM can be nearly 1 nm and Q factor can be more than 400. Furthermore, such device can act as a refractive index sensor with ultra-high figure of merit (FOM). This work provides a novel approach to design plasmonic high-Q-factor resonators, and has potential on-chip applications such as filters, sensors and nanolasers.

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Source: https://tomesphere.com/paper/1904.09437