Issue 40, 2024

Photoluminescence modal splitting via strong coupling in hybrid Au/WS2/GaP nanoparticle-on-mirror cavities

Abstract

By integrating dielectric and metallic components, hybrid nanophotonic devices present promising opportunities for manipulating nanoscale light–matter interactions. Here, we investigate hybrid nanoparticle-on-mirror optical cavities, where semiconductor WS2 monolayers are positioned between gallium phosphide (GaP) nanoantennas and a gold mirror, thereby establishing extreme confinement of optical fields. Prior to integration of the mirror, we observe an intermediate coupling regime from GaP nanoantennas covered with WS2 monolayers. Upon introduction of the mirror, enhanced interactions lead to modal splitting in the exciton photoluminescence spectra, spatially localized within the dielectric-metallic gap. Using a coupled harmonic oscillator model, we extract an average Rabi splitting energy of 22.6 meV at room temperature, at the onset of the strong coupling regime. Moreover, the characteristics of polaritonic emission are revealed by the increasing Lorentzian linewidth and energy blueshift with increasing excitation power. Our findings highlight hybrid nanophotonic structures as novel platforms for controlling light–matter coupling with atomically thin materials.

Graphical abstract: Photoluminescence modal splitting via strong coupling in hybrid Au/WS2/GaP nanoparticle-on-mirror cavities

Supplementary files

Article information

Article type
Paper
Submitted
01 avq 2024
Accepted
17 sen 2024
First published
18 sen 2024
This article is Open Access
Creative Commons BY license

Nanoscale, 2024,16, 18843-18851

Photoluminescence modal splitting via strong coupling in hybrid Au/WS2/GaP nanoparticle-on-mirror cavities

M. Gülmüs, T. Possmayer, B. Tilmann, P. Butler, I. D. Sharp, L. D. S. Menezes, S. A. Maier and L. Sortino, Nanoscale, 2024, 16, 18843 DOI: 10.1039/D4NR03166K

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