Universal method for realization of strong light-matter coupling in hierarchical microcavity-plasmon-exciton systems

TL;DR

This paper introduces a universal method to achieve strong light-matter coupling in hierarchical microcavity-plasmon-exciton systems, enabling room-temperature strong coupling with 2D materials and beyond, with Rabi splitting over 500 meV.

Contribution

The authors present a universal scheme for realizing strong and ultra-strong coupling regimes in hybrid systems combining plasmonic, excitonic, and cavity modes.

Findings

Rabi splitting exceeds 500 meV at room temperature

Photoluminescence shows dominant emission from lower polariton branch

Universal scheme enables strong coupling across a wide spectral range

Abstract

Polaritons are compositional light-matter quasiparticles that arise as a result of strong coupling between a vacuum field of a resonant optical cavity and electronic excitations in quantum emitters. Reaching such a regime is often hard, as it requires materials possessing high oscillator strengths to interact with the relevant optical mode. Two dimensional transition metal dichalcogenides (TMDs) have recently emerged as promising candidates for realization of the strong coupling regime at room temperature. However, these materials typically provide coupling strengths in the range of 10-40 meV, which may be insufficient for reaching strong coupling with low quality factor resonators. Here, we demonstrate a universal scheme that allows a straightforward realization of strong and ultra-strong coupling regime with 2D materials and beyond. By intermixing plasmonic excitations in nanoparticle arrays with excitons in a WS2 monolayer inside a resonant metallic microcavity, we fabricate a hierarchical system with the combined Rabi splitting exceeding 500 meV at room temperature. Photoluminescence measurements of the coupled systems show dominant emission from the lower polariton branch, indicating the participation of excitons in the coupling process. Strong coupling has been recently suggested to affect numerous optical- and material-related properties including chemical reactivity, exciton transport and optical nonlinearities. With the universal scheme presented here, strong coupling across a wide spectral range is within easy reach and therefore exploring these exciting phenomena can be further pursued in a much broader class of materials.