Controlling plexcitonic strong coupling via multidimensional hotspot nanoengineering

TL;DR

This paper introduces a novel multidimensional nanoengineering strategy for plasmonic nanocavities that significantly enhances hotspot fields and enables controlled strong coupling at the nanoscale, with broad implications for quantum technologies.

Contribution

It proposes a new design approach for nanocavity hotspots using substrate selection and gold bowtie nanoantennas, achieving a 1.6-fold field enhancement and top-gap hotspot elevation.

Findings

Achieved ~500-fold field enhancement in nanocavity hotspots.

Demonstrated substrate-dependent formation of antenna modes.

Revealed ultrafast quantum dynamics influenced by geometry and substrate.

Abstract

Plexcitonic strong coupling has ushered in an era of room-temperature quantum electrodynamics that is achievable at the nanoscale, with potential applications ranging from high-precision single-molecule spectroscopy to quantum technologies functional under ambient conditions. Realizing these applications on an industrial scale requires scalable and mass-producible plasmonic cavities that provide ease of access and control for quantum emitters. Via a rational selection of substrates and the canonical gold bowtie nanoantenna, we propose a novel design strategy for multidimensional engineering of nanocavity antenna-mode hotspots, which facilitates their elevation to the top of the nanobowtie gap and provides a field enhancement of ~500 fold (a 1.6-fold increase compared to a conventional nanobowtie-on-glass cavity at the bottom of the nanobowtie gap). We discuss the formation mechanism for such antenna modes using different material substrates from the perspective of charge carrier motion, and analyze their sensitivity to the geometrical parameters of the device. The advantages of these antenna modes, particularly in view of their dominantly in-plane polarized near-fields, are further elaborated in a spatiotemporal study of plexcitonic strong coupling involving single emitters and layered ensembles thereof, which reveals ultrafast quantum dynamics dependent on both the substrate and nanobowtie geometry, as well as the potential for applications related to 2D materials whose excitonic dipoles are typically oriented in-plane. The conceptual discovery of this substrate-enabled antenna-mode nanoengineering could readily be extended to tailor hotspots in other plasmonic platforms, and we anticipate that this work could inspire a wide range of novel research directions from photoluminescence spectroscopy and sensing to the design of quantum logic gates and systems for long-range energy transfer.