Tracking the Coupling of Single Emitters to Plasmonic Nanoantennas with Single-Molecule Super-Resolution Imaging

TL;DR

This paper demonstrates how single-molecule super-resolution imaging can be used to study and enhance the coupling of emitters to plasmonic nanoantennas, revealing improved stability and trapping effects.

Contribution

It introduces a method to observe and analyze the trapping dynamics of single emitters in nanocavities using super-resolution imaging, highlighting the effects of resonance on trapping efficiency.

Findings

Molecules in nanogaps show increased photostability and longer tracking.

Resonant antennas enhance optical trapping effects.

Super-resolution imaging enables detailed study of emitter-antenna coupling.

Abstract

Metal nanoantennas enable the manipulation of light emission and detection at the single photon level by confining light into very small volumes. Emitters coupled to these plasmonic structures are thus ideal candidates for usage in quantum information technology. However, controllably and reproducibly placing quantum emitters into nanocavities has been challenging due to the sizes of the systems involved. Here, we investigate the trapping dynamics of single emitters into nanocavities via optical gradient forces by using single-molecule super-resolution imaging and tracking. We show that molecules trapped in the nanogaps of bowtie antennas have increased photostability and track lengths compared to molecules farther away from the structure. For resonant antennas, these effects are magnified compared to the off-resonant case due to stronger optical trapping effects. These results open the way to using plasmonic optical trapping to reliably couple single emitters to single nanoantennas, enabling further studies of these coupled systems.