Enhanced Control of Quantum Dot Photoluminescence in Hybrid Assemblies

TL;DR

This paper demonstrates precise DNA-based assembly of quantum dots and plasmonic nanoparticles, enabling controlled studies of their interactions and effects on photoluminescence, revealing new mechanisms for emission rate control.

Contribution

It introduces a high-purity, controllable assembly method for quantum dots and metal nanoparticles, advancing understanding of plasmon-exciton interactions and emission rate manipulation.

Findings

Enhanced steady-state photoluminescence in hybrid assemblies

Emission rate can be increased or decreased by spectral detuning

Control over emission lifetime range exceeds previous capabilities

Abstract

The distance-dependent interaction of an emitter with a plasmonic nanoparticle or surface forms the basis of the field of plexitonics. Semiconductor quantum dots (QDs) are robust emitters due to their photostability, and offer the possibility of understanding the fundamental photophysics between one emitter and one metal nanoparticle. A key enabling challenge is the formation of systems containing both QDs and plasmonic nanoparticles in high purity. We present the translation of DNA-based self-assembly techniques to assemble metal and semiconductor nanocrystals into discrete hybrid structures, including dimers, of high purity. This method gives control over the interparticle separation, geometry, and ratio of QD:metal nanoparticle, as well as the spectral properties of the metal/QD components in the assembly to allow investigation of plasmon-exciton interaction. The hybrid assemblies show the expected enhancement in steady-state photoluminescence accompanied by an increase in the QD emission rate for assemblies with a strong overlap between the QD emission and localised surface plasmon resonance. In contrast, lengthening of the QD emission lifetime (a reduction of the emission rate) of up to 1.7-fold, along with an enhancement in steady-state PL of 15-75% is observed upon detuning of the QD and metal nanoparticle spectral properties. This understood in terms of the Purcell effect, where the gold nanoparticle acts as a damped, nanoscale cavity. Considering the metal nanoparticle using generalised nonlocal optical response theory (GNOR) and the QD as an open quantum system, the response is driven by the interference experienced by the emitter for parallel and perpendicular field orientations. This provides a mechanism for control of the emission rate of a QD by a metal nanoparticle across a much wider range of lifetimes than previously understood.