Plasmon resonances have appeared as a promising method to boost the fluorescence intensity of single emitters. However, because research has focused on the enhancement at low excitation intensity, little is known about plasmon–fluorophore coupling near the point where the dye saturates. Here we study plasmon-enhanced fluorescence at a broad range of excitation intensities up to saturation. We adopt a novel DNA-mediated approach wherein dynamic single-molecule binding provides a controlled particle–fluorophore spacing, and dynamic rebinding circumvents artifacts due to photobleaching. We find that near saturation the maximum photon count rate is enhanced by more than 2 orders of magnitude at the optimal particle–fluorophore spacing, even for a dye with a high intrinsic quantum yield. We compare our results to a numerical model taking into account dye saturation. These experiments provide design rules to maximize the photon output of single emitters, which will open the door to studying fast dynamics in real time using single-molecule fluorescence.
Spatially Resolved Sensitivity of Single-Particle Plasmon Sensors Michael A. Beuwer, Bas van Hoof, and Peter Zijlstra DOI:10.1021/acs.jpcc.8b00849 The high sensitivity of localized surface plasmon resonance sensors to the local refractive...
Peter will present the group’s most recent results at the Gordon Research Conference in Hong Kong on Plasmonically Powered Processes! For the conference’s full program see https://www.grc.org/plasmonically-powered-processes-conference/2019/.
Heterogeneous kinetics in the functionalization of single plasmonic nanoparticles Matej Horacek, Rachel E. Armstrong, and Peter Zijlstra DOI: 10.1021/acs.langmuir.7b04027 The functionalization of gold nanoparticles with DNA has been studied extensively in solution, however...