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Probing the Mechanisms of Strong Fluorescence Enhancement in Plasmonic Nanogaps with Sub-nanometer Precision

Boxiang Song, Zhihao Jiang, Zerui Liu, Yunxiang Wang, Fanxin Liu, Stephen B. Cronin, Hao Yang, Deming Meng, Buyun Chen, Pan Hu, Adam Schwartzberg, Stefano Cabrini, Stephan Haas, Wei Wu

2020ACS Nano63 citationsDOI

Abstract

Plasmon-enhanced fluorescence is demonstrated in the vicinity of metal surfaces due to strong local field enhancement. Meanwhile, fluorescence quenching is observed as the spacing between fluorophore molecules and the adjacent metal is reduced below a threshold of a few nanometers. Here, we introduce a technology, placing the fluorophore molecules in plasmonic hotspots between pairs of collapsible nanofingers with tunable gap sizes at sub-nanometer precision. Optimal gap sizes with maximum plasmon enhanced fluorescence are experimentally identified for different dielectric spacer materials. The ultrastrong local field enhancement enables simultaneous detection and characterization of sharp Raman fingerprints in the fluorescence spectra. This platform thus enables in situ monitoring of competing excitation enhancement and emission quenching processes. We systematically investigate the mechanisms behind fluorescence quenching. A quantum mechanical model is developed which explains the experimental data and will guide the future design of plasmon enhanced spectroscopy applications.

Topics & Concepts

PlasmonFluorophoreMaterials scienceFluorescenceRaman spectroscopyQuenching (fluorescence)OptoelectronicsFluorescence in the life sciencesFluorescence spectroscopyExcitationNanotechnologyOpticsPhysicsQuantum mechanicsGold and Silver Nanoparticles Synthesis and ApplicationsPlasmonic and Surface Plasmon ResearchAdvanced biosensing and bioanalysis techniques
Probing the Mechanisms of Strong Fluorescence Enhancement in Plasmonic Nanogaps with Sub-nanometer Precision | Litcius