Rotation of Single-Molecule Emission Polarization by Plasmonic Nanorods

The strong light–matter interactions between dyes and plasmonic nanoantennas enable the study of fundamental molecular-optical processes. Here, we overcome conventional limitations with high-throughput single-molecule polarization-resolved microscopy to measure dye emission polarization modification...

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Veröffentlicht in:	The journal of physical chemistry letters 2019-09, Vol.10 (17), p.5047-5054
Hauptverfasser:	Zuo, Tiancheng, Goldwyn, Harrison J, Isaacoff, Benjamin P, Masiello, David J, Biteen, Julie S
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Sprache:	eng
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container_title	The journal of physical chemistry letters
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creator	Zuo, Tiancheng Goldwyn, Harrison J Isaacoff, Benjamin P Masiello, David J Biteen, Julie S
description	The strong light–matter interactions between dyes and plasmonic nanoantennas enable the study of fundamental molecular-optical processes. Here, we overcome conventional limitations with high-throughput single-molecule polarization-resolved microscopy to measure dye emission polarization modifications upon near-field coupling to a gold nanorod. We determine that the emission polarization distribution is not only rotated toward the nanorod’s dominant localized surface plasmon mode as expected, but it is also unintuitively broadened. With a reduced-order analytical model, we elucidate how this distribution broadening depends upon both far-field interference and off-resonant coupling between the molecular dipole and the nanorod transverse plasmon mode. Experiments and modeling reveal that a nearby plasmonic nanoantenna affects dye emission polarization through a multicolor process, even when the orthogonal plasmon modes are separated by approximately 3 times the dye emission line width. Beyond advancing our understanding of plasmon-coupled emission modifications, this work promises to improve high-sensitivity single-molecule fluorescence imaging, biosensing, and spectral engineering.
doi_str_mv	10.1021/acs.jpclett.9b02270
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title	Rotation of Single-Molecule Emission Polarization by Plasmonic Nanorods
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