Author
Listed:
- Liang Su
(KU Leuven)
- Gang Lu
(KU Leuven)
- Bart Kenens
(KU Leuven)
- Susana Rocha
(KU Leuven)
- Eduard Fron
(KU Leuven)
- Haifeng Yuan
(KU Leuven)
- Chang Chen
(IMEC
KU Leuven)
- Pol Van Dorpe
(IMEC
KU Leuven)
- Maarten B. J. Roeffaers
(KU Leuven, Center for Surface Chemistry and Catalysis)
- Hideaki Mizuno
(KU Leuven)
- Johan Hofkens
(KU Leuven
University of Copenhagen)
- James A. Hutchison
(ISIS & icFRC, Université de Strasbourg & CNRS UMR 7006
School of Chemistry and Bio21 Institute, University of Melbourne)
- Hiroshi Uji-i
(KU Leuven
PRESTO, Japan Science and Technology Agency (JST))
Abstract
The enhancement of molecular absorption, emission and scattering processes by coupling to surface plasmon polaritons on metallic nanoparticles is a key issue in plasmonics for applications in (bio)chemical sensing, light harvesting and photocatalysis. Nevertheless, the point spread functions for single-molecule emission near metallic nanoparticles remain difficult to characterize due to fluorophore photodegradation, background emission and scattering from the plasmonic structure. Here we overcome this problem by exciting fluorophores remotely using plasmons propagating along metallic nanowires. The experiments reveal a complex array of single-molecule fluorescence point spread functions that depend not only on nanowire dimensions but also on the position and orientation of the molecular transition dipole. This work has consequences for both single-molecule regime-sensing and super-resolution imaging involving metallic nanoparticles and opens the possibilities for fast size sorting of metallic nanoparticles, and for predicting molecular orientation and binding position on metallic nanoparticles via far-field optical imaging.
Suggested Citation
Liang Su & Gang Lu & Bart Kenens & Susana Rocha & Eduard Fron & Haifeng Yuan & Chang Chen & Pol Van Dorpe & Maarten B. J. Roeffaers & Hideaki Mizuno & Johan Hofkens & James A. Hutchison & Hiroshi Uji-, 2015.
"Visualization of molecular fluorescence point spread functions via remote excitation switching fluorescence microscopy,"
Nature Communications, Nature, vol. 6(1), pages 1-9, May.
Handle:
RePEc:nat:natcom:v:6:y:2015:i:1:d:10.1038_ncomms7287
DOI: 10.1038/ncomms7287
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