Sub-diffraction positioning of a two-photon excited and optically trapped quantum dot

L. Jauffred; A. Kyrsting; Eva Arnspang Christensen; S. N. S. Reihani; L. B. Oddershede

doi:10.1039/c4nr01319k

Sub-diffraction positioning of a two-photon excited and optically trapped quantum dot

L. Jauffred, A. Kyrsting, Eva Arnspang Christensen, S. N. S. Reihani, L. B. Oddershede

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

Abstrakt

Colloidal quantum dots are luminescent long-lived probes that can be two-photon excited and manipulated by a single laser beam. Therefore, quantum dots can be used for simultaneous single molecule visualization and force manipulation using an infra-red laser. Here, we show that even a single optically trapped quantum dot, performing restricted Brownian motion within the focal volume, can be two-photon excited by the trapping laser beam and its luminescence can be detected by a camera. After two-photon excitation for a time long enough, the emitted light from the quantum dot is shown to blueshift. A quantum dot is much smaller than a diffraction limited laser focus and by mapping out the intensity of the focal volume and overlaying this with the positions visited by a quantum dot, a quantum dot is shown often to explore regions of the focal volume where the intensity is too low to render two-photon absorption likely. This is in accordance with the observation that a trapped quantum dot is only fluorescing 5-10 percent of the time. The results are important for realizing nano-scale quantum dot control and visualization and for correct interpretation of experiments using two-photon excited quantum dots as markers.

Originalsprog	Engelsk
Tidsskrift	Nanoscale
Vol/bind	6
Udgave nummer	12
Sider (fra-til)	6997-7003
ISSN	2040-3364
DOI	https://doi.org/10.1039/c4nr01319k
Status	Udgivet - 2014

Bibliografisk note

ISI Document Delivery No.: AI8FI Times Cited: 0 Cited Reference Count: 38 Jauffred, Liselotte Kyrsting, Anders Arnspang, Eva C. Reihani, S. Nader S. Oddershede, Lene B. Carlsberg Foundation; Lundbeck Foundation; University of Copenhagen Excellence Program We thank C. B. Lagerholm and MEMPHYS for lending us the QuadView image splitter and H. Ma for experimental assistance. We acknowledge financial support from the Carlsberg Foundation, the Lundbeck Foundation, and from the University of Copenhagen Excellence Program. 0 ROYAL SOC CHEMISTRY CAMBRIDGE NANOSCALE

Emneord

DIELECTRIC INTERFACE ELECTRIC-DIPOLES LIGHT-EMISSION NANOPARTICLES ORIENTATION TWEEZERS TRACKING CELLS

Dokumenter og links

10.1039/c4nr01319k

Citationsformater

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abstract = "Colloidal quantum dots are luminescent long-lived probes that can be two-photon excited and manipulated by a single laser beam. Therefore, quantum dots can be used for simultaneous single molecule visualization and force manipulation using an infra-red laser. Here, we show that even a single optically trapped quantum dot, performing restricted Brownian motion within the focal volume, can be two-photon excited by the trapping laser beam and its luminescence can be detected by a camera. After two-photon excitation for a time long enough, the emitted light from the quantum dot is shown to blueshift. A quantum dot is much smaller than a diffraction limited laser focus and by mapping out the intensity of the focal volume and overlaying this with the positions visited by a quantum dot, a quantum dot is shown often to explore regions of the focal volume where the intensity is too low to render two-photon absorption likely. This is in accordance with the observation that a trapped quantum dot is only fluorescing 5-10 percent of the time. The results are important for realizing nano-scale quantum dot control and visualization and for correct interpretation of experiments using two-photon excited quantum dots as markers.",

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AU - Jauffred, L.

AU - Kyrsting, A.

AU - Christensen, Eva Arnspang

AU - Reihani, S. N. S.

AU - Oddershede, L. B.

N1 - ISI Document Delivery No.: AI8FI Times Cited: 0 Cited Reference Count: 38 Jauffred, Liselotte Kyrsting, Anders Arnspang, Eva C. Reihani, S. Nader S. Oddershede, Lene B. Carlsberg Foundation; Lundbeck Foundation; University of Copenhagen Excellence Program We thank C. B. Lagerholm and MEMPHYS for lending us the QuadView image splitter and H. Ma for experimental assistance. We acknowledge financial support from the Carlsberg Foundation, the Lundbeck Foundation, and from the University of Copenhagen Excellence Program. 0 ROYAL SOC CHEMISTRY CAMBRIDGE NANOSCALE

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N2 - Colloidal quantum dots are luminescent long-lived probes that can be two-photon excited and manipulated by a single laser beam. Therefore, quantum dots can be used for simultaneous single molecule visualization and force manipulation using an infra-red laser. Here, we show that even a single optically trapped quantum dot, performing restricted Brownian motion within the focal volume, can be two-photon excited by the trapping laser beam and its luminescence can be detected by a camera. After two-photon excitation for a time long enough, the emitted light from the quantum dot is shown to blueshift. A quantum dot is much smaller than a diffraction limited laser focus and by mapping out the intensity of the focal volume and overlaying this with the positions visited by a quantum dot, a quantum dot is shown often to explore regions of the focal volume where the intensity is too low to render two-photon absorption likely. This is in accordance with the observation that a trapped quantum dot is only fluorescing 5-10 percent of the time. The results are important for realizing nano-scale quantum dot control and visualization and for correct interpretation of experiments using two-photon excited quantum dots as markers.

AB - Colloidal quantum dots are luminescent long-lived probes that can be two-photon excited and manipulated by a single laser beam. Therefore, quantum dots can be used for simultaneous single molecule visualization and force manipulation using an infra-red laser. Here, we show that even a single optically trapped quantum dot, performing restricted Brownian motion within the focal volume, can be two-photon excited by the trapping laser beam and its luminescence can be detected by a camera. After two-photon excitation for a time long enough, the emitted light from the quantum dot is shown to blueshift. A quantum dot is much smaller than a diffraction limited laser focus and by mapping out the intensity of the focal volume and overlaying this with the positions visited by a quantum dot, a quantum dot is shown often to explore regions of the focal volume where the intensity is too low to render two-photon absorption likely. This is in accordance with the observation that a trapped quantum dot is only fluorescing 5-10 percent of the time. The results are important for realizing nano-scale quantum dot control and visualization and for correct interpretation of experiments using two-photon excited quantum dots as markers.

KW - DIELECTRIC INTERFACE ELECTRIC-DIPOLES LIGHT-EMISSION NANOPARTICLES ORIENTATION TWEEZERS TRACKING CELLS

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