Control of Quantum Dot Emission by Colloidal Plasmonic Pyramids in a Liquid Crystal

Jao Van De Lagemaat; Haridas Mundoor; Enid Cruz-Colon; Sungoh Park; Qingkun Liu; Ivan Smalyukh

doi:10.1364/OE.383672

Control of Quantum Dot Emission by Colloidal Plasmonic Pyramids in a Liquid Crystal

Jao Van De Lagemaat
, Haridas Mundoor
, Enid Cruz-Colon
, Sungoh Park
, Qingkun Liu
, Ivan Smalyukh

Chemistry and Nanoscience

University of Colorado Boulder

Research output: Contribution to journal › Article › peer-review

3 Scopus Citations

Abstract

We study the plasmon-enhanced fluorescence of a single semiconducting quantum dot near the apex of a colloidal gold pyramid spatially localized by the elastic forces of the liquid crystal host. The gold pyramid particles were manipulated within the liquid crystal medium by laser tweezers, enabling the self-assembly of a semiconducting quantum dot dispersed in the medium near the apex of the gold pyramid, allowing us to probe the plasmon-exciton interactions. We demonstrate the effect of plasmon coupling on the fluorescence lifetime and the blinking properties of the quantum dot. Our results demonstrate that topological defects around colloidal particles in liquid crystal combined with laser tweezers provide a platform for plasmon exciton interaction studies and potentially could be extended to the scale of composite materials for nanophotonic applications.

Original language	American English
Pages (from-to)	5459-5469
Number of pages	11
Journal	Optics Express
Volume	28
Issue number	4
DOIs	https://doi.org/10.1364/OE.383672 https://doi.org/10.1364/OE.383672
State	Published - 2020

Bibliographical note

Publisher Copyright:
© 2020 Optical Society of America.

NLR Publication Number

NREL/JA-5900-75469

Keywords

blinking
light emission
plasmonics
quantum dots
solar-photochemistry

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title = "Control of Quantum Dot Emission by Colloidal Plasmonic Pyramids in a Liquid Crystal",

abstract = "We study the plasmon-enhanced fluorescence of a single semiconducting quantum dot near the apex of a colloidal gold pyramid spatially localized by the elastic forces of the liquid crystal host. The gold pyramid particles were manipulated within the liquid crystal medium by laser tweezers, enabling the self-assembly of a semiconducting quantum dot dispersed in the medium near the apex of the gold pyramid, allowing us to probe the plasmon-exciton interactions. We demonstrate the effect of plasmon coupling on the fluorescence lifetime and the blinking properties of the quantum dot. Our results demonstrate that topological defects around colloidal particles in liquid crystal combined with laser tweezers provide a platform for plasmon exciton interaction studies and potentially could be extended to the scale of composite materials for nanophotonic applications.",

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T1 - Control of Quantum Dot Emission by Colloidal Plasmonic Pyramids in a Liquid Crystal

AU - Van De Lagemaat, Jao

AU - Mundoor, Haridas

AU - Cruz-Colon, Enid

AU - Park, Sungoh

AU - Liu, Qingkun

AU - Smalyukh, Ivan

PY - 2020

Y1 - 2020

N2 - We study the plasmon-enhanced fluorescence of a single semiconducting quantum dot near the apex of a colloidal gold pyramid spatially localized by the elastic forces of the liquid crystal host. The gold pyramid particles were manipulated within the liquid crystal medium by laser tweezers, enabling the self-assembly of a semiconducting quantum dot dispersed in the medium near the apex of the gold pyramid, allowing us to probe the plasmon-exciton interactions. We demonstrate the effect of plasmon coupling on the fluorescence lifetime and the blinking properties of the quantum dot. Our results demonstrate that topological defects around colloidal particles in liquid crystal combined with laser tweezers provide a platform for plasmon exciton interaction studies and potentially could be extended to the scale of composite materials for nanophotonic applications.

AB - We study the plasmon-enhanced fluorescence of a single semiconducting quantum dot near the apex of a colloidal gold pyramid spatially localized by the elastic forces of the liquid crystal host. The gold pyramid particles were manipulated within the liquid crystal medium by laser tweezers, enabling the self-assembly of a semiconducting quantum dot dispersed in the medium near the apex of the gold pyramid, allowing us to probe the plasmon-exciton interactions. We demonstrate the effect of plasmon coupling on the fluorescence lifetime and the blinking properties of the quantum dot. Our results demonstrate that topological defects around colloidal particles in liquid crystal combined with laser tweezers provide a platform for plasmon exciton interaction studies and potentially could be extended to the scale of composite materials for nanophotonic applications.

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KW - light emission

KW - plasmonics

KW - quantum dots

KW - solar-photochemistry

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M3 - Article

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AN - SCOPUS:85079343277

SN - 1094-4087

VL - 28

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JO - Optics Express

JF - Optics Express

IS - 4

ER -

Control of Quantum Dot Emission by Colloidal Plasmonic Pyramids in a Liquid Crystal

Abstract

Bibliographical note

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Keywords

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