Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer

Luke J. Higgins; Cristian A. Marocico; Jorge Garcia Coindreau; Vasilios D. Karanikolas; Alan P. Bell; John J. Gough; Graham P. Murphy; Peter J. Parbrook; A. Louise Bradley

doi:10.1109/ICTON.2017.8024804

Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer

Luke J. Higgins
, Cristian A. Marocico
, Jorge Garcia Coindreau
, Vasilios D. Karanikolas
, Alan P. Bell
, John J. Gough
, Graham P. Murphy
, Peter J. Parbrook
, A. Louise Bradley

Trinity College Dublin

Research output: Chapter in Book/Report/Conference proceedings › Conference proceeding › peer-review

Abstract

The influence of ordered plasmonic arrays on energy transfer from a quantum well to a quantum dot layer has been investigated. The ordered arrays are comprised of nanostructures of different geometries, including boxes, disks and rings. Despite no signature of non-radiative energy transfer in the absence of an array, an efficiency of ∼51% is observed for a ring array, though strong emission quenching yields an overall increase of only ∼ 14% of the QD emission. The QD emission is enhanced by ∼25% for disk arrays, and was found to be relatively insensitive to the gap between disks. In contrast, the QD emission enhancement decreases from ∼70% to 40% as the separation between boxes increases from 100 nm to 160 nm. The largest increase in QD emission of ∼70% is due to a non-radiative energy transfer efficiency of ∼25% coupled with a QD emission enhancement factor of ∼1.4. The results demonstrate the flexibility offered by plasmonic arrays to optimise non-radiative energy transfer or to benefit from a combination of energy transfer and enhanced radiative emission, relevant to sensing and colour conversion applications.

Original language	English
Title of host publication	ICTON 2017 - 19th International Conference on Transparent Optical Networks
Publisher	IEEE Computer Society
ISBN (Electronic)	9781538608586
DOIs	https://doi.org/10.1109/ICTON.2017.8024804
Publication status	Published - 1 Sep 2017
Event	19th International Conference on Transparent Optical Networks, ICTON 2017 - Girona, Catalonia, Spain Duration: 2 Jul 2017 → 6 Jul 2017

Publication series

Name	International Conference on Transparent Optical Networks
ISSN (Electronic)	2162-7339

Conference

Conference	19th International Conference on Transparent Optical Networks, ICTON 2017
Country/Territory	Spain
City	Girona, Catalonia
Period	2/07/17 → 6/07/17

Keywords

down conversion
Förster resonance energy transfer (FRET)
non-radiative energy transfer
plasmonics
quantum dots
quantum well

Access to Document

10.1109/ICTON.2017.8024804

Cite this

Higgins, L. J., Marocico, C. A., Coindreau, J. G., Karanikolas, V. D., Bell, A. P., Gough, J. J., Murphy, G. P., Parbrook, P. J., & Bradley, A. L. (2017). Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer. In ICTON 2017 - 19th International Conference on Transparent Optical Networks Article 8024804 (International Conference on Transparent Optical Networks). IEEE Computer Society. https://doi.org/10.1109/ICTON.2017.8024804

@inproceedings{33f125a1efd345f2be2a381b66b1d02a,

title = "Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer",

abstract = "The influence of ordered plasmonic arrays on energy transfer from a quantum well to a quantum dot layer has been investigated. The ordered arrays are comprised of nanostructures of different geometries, including boxes, disks and rings. Despite no signature of non-radiative energy transfer in the absence of an array, an efficiency of ∼51\% is observed for a ring array, though strong emission quenching yields an overall increase of only ∼ 14\% of the QD emission. The QD emission is enhanced by ∼25\% for disk arrays, and was found to be relatively insensitive to the gap between disks. In contrast, the QD emission enhancement decreases from ∼70\% to 40\% as the separation between boxes increases from 100 nm to 160 nm. The largest increase in QD emission of ∼70\% is due to a non-radiative energy transfer efficiency of ∼25\% coupled with a QD emission enhancement factor of ∼1.4. The results demonstrate the flexibility offered by plasmonic arrays to optimise non-radiative energy transfer or to benefit from a combination of energy transfer and enhanced radiative emission, relevant to sensing and colour conversion applications.",

keywords = "down conversion, F{\"o}rster resonance energy transfer (FRET), non-radiative energy transfer, plasmonics, quantum dots, quantum well",

author = "Higgins, \{Luke J.\} and Marocico, \{Cristian A.\} and Coindreau, \{Jorge Garcia\} and Karanikolas, \{Vasilios D.\} and Bell, \{Alan P.\} and Gough, \{John J.\} and Murphy, \{Graham P.\} and Parbrook, \{Peter J.\} and Bradley, \{A. Louise\}",

note = "Publisher Copyright: {\textcopyright} 2017 IEEE.; 19th International Conference on Transparent Optical Networks, ICTON 2017 ; Conference date: 02-07-2017 Through 06-07-2017",

year = "2017",

month = sep,

day = "1",

doi = "10.1109/ICTON.2017.8024804",

language = "English",

series = "International Conference on Transparent Optical Networks",

publisher = "IEEE Computer Society",

booktitle = "ICTON 2017 - 19th International Conference on Transparent Optical Networks",

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Higgins, LJ, Marocico, CA, Coindreau, JG, Karanikolas, VD, Bell, AP, Gough, JJ, Murphy, GP, Parbrook, PJ & Bradley, AL 2017, Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer. in ICTON 2017 - 19th International Conference on Transparent Optical Networks., 8024804, International Conference on Transparent Optical Networks, IEEE Computer Society, 19th International Conference on Transparent Optical Networks, ICTON 2017, Girona, Catalonia, Spain, 2/07/17. https://doi.org/10.1109/ICTON.2017.8024804

Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer. / Higgins, Luke J.; Marocico, Cristian A.; Coindreau, Jorge Garcia et al.
ICTON 2017 - 19th International Conference on Transparent Optical Networks. IEEE Computer Society, 2017. 8024804 (International Conference on Transparent Optical Networks).

Research output: Chapter in Book/Report/Conference proceedings › Conference proceeding › peer-review

TY - GEN

T1 - Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer

AU - Higgins, Luke J.

AU - Marocico, Cristian A.

AU - Coindreau, Jorge Garcia

AU - Karanikolas, Vasilios D.

AU - Bell, Alan P.

AU - Gough, John J.

AU - Murphy, Graham P.

AU - Parbrook, Peter J.

AU - Bradley, A. Louise

PY - 2017/9/1

Y1 - 2017/9/1

N2 - The influence of ordered plasmonic arrays on energy transfer from a quantum well to a quantum dot layer has been investigated. The ordered arrays are comprised of nanostructures of different geometries, including boxes, disks and rings. Despite no signature of non-radiative energy transfer in the absence of an array, an efficiency of ∼51% is observed for a ring array, though strong emission quenching yields an overall increase of only ∼ 14% of the QD emission. The QD emission is enhanced by ∼25% for disk arrays, and was found to be relatively insensitive to the gap between disks. In contrast, the QD emission enhancement decreases from ∼70% to 40% as the separation between boxes increases from 100 nm to 160 nm. The largest increase in QD emission of ∼70% is due to a non-radiative energy transfer efficiency of ∼25% coupled with a QD emission enhancement factor of ∼1.4. The results demonstrate the flexibility offered by plasmonic arrays to optimise non-radiative energy transfer or to benefit from a combination of energy transfer and enhanced radiative emission, relevant to sensing and colour conversion applications.

AB - The influence of ordered plasmonic arrays on energy transfer from a quantum well to a quantum dot layer has been investigated. The ordered arrays are comprised of nanostructures of different geometries, including boxes, disks and rings. Despite no signature of non-radiative energy transfer in the absence of an array, an efficiency of ∼51% is observed for a ring array, though strong emission quenching yields an overall increase of only ∼ 14% of the QD emission. The QD emission is enhanced by ∼25% for disk arrays, and was found to be relatively insensitive to the gap between disks. In contrast, the QD emission enhancement decreases from ∼70% to 40% as the separation between boxes increases from 100 nm to 160 nm. The largest increase in QD emission of ∼70% is due to a non-radiative energy transfer efficiency of ∼25% coupled with a QD emission enhancement factor of ∼1.4. The results demonstrate the flexibility offered by plasmonic arrays to optimise non-radiative energy transfer or to benefit from a combination of energy transfer and enhanced radiative emission, relevant to sensing and colour conversion applications.

KW - down conversion

KW - Förster resonance energy transfer (FRET)

KW - non-radiative energy transfer

KW - plasmonics

KW - quantum dots

KW - quantum well

UR - https://www.scopus.com/pages/publications/85030982710

U2 - 10.1109/ICTON.2017.8024804

DO - 10.1109/ICTON.2017.8024804

M3 - Conference proceeding

AN - SCOPUS:85030982710

T3 - International Conference on Transparent Optical Networks

BT - ICTON 2017 - 19th International Conference on Transparent Optical Networks

PB - IEEE Computer Society

T2 - 19th International Conference on Transparent Optical Networks, ICTON 2017

Y2 - 2 July 2017 through 6 July 2017

ER -

Higgins LJ, Marocico CA, Coindreau JG, Karanikolas VD, Bell AP, Gough JJ et al. Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer. In ICTON 2017 - 19th International Conference on Transparent Optical Networks. IEEE Computer Society. 2017. 8024804. (International Conference on Transparent Optical Networks). doi: 10.1109/ICTON.2017.8024804

Influence of plasmonic array geometry on non-radiative energy transfer from a quantum well to a quantum dot layer

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