Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters

Research output: Contribution to journalJournal articleResearchpeer-review

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Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters. / Andersen, Mads Lykke; Stobbe, Søren; Sørensen, Anders Søndberg; Lodahl, Peter.

In: Nature Physics, Vol. 7, 19.12.2010, p. 215-218.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Andersen, ML, Stobbe, S, Sørensen, AS & Lodahl, P 2010, 'Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters', Nature Physics, vol. 7, pp. 215-218. https://doi.org/10.1038/nphys1870

APA

Andersen, M. L., Stobbe, S., Sørensen, A. S., & Lodahl, P. (2010). Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters. Nature Physics, 7, 215-218. https://doi.org/10.1038/nphys1870

Vancouver

Andersen ML, Stobbe S, Sørensen AS, Lodahl P. Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters. Nature Physics. 2010 Dec 19;7:215-218. https://doi.org/10.1038/nphys1870

Author

Andersen, Mads Lykke ; Stobbe, Søren ; Sørensen, Anders Søndberg ; Lodahl, Peter. / Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters. In: Nature Physics. 2010 ; Vol. 7. pp. 215-218.

Bibtex

@article{c13215dbb8f84977a5811a1b1a4cc500,
title = "Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters",
abstract = "Semiconductor quantum dots (QDs) provide useful means to couple light and matter in applications such as light-harvesting1, 2 and all-solid-state quantum information processing3, 4. This coupling can be increased by placing QDs in nanostructured optical environments such as photonic crystals or metallic nanostructures that enable strong confinement of light and thereby enhance the light–matter interaction. It has thus far been assumed that QDs can be described in the same way as atomic photon emitters—as point sources with wavefunctions whose spatial extent can be disregarded. Here we demonstrate that this description breaks down for QDs near plasmonic nanostructures. We observe an eightfold enhancement of the plasmon excitation rate, depending on QD orientation as a result of their mesoscopic character. Moreover, we show that the interaction can be enhanced or suppressed, determined by the geometry of the plasmonic nanostructure, consistent with a newly developed theory that takes mesoscopic effects into account. This behaviour has no equivalence in atomic systems and offers new opportunities to exploit the unique mesoscopic characteristics of QDs in the development of nanophotonic devices that use the increased light–matter interaction. ",
author = "Andersen, {Mads Lykke} and S{\o}ren Stobbe and S{\o}rensen, {Anders S{\o}ndberg} and Peter Lodahl",
year = "2010",
month = dec,
day = "19",
doi = "10.1038/nphys1870",
language = "English",
volume = "7",
pages = "215--218",
journal = "Nature Physics",
issn = "1745-2473",
publisher = "nature publishing group",

}

RIS

TY - JOUR

T1 - Strongly modified plasmon-matter inetraction with mesoscopic quantum emitters

AU - Andersen, Mads Lykke

AU - Stobbe, Søren

AU - Sørensen, Anders Søndberg

AU - Lodahl, Peter

PY - 2010/12/19

Y1 - 2010/12/19

N2 - Semiconductor quantum dots (QDs) provide useful means to couple light and matter in applications such as light-harvesting1, 2 and all-solid-state quantum information processing3, 4. This coupling can be increased by placing QDs in nanostructured optical environments such as photonic crystals or metallic nanostructures that enable strong confinement of light and thereby enhance the light–matter interaction. It has thus far been assumed that QDs can be described in the same way as atomic photon emitters—as point sources with wavefunctions whose spatial extent can be disregarded. Here we demonstrate that this description breaks down for QDs near plasmonic nanostructures. We observe an eightfold enhancement of the plasmon excitation rate, depending on QD orientation as a result of their mesoscopic character. Moreover, we show that the interaction can be enhanced or suppressed, determined by the geometry of the plasmonic nanostructure, consistent with a newly developed theory that takes mesoscopic effects into account. This behaviour has no equivalence in atomic systems and offers new opportunities to exploit the unique mesoscopic characteristics of QDs in the development of nanophotonic devices that use the increased light–matter interaction.

AB - Semiconductor quantum dots (QDs) provide useful means to couple light and matter in applications such as light-harvesting1, 2 and all-solid-state quantum information processing3, 4. This coupling can be increased by placing QDs in nanostructured optical environments such as photonic crystals or metallic nanostructures that enable strong confinement of light and thereby enhance the light–matter interaction. It has thus far been assumed that QDs can be described in the same way as atomic photon emitters—as point sources with wavefunctions whose spatial extent can be disregarded. Here we demonstrate that this description breaks down for QDs near plasmonic nanostructures. We observe an eightfold enhancement of the plasmon excitation rate, depending on QD orientation as a result of their mesoscopic character. Moreover, we show that the interaction can be enhanced or suppressed, determined by the geometry of the plasmonic nanostructure, consistent with a newly developed theory that takes mesoscopic effects into account. This behaviour has no equivalence in atomic systems and offers new opportunities to exploit the unique mesoscopic characteristics of QDs in the development of nanophotonic devices that use the increased light–matter interaction.

U2 - 10.1038/nphys1870

DO - 10.1038/nphys1870

M3 - Journal article

VL - 7

SP - 215

EP - 218

JO - Nature Physics

JF - Nature Physics

SN - 1745-2473

ER -

ID: 32900375