Plasmon-exciton hybridization in ZnO quantum-well Al nanodisc heterostructures

B. J. Lawrie; K. W. Kim; D. P. Norton; R. F. Haglund

doi:10.1021/nl3029784

Plasmon-exciton hybridization in ZnO quantum-well Al nanodisc heterostructures

B. J. Lawrie, K. W. Kim, D. P. Norton, R. F. Haglund

Quantum Heterostructures

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74 Scopus citations

Abstract

We demonstrate the formation of a hybridized plasmon-exciton state exhibiting strong exciton-plasmon coupling in ZnO/Zn_0.85Mg _0.15O single quantum wells capped with arrays of Al nanodiscs. Tuning the quantum-well width and the diameter and pitch of the Al nanodisc arrays facilitates a transition from the weak-coupling regime into the strong coupling regime. Finite-difference time-domain simulations substantiate the localization of the plasmonic quadrupole moment within the ZnO quantum-well layer, resulting in a hybridized plasmonexciton state demonstrating a Rabi splitting of roughly 15 meV in heterostructures that exhibit a prominent plasmon quadrupole mode. The significant tunability offered by quantum-well heterostructures like those discussed here provides a flexible system for controlling exciton plasmon coupling in a device-compatible thin-film architecture.

Original language	English
Pages (from-to)	6152-6157
Number of pages	6
Journal	Nano Letters
Volume	12
Issue number	12
DOIs	https://doi.org/10.1021/nl3029784
State	Published - Dec 12 2012

Keywords

Localized surface plasmons
ZnO quantum wells
nanophotonics
strong coupling

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10.1021/nl3029784

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abstract = "We demonstrate the formation of a hybridized plasmon-exciton state exhibiting strong exciton-plasmon coupling in ZnO/Zn0.85Mg 0.15O single quantum wells capped with arrays of Al nanodiscs. Tuning the quantum-well width and the diameter and pitch of the Al nanodisc arrays facilitates a transition from the weak-coupling regime into the strong coupling regime. Finite-difference time-domain simulations substantiate the localization of the plasmonic quadrupole moment within the ZnO quantum-well layer, resulting in a hybridized plasmonexciton state demonstrating a Rabi splitting of roughly 15 meV in heterostructures that exhibit a prominent plasmon quadrupole mode. The significant tunability offered by quantum-well heterostructures like those discussed here provides a flexible system for controlling exciton plasmon coupling in a device-compatible thin-film architecture.",

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T1 - Plasmon-exciton hybridization in ZnO quantum-well Al nanodisc heterostructures

AU - Lawrie, B. J.

AU - Kim, K. W.

AU - Norton, D. P.

AU - Haglund, R. F.

PY - 2012/12/12

Y1 - 2012/12/12

N2 - We demonstrate the formation of a hybridized plasmon-exciton state exhibiting strong exciton-plasmon coupling in ZnO/Zn0.85Mg 0.15O single quantum wells capped with arrays of Al nanodiscs. Tuning the quantum-well width and the diameter and pitch of the Al nanodisc arrays facilitates a transition from the weak-coupling regime into the strong coupling regime. Finite-difference time-domain simulations substantiate the localization of the plasmonic quadrupole moment within the ZnO quantum-well layer, resulting in a hybridized plasmonexciton state demonstrating a Rabi splitting of roughly 15 meV in heterostructures that exhibit a prominent plasmon quadrupole mode. The significant tunability offered by quantum-well heterostructures like those discussed here provides a flexible system for controlling exciton plasmon coupling in a device-compatible thin-film architecture.

AB - We demonstrate the formation of a hybridized plasmon-exciton state exhibiting strong exciton-plasmon coupling in ZnO/Zn0.85Mg 0.15O single quantum wells capped with arrays of Al nanodiscs. Tuning the quantum-well width and the diameter and pitch of the Al nanodisc arrays facilitates a transition from the weak-coupling regime into the strong coupling regime. Finite-difference time-domain simulations substantiate the localization of the plasmonic quadrupole moment within the ZnO quantum-well layer, resulting in a hybridized plasmonexciton state demonstrating a Rabi splitting of roughly 15 meV in heterostructures that exhibit a prominent plasmon quadrupole mode. The significant tunability offered by quantum-well heterostructures like those discussed here provides a flexible system for controlling exciton plasmon coupling in a device-compatible thin-film architecture.

KW - Localized surface plasmons

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KW - nanophotonics

KW - strong coupling

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Plasmon-exciton hybridization in ZnO quantum-well Al nanodisc heterostructures

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Keywords

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