Plasmon blockade in nanostructured graphene
Plasmon blockade in nanostructured graphene
Among the many extraordinary properties of graphene, its optical response allows one to easily tune its interaction with nearby molecules via electrostatic doping. The large confinement displayed by plasmons in graphene nanodisks makes it possible to reach the strong-coupling regime with a nearby quantum emitter, such as a quantum dot or a molecule. In this limit, the quantum emitter can introduce a significant plasmon–plasmon interaction, which gives rise to a plasmon blockade effect. This produces, in turn, strongly nonlinear absorption cross sections and modified statistics of the bosonic plasmon mode. We characterize these phenomena by studying the equal-time second-order correlation function g(2)(0), which plunges below a value of 1, thus revealing the existence of nonclassical plasmon states. The plasmon-emitter coupling, and therefore the plasmon blockade, can be efficiently controlled by tuning the doping level of the graphene nanodisks. The proposed system emerges as a new promising platform to realize quantum plasmonic devices capable of commuting optical signals at the single-photon/plasmon level.
1724-1731
Manjavacas, Alejandro
4be9f6f6-2641-4352-8508-33d99566eacd
Nordlander, Peter
7888b579-5ef3-4e32-bd7a-02d6c29a16bd
García de Abajo, F.Javier
07e3df24-ab3b-4a70-af18-188db066aa1a
6 January 2012
Manjavacas, Alejandro
4be9f6f6-2641-4352-8508-33d99566eacd
Nordlander, Peter
7888b579-5ef3-4e32-bd7a-02d6c29a16bd
García de Abajo, F.Javier
07e3df24-ab3b-4a70-af18-188db066aa1a
Manjavacas, Alejandro, Nordlander, Peter and García de Abajo, F.Javier
(2012)
Plasmon blockade in nanostructured graphene.
ACS Nano, 6 (2), .
(doi:10.1021/nn204701w).
Abstract
Among the many extraordinary properties of graphene, its optical response allows one to easily tune its interaction with nearby molecules via electrostatic doping. The large confinement displayed by plasmons in graphene nanodisks makes it possible to reach the strong-coupling regime with a nearby quantum emitter, such as a quantum dot or a molecule. In this limit, the quantum emitter can introduce a significant plasmon–plasmon interaction, which gives rise to a plasmon blockade effect. This produces, in turn, strongly nonlinear absorption cross sections and modified statistics of the bosonic plasmon mode. We characterize these phenomena by studying the equal-time second-order correlation function g(2)(0), which plunges below a value of 1, thus revealing the existence of nonclassical plasmon states. The plasmon-emitter coupling, and therefore the plasmon blockade, can be efficiently controlled by tuning the doping level of the graphene nanodisks. The proposed system emerges as a new promising platform to realize quantum plasmonic devices capable of commuting optical signals at the single-photon/plasmon level.
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Published date: 6 January 2012
Organisations:
Optoelectronics Research Centre
Identifiers
Local EPrints ID: 337812
URI: http://eprints.soton.ac.uk/id/eprint/337812
ISSN: 1936-0851
PURE UUID: b11c03bf-22d2-4970-a277-a5c52718ad9d
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Date deposited: 03 May 2012 16:21
Last modified: 14 Mar 2024 10:58
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Contributors
Author:
Alejandro Manjavacas
Author:
Peter Nordlander
Author:
F.Javier García de Abajo
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