Propagation and survival of frequency-bin entangled photons in metallic nanostructures

Laurent Olislager; Wakana Kubo; Takuo Tanaka; Simona Ungureanu; Renaud A L Vallée; Branko Kolaric; Philippe Emplit; Serge Massar

doi:10.1515/nanoph-2015-0011

Propagation and survival of frequency-bin entangled photons in metallic nanostructures

Laurent Olislager, Wakana Kubo, Takuo Tanaka, Simona Ungureanu, Renaud A L Vallée, Branko Kolaric, Philippe Emplit, Serge Massar

Résultats de recherche: Contribution à un journal/une revue › Article › Revue par des pairs

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Résumé

We report on the design of two plasmonic nanostructures and the propagation of frequency-bin entangled photons through them. The experimental findings clearly show the robustness of frequency-bin entanglement, which survives after interactions with both a hybrid plasmo-photonic structure, and a nano-pillar array. These results confirm that quantum states can be encoded into the collective motion of a many-body electronic system without demolishing their quantum nature, and pave the way towards applications of plasmonic structures in quantum information.

langue originale	Anglais
Pages (de - à)	324-331
Nombre de pages	8
journal	Nanophotonics
Volume	4
Numéro de publication	1
Les DOIs	https://doi.org/10.1515/nanoph-2015-0011
Etat de la publication	Publié - 1 janv. 2015

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abstract = "We report on the design of two plasmonic nanostructures and the propagation of frequency-bin entangled photons through them. The experimental findings clearly show the robustness of frequency-bin entanglement, which survives after interactions with both a hybrid plasmo-photonic structure, and a nano-pillar array. These results confirm that quantum states can be encoded into the collective motion of a many-body electronic system without demolishing their quantum nature, and pave the way towards applications of plasmonic structures in quantum information.",

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AU - Olislager, Laurent

AU - Kubo, Wakana

AU - Tanaka, Takuo

AU - Ungureanu, Simona

AU - Vallée, Renaud A L

AU - Kolaric, Branko

AU - Emplit, Philippe

AU - Massar, Serge

PY - 2015/1/1

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AB - We report on the design of two plasmonic nanostructures and the propagation of frequency-bin entangled photons through them. The experimental findings clearly show the robustness of frequency-bin entanglement, which survives after interactions with both a hybrid plasmo-photonic structure, and a nano-pillar array. These results confirm that quantum states can be encoded into the collective motion of a many-body electronic system without demolishing their quantum nature, and pave the way towards applications of plasmonic structures in quantum information.

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Propagation and survival of frequency-bin entangled photons in metallic nanostructures

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