Deterministic quantum teleportation between distant atomic objects

Hanna Westergaard Krauter; Daniel Salart Subils; C.A. Muschik; Jonas Meyer Petersen; Heng Shen; Thomas Fernholz; Eugene Simon Polzik

doi:10.1038/nphys2631

Deterministic quantum teleportation between distant atomic objects

Hanna Westergaard Krauter, Daniel Salart Subils, C.A. Muschik, Jonas Meyer Petersen, Heng Shen, Thomas Fernholz, Eugene Simon Polzik

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105 Citationer (Scopus)

Abstract

Quantum teleportation is a key ingredient in quantum networks and one of the building blocks for quantum computation. Teleportation between distant material objects using light at the quantum-information carrier has been a particularly exciting goal. Here we propose and demonstrat. The deterministic continuous-variable teleportation between distant material objects. The objects are macroscopic atomic ensembles at room temperature. Entanglement required for teleportation is distributed by light propagating from one ensemble to the other. We demonstrate tha. The experimental fidelity of the quantum teleportation is higher than that achievable by any classical process. Furthermore, we demonstrat. The benefits of deterministic teleportation by teleporting a sequence of spin states evolving in time from one distant object onto another. The teleportation protocol is applicable to other important systems, such as mechanical oscillators coupled to light or cold spin ensembles coupled to microwaves.

Originalsprog	Engelsk
Tidsskrift	Nature Physics
Vol/bind	9
Udgave nummer	7
Sider (fra-til)	400-404
ISSN	1745-2473
DOI	https://doi.org/10.1038/nphys2631
Status	Udgivet - 1 jul. 2013

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10.1038/nphys2631

Citationsformater

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title = "Deterministic quantum teleportation between distant atomic objects",

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AU - Krauter, Hanna Westergaard

AU - Salart Subils, Daniel

AU - Muschik, C.A.

AU - Petersen, Jonas Meyer

AU - Shen, Heng

AU - Fernholz, Thomas

AU - Polzik, Eugene Simon

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N2 - Quantum teleportation is a key ingredient in quantum networks and one of the building blocks for quantum computation. Teleportation between distant material objects using light at the quantum-information carrier has been a particularly exciting goal. Here we propose and demonstrat. The deterministic continuous-variable teleportation between distant material objects. The objects are macroscopic atomic ensembles at room temperature. Entanglement required for teleportation is distributed by light propagating from one ensemble to the other. We demonstrate tha. The experimental fidelity of the quantum teleportation is higher than that achievable by any classical process. Furthermore, we demonstrat. The benefits of deterministic teleportation by teleporting a sequence of spin states evolving in time from one distant object onto another. The teleportation protocol is applicable to other important systems, such as mechanical oscillators coupled to light or cold spin ensembles coupled to microwaves.

AB - Quantum teleportation is a key ingredient in quantum networks and one of the building blocks for quantum computation. Teleportation between distant material objects using light at the quantum-information carrier has been a particularly exciting goal. Here we propose and demonstrat. The deterministic continuous-variable teleportation between distant material objects. The objects are macroscopic atomic ensembles at room temperature. Entanglement required for teleportation is distributed by light propagating from one ensemble to the other. We demonstrate tha. The experimental fidelity of the quantum teleportation is higher than that achievable by any classical process. Furthermore, we demonstrat. The benefits of deterministic teleportation by teleporting a sequence of spin states evolving in time from one distant object onto another. The teleportation protocol is applicable to other important systems, such as mechanical oscillators coupled to light or cold spin ensembles coupled to microwaves.

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Deterministic quantum teleportation between distant atomic objects

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