Manipulating frequency-bin entangled states in cold atoms

Alessandro Zavatta; Maurizio Artoni; Daniel Viscor; Giuseppe La Rocca

doi:10.1038/srep03941

Manipulating frequency-bin entangled states in cold atoms

Alessandro Zavatta, Maurizio Artoni, Daniel Viscor, Giuseppe La Rocca

Department of Physics

Research output: Contribution to journal › Article › Research › peer-review

8 Citations (Scopus)

Abstract

Optical manipulation of entanglement harnessing the frequency degree of freedom is important for encoding of quantum information. We here devise a phase-resonant excitation mechanism of an atomic interface where full control of a narrowband single-photon two-mode frequency entangled state can be efficiently achieved. We illustrate the working physical mechanism for an interface made of cold 87 Rb atoms where entanglement is well preserved from degradation over a typical 100 μ m length scale of the interface and with fractional delays of the order of unity. The scheme provides a basis for efficient multi-frequency and multi-photon entanglement, which is not easily accessible to polarization and spatial encoding.

Original language	English
Journal	Scientific reports
Volume	4
DOIs	https://doi.org/10.1038/srep03941
Publication status	Published - 2014

Keywords

Atomic and molecular interactions with photons
Quantum optics
Slow light

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10.1038/srep03941

https://ddd.uab.cat/record/184996

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title = "Manipulating frequency-bin entangled states in cold atoms",

abstract = "Optical manipulation of entanglement harnessing the frequency degree of freedom is important for encoding of quantum information. We here devise a phase-resonant excitation mechanism of an atomic interface where full control of a narrowband single-photon two-mode frequency entangled state can be efficiently achieved. We illustrate the working physical mechanism for an interface made of cold 87 Rb atoms where entanglement is well preserved from degradation over a typical 100 μ m length scale of the interface and with fractional delays of the order of unity. The scheme provides a basis for efficient multi-frequency and multi-photon entanglement, which is not easily accessible to polarization and spatial encoding.",

keywords = "Atomic and molecular interactions with photons, Quantum optics, Slow light",

author = "Alessandro Zavatta and Maurizio Artoni and Daniel Viscor and \{La Rocca\}, Giuseppe",

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TY - JOUR

T1 - Manipulating frequency-bin entangled states in cold atoms

AU - Zavatta, Alessandro

AU - Artoni, Maurizio

AU - Viscor, Daniel

AU - La Rocca, Giuseppe

PY - 2014

Y1 - 2014

N2 - Optical manipulation of entanglement harnessing the frequency degree of freedom is important for encoding of quantum information. We here devise a phase-resonant excitation mechanism of an atomic interface where full control of a narrowband single-photon two-mode frequency entangled state can be efficiently achieved. We illustrate the working physical mechanism for an interface made of cold 87 Rb atoms where entanglement is well preserved from degradation over a typical 100 μ m length scale of the interface and with fractional delays of the order of unity. The scheme provides a basis for efficient multi-frequency and multi-photon entanglement, which is not easily accessible to polarization and spatial encoding.

AB - Optical manipulation of entanglement harnessing the frequency degree of freedom is important for encoding of quantum information. We here devise a phase-resonant excitation mechanism of an atomic interface where full control of a narrowband single-photon two-mode frequency entangled state can be efficiently achieved. We illustrate the working physical mechanism for an interface made of cold 87 Rb atoms where entanglement is well preserved from degradation over a typical 100 μ m length scale of the interface and with fractional delays of the order of unity. The scheme provides a basis for efficient multi-frequency and multi-photon entanglement, which is not easily accessible to polarization and spatial encoding.

KW - Atomic and molecular interactions with photons

KW - Quantum optics

KW - Slow light

UR - https://www.scopus.com/pages/publications/84893826052

U2 - 10.1038/srep03941

DO - 10.1038/srep03941

M3 - Article

C2 - 24487523

SN - 2045-2322

VL - 4

JO - Scientific reports

JF - Scientific reports

ER -

Manipulating frequency-bin entangled states in cold atoms

Abstract

Keywords

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