Optical investigation of nuclear spin coherence in Tm:YAG

A. Louchet; Y. Le Du; T. Brouri; F. Bretenaker; T. Chanelière; F. Goldfarb; I. Lorgeré; J. L. Le Gouët

doi:10.1016/j.solidstatesciences.2007.12.029

Optical investigation of nuclear spin coherence in Tm:YAG

A. Louchet
, Y. Le Du
, T. Brouri
, F. Bretenaker
, T. Chanelière
, F. Goldfarb
, I. Lorgeré
, J. L. Le Gouët

Laboratoire Aimé Cotton

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

Abstract

With all-optical means, the nuclear spin coherence lifetime is measured for the first time in a crystal doped with low-concentration thulium. A novel Raman echo scheme is demonstrated. The hyperfine splitting is varied over a 15 MHz-wide range with the help of an external magnetic field. Over this range the spin coherence lifetime remains close to 350 μs in the electronic ground state. Thulium-doped materials are proved to be interesting substitutes to other rare earth ion-doped crystals as quantum memory candidates, thanks to their convenient wavelength, their adjustable three-level system and their stable and long spin coherence lifetime.

Original language	English
Pages (from-to)	1374-1378
Number of pages	5
Journal	Solid State Sciences
Volume	10
Issue number	10
DOIs	https://doi.org/10.1016/j.solidstatesciences.2007.12.029
Publication status	Published - 1 Jan 2008
Externally published	Yes

Keywords

Heterodyne detection
Quantum memory
Raman echo
Rare earth ions

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10.1016/j.solidstatesciences.2007.12.029

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title = "Optical investigation of nuclear spin coherence in Tm:YAG",

abstract = "With all-optical means, the nuclear spin coherence lifetime is measured for the first time in a crystal doped with low-concentration thulium. A novel Raman echo scheme is demonstrated. The hyperfine splitting is varied over a 15 MHz-wide range with the help of an external magnetic field. Over this range the spin coherence lifetime remains close to 350 μs in the electronic ground state. Thulium-doped materials are proved to be interesting substitutes to other rare earth ion-doped crystals as quantum memory candidates, thanks to their convenient wavelength, their adjustable three-level system and their stable and long spin coherence lifetime.",

keywords = "Heterodyne detection, Quantum memory, Raman echo, Rare earth ions",

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AU - Louchet, A.

AU - Le Du, Y.

AU - Brouri, T.

AU - Bretenaker, F.

AU - Chanelière, T.

AU - Goldfarb, F.

AU - Lorgeré, I.

AU - Le Gouët, J. L.

PY - 2008/1/1

Y1 - 2008/1/1

N2 - With all-optical means, the nuclear spin coherence lifetime is measured for the first time in a crystal doped with low-concentration thulium. A novel Raman echo scheme is demonstrated. The hyperfine splitting is varied over a 15 MHz-wide range with the help of an external magnetic field. Over this range the spin coherence lifetime remains close to 350 μs in the electronic ground state. Thulium-doped materials are proved to be interesting substitutes to other rare earth ion-doped crystals as quantum memory candidates, thanks to their convenient wavelength, their adjustable three-level system and their stable and long spin coherence lifetime.

AB - With all-optical means, the nuclear spin coherence lifetime is measured for the first time in a crystal doped with low-concentration thulium. A novel Raman echo scheme is demonstrated. The hyperfine splitting is varied over a 15 MHz-wide range with the help of an external magnetic field. Over this range the spin coherence lifetime remains close to 350 μs in the electronic ground state. Thulium-doped materials are proved to be interesting substitutes to other rare earth ion-doped crystals as quantum memory candidates, thanks to their convenient wavelength, their adjustable three-level system and their stable and long spin coherence lifetime.

KW - Heterodyne detection

KW - Quantum memory

KW - Raman echo

KW - Rare earth ions

UR - https://www.scopus.com/pages/publications/53349175611

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DO - 10.1016/j.solidstatesciences.2007.12.029

M3 - Article

AN - SCOPUS:53349175611

SN - 1293-2558

VL - 10

SP - 1374

EP - 1378

JO - Solid State Sciences

JF - Solid State Sciences

IS - 10

ER -

Optical investigation of nuclear spin coherence in Tm:YAG

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Keywords

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