Three-dimensional theory of quantum memories based on ¿-type atomic ensembles

Emil Zeuthen; Anna Grodecka-Grad; Anders Søndberg Sørensen

doi:10.1103/PhysRevA.84.043838

Three-dimensional theory of quantum memories based on ¿-type atomic ensembles

Emil Zeuthen, Anna Grodecka-Grad, Anders Søndberg Sørensen

16 Citations (Scopus)

Abstract

We develop a three-dimensional theory for quantum memories based on light storage in ensembles of Λ-type atoms, where two long-lived atomic ground states are employed. We consider light storage in an ensemble of finite spatial extent and we show that within the paraxial approximation the Fresnel number of the atomic ensemble and the optical depth are the only important physical parameters determining the quality of the quantum memory. We analyze the influence of these parameters on the storage of light followed by either forward or backward read-out from the quantum memory. We show that for small Fresnel numbers the forward memory provides higher efficiencies, whereas for large Fresnel numbers the backward memory is advantageous. The optimal light modes to store in the memory are presented together with the corresponding spin waves and outcoming light modes. We show that for high optical depths such Λ-type atomic ensembles allow for highly efficient backward and forward memories even for small Fresnel numbers F 0.1.

Original language	English
Journal	Physical Review A (Atomic, Molecular and Optical Physics)
Volume	84
Issue number	4
Pages (from-to)	043838
Number of pages	17
ISSN	2469-9926
DOIs	https://doi.org/10.1103/PhysRevA.84.043838
Publication status	Published - 24 Oct 2011
Externally published	Yes

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title = "Three-dimensional theory of quantum memories based on ¿-type atomic ensembles",

abstract = "We develop a three-dimensional theory for quantum memories based on light storage in ensembles of Λ-type atoms, where two long-lived atomic ground states are employed. We consider light storage in an ensemble of finite spatial extent and we show that within the paraxial approximation the Fresnel number of the atomic ensemble and the optical depth are the only important physical parameters determining the quality of the quantum memory. We analyze the influence of these parameters on the storage of light followed by either forward or backward read-out from the quantum memory. We show that for small Fresnel numbers the forward memory provides higher efficiencies, whereas for large Fresnel numbers the backward memory is advantageous. The optimal light modes to store in the memory are presented together with the corresponding spin waves and outcoming light modes. We show that for high optical depths such Λ-type atomic ensembles allow for highly efficient backward and forward memories even for small Fresnel numbers F 0.1.",

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T1 - Three-dimensional theory of quantum memories based on ¿-type atomic ensembles

AU - Zeuthen, Emil

AU - Grodecka-Grad, Anna

AU - Sørensen, Anders Søndberg

PY - 2011/10/24

Y1 - 2011/10/24

N2 - We develop a three-dimensional theory for quantum memories based on light storage in ensembles of Λ-type atoms, where two long-lived atomic ground states are employed. We consider light storage in an ensemble of finite spatial extent and we show that within the paraxial approximation the Fresnel number of the atomic ensemble and the optical depth are the only important physical parameters determining the quality of the quantum memory. We analyze the influence of these parameters on the storage of light followed by either forward or backward read-out from the quantum memory. We show that for small Fresnel numbers the forward memory provides higher efficiencies, whereas for large Fresnel numbers the backward memory is advantageous. The optimal light modes to store in the memory are presented together with the corresponding spin waves and outcoming light modes. We show that for high optical depths such Λ-type atomic ensembles allow for highly efficient backward and forward memories even for small Fresnel numbers F 0.1.

AB - We develop a three-dimensional theory for quantum memories based on light storage in ensembles of Λ-type atoms, where two long-lived atomic ground states are employed. We consider light storage in an ensemble of finite spatial extent and we show that within the paraxial approximation the Fresnel number of the atomic ensemble and the optical depth are the only important physical parameters determining the quality of the quantum memory. We analyze the influence of these parameters on the storage of light followed by either forward or backward read-out from the quantum memory. We show that for small Fresnel numbers the forward memory provides higher efficiencies, whereas for large Fresnel numbers the backward memory is advantageous. The optimal light modes to store in the memory are presented together with the corresponding spin waves and outcoming light modes. We show that for high optical depths such Λ-type atomic ensembles allow for highly efficient backward and forward memories even for small Fresnel numbers F 0.1.

U2 - 10.1103/PhysRevA.84.043838

DO - 10.1103/PhysRevA.84.043838

M3 - Journal article

SN - 2469-9926

VL - 84

SP - 043838

JO - Physical Review A - Atomic, Molecular, and Optical Physics

JF - Physical Review A - Atomic, Molecular, and Optical Physics

IS - 4

ER -

Three-dimensional theory of quantum memories based on ¿-type atomic ensembles

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