Strongly enhanced spin squeezing via quantum control

Collin M. Trail; Poul S. Jessen; Ivan H. Deutsch

doi:10.1103/PhysRevLett.105.193602

Strongly enhanced spin squeezing via quantum control

Collin M. Trail, Poul S. Jessen, Ivan H. Deutsch

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32 Scopus citations

Abstract

We describe a new approach to spin squeezing based on a double-pass Faraday interaction between an optical probe and an optically dense atomic sample. A quantum eraser is used to remove residual spin-probe entanglement, thereby realizing a single-axis twisting unitary map on the collective spin. This interaction can be phase matched, resulting in exponential enhancement of squeezing as a function of optical density for times short compared to the decoherence time. In practice the scaling and peak squeezing depends on decoherence, technical loss, and noise. Including these imperfections, our model indicates that ∼10dB of squeezing should be achievable with laboratory parameters.

Original language	English (US)
Article number	193602
Journal	Physical review letters
Volume	105
Issue number	19
DOIs	https://doi.org/10.1103/PhysRevLett.105.193602
State	Published - Nov 4 2010

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.105.193602

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abstract = "We describe a new approach to spin squeezing based on a double-pass Faraday interaction between an optical probe and an optically dense atomic sample. A quantum eraser is used to remove residual spin-probe entanglement, thereby realizing a single-axis twisting unitary map on the collective spin. This interaction can be phase matched, resulting in exponential enhancement of squeezing as a function of optical density for times short compared to the decoherence time. In practice the scaling and peak squeezing depends on decoherence, technical loss, and noise. Including these imperfections, our model indicates that ∼10dB of squeezing should be achievable with laboratory parameters.",

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AB - We describe a new approach to spin squeezing based on a double-pass Faraday interaction between an optical probe and an optically dense atomic sample. A quantum eraser is used to remove residual spin-probe entanglement, thereby realizing a single-axis twisting unitary map on the collective spin. This interaction can be phase matched, resulting in exponential enhancement of squeezing as a function of optical density for times short compared to the decoherence time. In practice the scaling and peak squeezing depends on decoherence, technical loss, and noise. Including these imperfections, our model indicates that ∼10dB of squeezing should be achievable with laboratory parameters.

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Strongly enhanced spin squeezing via quantum control

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