Enhancing vacuum squeezing via magnetic field optimization

Zhifei Yu; Shuqi Liu; Jinxian Guo; Guzhi Bao; Yuan Wu; Liqing Chen

doi:10.1364/OE.455071

Enhancing vacuum squeezing via magnetic field optimization

Zhifei Yu
, Shuqi Liu
, Jinxian Guo
, Guzhi Bao^*
, Yuan Wu^*
, Liqing Chen^*

^*Corresponding author for this work

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

3 Scopus citations

Abstract

In this paper, we report on -3.5±0.2 dB vacuum squeezing (corresponding to -4.2±0.2 dB with loss correction) at 795 nm via the polarization self-rotation (PSR) effect in rubidium vapor by applying a magnetic field, whose direction is perpendicular to the propagation and polarization of the pump light. Compared with the case without the magnetic field, whose optimal squeezing degree is about -1.5 dB, this weak magnetic field can enhance the PSR effect and ultimately increase the squeezing degree. This compact squeezed light source can be potentially utilized in quantum protocols in which atomic ensembles are involved, such as in quantum memory, atomic magnetometers and quantum interferometers.

Original language	English
Pages (from-to)	17106-17114
Number of pages	9
Journal	Optics Express
Volume	30
Issue number	10
DOIs	https://doi.org/10.1364/OE.455071
State	Published - 9 May 2022
Externally published	Yes

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title = "Enhancing vacuum squeezing via magnetic field optimization",

abstract = "In this paper, we report on -3.5±0.2 dB vacuum squeezing (corresponding to -4.2±0.2 dB with loss correction) at 795 nm via the polarization self-rotation (PSR) effect in rubidium vapor by applying a magnetic field, whose direction is perpendicular to the propagation and polarization of the pump light. Compared with the case without the magnetic field, whose optimal squeezing degree is about -1.5 dB, this weak magnetic field can enhance the PSR effect and ultimately increase the squeezing degree. This compact squeezed light source can be potentially utilized in quantum protocols in which atomic ensembles are involved, such as in quantum memory, atomic magnetometers and quantum interferometers.",

author = "Zhifei Yu and Shuqi Liu and Jinxian Guo and Guzhi Bao and Yuan Wu and Liqing Chen",

note = "Publisher Copyright: {\textcopyright} 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement Journal {\textcopyright} 2022",

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AU - Yu, Zhifei

AU - Liu, Shuqi

AU - Guo, Jinxian

AU - Bao, Guzhi

AU - Wu, Yuan

AU - Chen, Liqing

PY - 2022/5/9

Y1 - 2022/5/9

N2 - In this paper, we report on -3.5±0.2 dB vacuum squeezing (corresponding to -4.2±0.2 dB with loss correction) at 795 nm via the polarization self-rotation (PSR) effect in rubidium vapor by applying a magnetic field, whose direction is perpendicular to the propagation and polarization of the pump light. Compared with the case without the magnetic field, whose optimal squeezing degree is about -1.5 dB, this weak magnetic field can enhance the PSR effect and ultimately increase the squeezing degree. This compact squeezed light source can be potentially utilized in quantum protocols in which atomic ensembles are involved, such as in quantum memory, atomic magnetometers and quantum interferometers.

AB - In this paper, we report on -3.5±0.2 dB vacuum squeezing (corresponding to -4.2±0.2 dB with loss correction) at 795 nm via the polarization self-rotation (PSR) effect in rubidium vapor by applying a magnetic field, whose direction is perpendicular to the propagation and polarization of the pump light. Compared with the case without the magnetic field, whose optimal squeezing degree is about -1.5 dB, this weak magnetic field can enhance the PSR effect and ultimately increase the squeezing degree. This compact squeezed light source can be potentially utilized in quantum protocols in which atomic ensembles are involved, such as in quantum memory, atomic magnetometers and quantum interferometers.

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EP - 17114

JO - Optics Express

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Enhancing vacuum squeezing via magnetic field optimization

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