Experimental demonstration of quantum memory for light

Julsgaard, Brian; Sherson, Jacob; Cirac, J. I.; Fiurášek, Jaromı́r; Polzik, E. S.

doi:10.1038/nature03064

Cited by 801 publications

(954 citation statements)

References 22 publications

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“…Since the first observation of coherent retrieval of a stored optical pulse in a Bose Einstein condensate using slow light (Liu et al, 2001), interest in quantum memories has increased in the last decade (Alexander et al, 2006;Afzelius et al, 2010;Chaneliere et al, 2005. Choi et al, 2008110 Ham, 1998;Ham 2009a;Ham, 2010a;Hedges et al, 2010;Hetet et al, 2008;Hosseini et al, 2009;Julsgaard et al, 2004;Kocharovskaya et al, 2001;Kraus et al, 2006;Liu et al, 2001;Moiseev & Kroll, 2001;Moiseev et al, 2003;Neumann et al, 2009;Nilsson & Kroll, 2005;Sangouard et al, 2007;Turukhin et al, 2002;Van der Wal, et al, 2003). Because temporal multimode storage capability is required for the quantum repeaters, a photon echo-type protocol has emerged as a best candidate.…”

Section: Introductionmentioning

confidence: 99%

Control of Photon Storage Time in Photon Echoes using a Deshelving Process

Ham¹

2011

Numerical Simulations - Applications, Examples and Theory

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Section: Introductionmentioning

confidence: 99%

Control of Photon Storage Time in Photon Echoes using a Deshelving Process

Ham¹

2011

Numerical Simulations - Applications, Examples and Theory

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“…As discussed in e.g. [5,7] the Faraday interaction ∝Ŝ zĴz causes different phase shifts on the σ + and σ − circularly polarized field components due to the population difference on the atomic magnetic sub-states, equivalent to a rotation of the linear optical polarization. Conversely, the light induced AC-Stark shift imposes a phase difference between the atomic magnetic sub-states equivalent to an optical spin rotation around the z-axis proportional to the intensity difference between σ + and σ − field components.…”

mentioning

confidence: 99%

“…In these experiments, the collective atomic population distribution on internal states is a quantum degree of freedom, and the measurement of the polarization of the light after the interaction alters the collective atomic quantum state. Measurements play an important role in the experiments reported in [5,6,7,8], but it has also been shown that multiple interactions between a light pulse and an atomic medium [9,10,11,12] suffice to effectively couple atoms and fields e.g. resulting in interspecies entanglement, atomic squeezing, or transfer of quantum states.…”

mentioning

confidence: 99%

“…∼ 7 dB in [4]). In this Letter we show, however, that by reflecting a light beam so that it interacts twice through the off-resonant Faraday-type interaction with an atomic sample, a simple, robust, and efficient source of strongly squeezed light is obtained, which may well outperform the above mentioned schemes.The optical Faraday rotation of light passing through a spin polarized atomic medium has been applied in a number of recent experiments to demonstrate entanglement and squeezing of atomic samples [5,6], atomic quantum memories for light [7], and teleportation of quantum states between light and matter [8]. In these experiments, the collective atomic population distribution on internal states is a quantum degree of freedom, and the measurement of the polarization of the light after the interaction alters the collective atomic quantum state.…”

mentioning

confidence: 99%

“…The optical Faraday rotation of light passing through a spin polarized atomic medium has been applied in a number of recent experiments to demonstrate entanglement and squeezing of atomic samples [5,6], atomic quantum memories for light [7], and teleportation of quantum states between light and matter [8]. In these experiments, the collective atomic population distribution on internal states is a quantum degree of freedom, and the measurement of the polarization of the light after the interaction alters the collective atomic quantum state.…”

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Polarization Squeezing by Optical Faraday Rotation

Sherson

Mølmer

2006

Phys. Rev. Lett.

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We show that it is possible to generate continuous-wave fields and pulses of polarization squeezed light by sending classical, linearly polarized laser light twice through an atomic sample which causes an optical Faraday rotation of the field polarization. We characterize the performance of the process, and we show that an appreciable degree of squeezing can be obtained under realistic physical assumptions.PACS numbers: 32.80.Qk; 42.50.Dv Highly squeezed states of light are valuable for numerous quantum information protocols and high precision metrology . Several techniques exist for the generation of squeezed states. In [1] the non-linear phase evolution due to the Kerr effect in an optical fiber was used to produce 5.1 dB of polarization squeezing. Cold atomic samples in high-finesse cavities cause similar Kerr-like effects, and 1.5 dB of quadrature squeezing [2] and ∼ 0.5 dB of polarization squeezing [3] has been observed. The most well established technique to date, however, is to use non-linear crystals in very good cavities (e.g. ∼ 7 dB in [4]). In this Letter we show, however, that by reflecting a light beam so that it interacts twice through the off-resonant Faraday-type interaction with an atomic sample, a simple, robust, and efficient source of strongly squeezed light is obtained, which may well outperform the above mentioned schemes.The optical Faraday rotation of light passing through a spin polarized atomic medium has been applied in a number of recent experiments to demonstrate entanglement and squeezing of atomic samples [5,6], atomic quantum memories for light [7], and teleportation of quantum states between light and matter [8]. In these experiments, the collective atomic population distribution on internal states is a quantum degree of freedom, and the measurement of the polarization of the light after the interaction alters the collective atomic quantum state. Measurements play an important role in the experiments reported in [5,6,7,8], but it has also been shown that multiple interactions between a light pulse and an atomic medium [9,10,11,12] suffice to effectively couple atoms and fields e.g. resulting in interspecies entanglement, atomic squeezing, or transfer of quantum states.Our proposed physical set-up is sketched in Figure 1. In part a) we depict an atomic gas, spin polarized perpendicular to the plane of the figure, through which a cw beam or a pulse of linearly polarized light is transmitted twice from different directions. In part b) of the figure we suggest an implementation with two oppositely polarized samples which are both traversed twice by the laser beam. As will become clear below, the desired dynamics arises solely in the limit in which the light field passes through the atoms from both directions simultaneously. Figure 1: Physical setup for production of squeezed light. In panel a), a coherent cw beam or pulse of linearly polarized light is transmitted through a spin polarized atomic gas, its polarization is rotated, and it is transmitted through the gas a second time...

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Quantum Memory

Bashkansky¹,

Black²,

Kwolek³

et al. 2021

Wiley Encyclopedia of Electrical and Electronics Engineering

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Quantum Memory (QM) commonly refers to a system that reversibly transfers quantum states between a material storage system and a propagating electromagnetic field. It represents a key component in quantum information science and technology. Over the past 25 years, a wide range of theoretical protocols and experimental approaches to QM has been studied. These include optical delays, mechanical resonators, topological approaches, solid state spins, trapped single atoms and ions, and atomic ensembles. New applications of QM are being investigated and discovered all the time, including quantum computation, long‐distance entanglement distribution, quantum teleportation, and long‐distance quantum key distribution. Challenges to the implementation of QM include inefficiencies in storing and recovering the quantum state, and decoherence, which usually manifests by environment‐induced dephasing. In this monograph we describe, in general terms, methods and protocols that are used in many forms of QM. We also discuss the various experimental systems in which QM has been demonstrated or proposed. Additionally, we discuss the applications of QM that have been identified and progress made in implementing those applications.

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Experimental demonstration of quantum memory for light

Cited by 801 publications

References 22 publications

Control of Photon Storage Time in Photon Echoes using a Deshelving Process

Control of Photon Storage Time in Photon Echoes using a Deshelving Process

Polarization Squeezing by Optical Faraday Rotation

Quantum Memory

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