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Atomic and Laser Physics
Credit: Jack Hobhouse

Shuying Chen

PDRA

Research theme

  • Quantum information and computation

Sub department

  • Atomic and Laser Physics

Research groups

  • Ion trap quantum computing
shuying.chen@physics.ox.ac.uk
Clarendon Laboratory, room Old Library
  • About
  • Publications

Quantum non-demolition measurement of photon number with atom-light interferometers.

Optics express 25:25 (2017) 31827-31839

Authors:

SY Chen, LQ Chen, ZY Ou, Weipingz Hang

Abstract:

When atoms are illuminated by an off-resonant field, the AC Stark effect will lead to phase shifts in atomic states. The phase shifts are proportional to the photon number of the off-resonant illuminating field. By measuring the atomic phase with newly developed atom-light hybrid interferometers, we can achieve quantum non-demolition measurement of the photon number of the optical field. In this paper, we analyze theoretically the performance of this QND measurement scheme by using the QND measurement criteria established by Holland et al [Phys. Rev. A 42, 2995 (1990)]. We find the quality of the QND measurement depends on the phase resolution of the atom-light hybrid interferometers. We apply this QND measurement scheme to a twin-photon state from parametric amplifier to verify the photon correlation in the twin beams. Furthermore, a sequential QND measurement procedure is analyzed for verifying the projection property of quantum measurement and for the quantum information tapping. Finally, we discuss the possibility for single-photon-number-resolving detection via QND measurement.
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Atom–light superposition oscillation and Ramsey-like atom–light interferometer

Optica Optica Publishing Group 3:7 (2016) 775-775

Authors:

Cheng Qiu, Shuying Chen, LQ Chen, Bing Chen, Jinxian Guo, ZY Ou, Weiping Zhang
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Atom-Light Hybrid Interferometer.

Physical review letters 115:4 (2015) 043602

Authors:

Bing Chen, Cheng Qiu, Shuying Chen, Jinxian Guo, LQ Chen, ZY Ou, Weiping Zhang

Abstract:

A new type of hybrid atom-light interferometer is demonstrated with atomic Raman amplification processes replacing the beam splitting elements in a traditional interferometer. This nonconventional interferometer involves correlated optical and atomic waves in the two arms. The correlation between atoms and light developed with the Raman process makes this interferometer different from conventional interferometers with linear beam splitters. It is observed that the high-contrast interference fringes are sensitive to the optical phase via a path change as well as the atomic phase via a magnetic field change. This new atom-light correlated hybrid interferometer is a sensitive probe of the atomic internal state and should find wide applications in precision measurement and quantum control with atoms and photons.
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