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W2262821266 abstract "We theoretically investigate the generation of atom-light entanglement via Raman superradiance in an optical cavity, and show how this can be used to enhance the sensitivity of atom interferometry. We model a realistic optical cavity, and show that by careful temporal shaping of the optical local oscillator used to measure the light emitted from the cavity, information in the optical mode can be combined with the signal from the atom interferometer to reduce the quantum noise, and thus increase the sensitivity. It was found in Phys. Rev. Lett. 110, 053002 (2013) that an atomic `seed' was required in order to reduce spontaneous emission and allow for single mode behaviour of the device. In this paper we find that the optical cavity reduces the need for an atomic seed, which allows for stronger atom-light correlations and a greater level of quantum enhancement." @default.
W2262821266 created "2016-06-24" @default.
W2262821266 creator A5064985963 @default.
W2262821266 creator A5071441102 @default.
W2262821266 date "2016-02-03" @default.
W2262821266 modified "2023-09-27" @default.
W2262821266 title "Generation of atom-light entanglement in an optical cavity for quantum enhanced atom interferometry" @default.
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W2262821266 doi "https://doi.org/10.1103/physreva.93.023607" @default.
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