Krešić, I., & Ackemann, T. (2023). Quantum enhanced SU(1,1) matter-wave interferometry in a ring cavity. Physical Review A, 108(4), Article 043302. https://doi.org/10.1103/PhysRevA.108.043302
quantum entanglement; quantum metrology; ultracold atoms; cavity QED
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Abstract:
Quantum squeezed states offer metrological enhancement as compared to their classical counterparts. Here, we devise and numerically explore a method for performing SU(1,1) interferometry beyond the standard quantum limit, using quasi-cyclic nonlinear wave mixing dynamics of ultracold atoms in a ring cavity. The method is based on generating quantum correlations between many atoms via photon-mediated optomechanical interaction. Timescales of the interferometer operation are here given by the inverse of photonic recoil frequency, and are orders of magnitude shorter than the timescales of collisional spin mixing–based interferometers. Such shorter timescales should enable not only faster measurement cycles but also lower atomic losses from the trap during measurement, which may lead to significant quantum metrological gain in matter-wave interferometry with state-of-the-art cavity setups.
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Research facilities:
Vienna Scientific Cluster
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Project title:
Lichtausbreitung in der nicht-hermitischen Photonik: M 3011 (FWF Fonds zur Förderung der wissenschaftlichen Forschung (FWF)) Selbstorganisation von ultrakalten Atomen für die kommenden Quantentechnologien: ESQ-Kresic (Österr. Akademie der Wissenschaften)
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Research Areas:
Quantum Modeling and Simulation: 25% Quantum Many-body Systems Physics: 50% Quantum Metrology and Precision Measurements: 25%
