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Quantum metrology with a squeezed Kerr oscillator

Jiajie Guo, Qiongyi He, Matteo Fadel

2024Physical review. A/Physical review, A12 citationsDOIOpen Access PDF

Abstract

We study the squeezing dynamics in a Kerr-nonlinear oscillator, and quantify the metrological usefulness of the resulting states. Even if the nonlinearity limits the attainable squeezing by making the evolution non-Gaussian, the states obtained still have a high quantum Fisher information for sensing displacements. However, contrary to the Gaussian case, the amplitude of the displacement cannot be estimated by simple quadrature measurements. Therefore, we propose the use of a measurement-after-interaction protocol where a linear quadrature measurement is preceded by an additional nonlinear evolution, and show the significant sensitivity enhancement that can be obtained. Our results are robust when considering realistic imperfections such as energy relaxation, and can be implemented in state-of-the-art experimental setups.

Topics & Concepts

Quantum metrologyMetrologyNonlinear systemPhysicsStatistical physicsGaussianQuantumCoherent statesKerr nonlinearityQuantum mechanicsQuadrature (astronomy)AmplitudeSensitivity (control systems)Squeezed coherent stateClassical mechanicsKerr effectOpticsQuantum dynamicsElectronic engineeringEngineeringQuantum discordQuantum Information and CryptographyMechanical and Optical ResonatorsNeural Networks and Reservoir Computing
Quantum metrology with a squeezed Kerr oscillator | Litcius