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Quantum Versus Classical Switching Dynamics of Driven Dissipative Kerr Resonators

Christian Kraglund Andersen, Archana Kamal, Nicholas A. Masluk, Ioan M. Pop, Alexandre Blais, Michel H. Devoret

2020Physical Review Applied25 citationsDOIOpen Access PDF

Abstract

We report a first-principles study of the driven dissipative dynamics for Kerr oscillators in the mesoscopic regime. This regime is characterized by large Kerr nonlinearity, realized here using the nonlinear kinetic inductance of a large array of Josephson junctions. The experimentally measured nonlinear resonance lineshapes of the junction array modes show significant deviations from steady-state numerical predictions, and necessitate time-dependent numerical simulations indicative of strong measurement-induced dephasing in the system arising from the large cross-Kerr effect between array modes. Analytical and numerical calculations of switching rate corroborate this by showing the emergence of a slow time scale, which is much longer than the linear decay rate and is set by fluctuation-induced switching times in the bistable regime. Furthermore, our analysis shows that the usual quantum-activated escape treatment is inadequate for prediction of the switching rates at large frequency shifts caused by strong nonlinearities, necessitating a quantum treatment that utilizes the full system Liouvillian. Based on our analysis, we identify a universal crossover parameter that delineates the regimes of validity of semiclassical and quantum descriptions, respectively. Our work shows how dynamical switching effects in strongly nonlinear systems provide a platform to study quantum-to-classical transitions.

Topics & Concepts

PhysicsDephasingBistabilityMesoscopic physicsDissipative systemSemiclassical physicsQuantumNonlinear systemJosephson effectWork (physics)Quantum mechanicsParametric oscillatorAttractorQuantum dynamicsKerr effectResonance (particle physics)Quantum systemChaoticStatistical physicsClassical mechanicsKinetic inductanceResonatorQuantum electrodynamicsSynchronization (alternating current)Parametric statisticsSwitching timeBifurcationDegenerate energy levelsComputer simulationQuantum opticsDynamics (music)Condensed matter physicsMechanical and Optical ResonatorsNonlinear Photonic Systemsstochastic dynamics and bifurcation
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