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Shortcuts to Squeezed Thermal States

Léonce Dupays, Aurélia Chenu

2021Quantum17 citationsDOIOpen Access PDF

Abstract

Squeezed state in harmonic systems can be generated through a variety of techniques, including varying the oscillator frequency or using nonlinear two-photon Raman interaction. We focus on these two techniques to drive an initial thermal state into a final squeezed thermal state with controlled squeezing parameters – amplitude and phase – in arbitrary time. The protocols are designed through reverse engineering for both unitary and open dynamics. Control of the dissipation is achieved using stochastic processes, readily implementable via, e.g., continuous quantum measurements. Importantly, this allows controlling the state entropy and can be used for fast thermalization. The developed protocols are thus suited to generate squeezed thermal states at controlled temperature in arbitrary time.

Topics & Concepts

Unitary stateThermalSqueezed coherent statePhysicsDissipationNonlinear systemState (computer science)Harmonic oscillatorThermal stateCoherent statesStatistical physicsQuantum mechanicsQuantumFocus (optics)AmplitudeEntropy (arrow of time)Control theory (sociology)Quantum stateQuantum opticsUnitary transformationComputer scienceHarmonicVariety (cybernetics)Entropy productionQuantum decoherenceQuantum informationThermal management of electronic devices and systemsPhase (matter)Electronic engineeringMechanical and Optical ResonatorsQuantum Information and CryptographySpectroscopy and Quantum Chemical Studies
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