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Kibble-Zurek scaling in quantum speed limits for shortcuts to adiabaticity

Ricardo Puebla, Sebastian Deffner, Steve Campbell

2020Physical Review Research36 citationsDOIOpen Access PDF

Abstract

Geometric quantum speed limits quantify the tradeoff between the rate at which quantum states can change and the resources that are expended during the evolution. Counterdiabatic driving is a unique tool from shortcuts to adiabaticity to speed up quantum dynamics while completely suppressing nonequilibrium excitations. We show that the quantum speed limit for counterdiabatically driven systems undergoing quantum phase transitions fully encodes the Kibble-Zurek mechanism by correctly predicting the transition from adiabatic to impulse regimes. Our findings are demonstrated for three scenarios, namely the transverse field Ising model, the Landau-Zener model, and the Lipkin-Meshkov-Glick model.

Topics & Concepts

PhysicsQuantumScalingAdiabatic processQuantum annealingStatistical physicsQuantum phase transitionQuantum mechanicsNon-equilibrium thermodynamicsSpeed limitQuantum dynamicsImpulse (physics)Quantum processIsing modelQuantum fluctuationLimit (mathematics)Quantum algorithmQuantum limitSpeedupClassical mechanicsQuantum gateQuantum metrologyOpen quantum systemQuantum computerField (mathematics)Phase transitionQuantum phasesQuantum systemAdiabatic quantum computationQuantum dissipationWork (physics)Quantum operationGeometric phaseQuantum discordTransverse planeQuantum error correctionQuantum simulatorTransverse fieldClassical limitQuantum many-body systemsQuantum Information and CryptographyQuantum Computing Algorithms and Architecture
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