Litcius/Paper detail

Finite-Time Dynamical Phase Transition in Nonequilibrium Relaxation

Jan Meibohm, Massimiliano Esposito

2022Physical Review Letters31 citationsDOIOpen Access PDF

Abstract

We uncover a finite-time dynamical phase transition in the thermal relaxation of a mean-field magnetic model. The phase transition manifests itself as a cusp singularity in the probability distribution of the magnetization that forms at a critical time. The transition is due to a sudden switch in the dynamics, characterized by a dynamical order parameter. We derive a dynamical Landau theory for the transition that applies to a range of systems with scalar, parity-invariant order parameters. Close to criticalilty, our theory reveals an exact mapping between the dynamical and equilibrium phase transitions of the magnetic model, and implies critical exponents of mean-field type. We argue that interactions between nearby saddle points, neglected at the mean-field level, may lead to critical, spatiotemporal fluctuations of the order parameter, and thus give rise to novel, dynamical critical phenomena.

Topics & Concepts

PhysicsPhase transitionCritical exponentCusp (singularity)Non-equilibrium thermodynamicsStatistical physicsSingularityRelaxation (psychology)SaddleCondensed matter physicsDynamical systems theoryMagnetizationCritical phenomenaQuantum phase transitionSaddle pointCritical point (mathematics)Thermal fluctuationsOrder (exchange)Landau theoryPhase (matter)HysteresisAttractorDistribution (mathematics)Thermal equilibriumGravitational singularityDistribution functionRange (aeronautics)IsotropyCatastrophe theoryDynamical system (definition)Ising modelProbability distributionStatistical Mechanics and EntropyTheoretical and Computational PhysicsAdvanced Thermodynamics and Statistical Mechanics