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Autores principales: Yerrababu, Yogeesh Reddy, Majumdar, Satya N., Guiselin, Benjamin, Sadhu, Tridib
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2412.19516
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author Yerrababu, Yogeesh Reddy
Majumdar, Satya N.
Guiselin, Benjamin
Sadhu, Tridib
author_facet Yerrababu, Yogeesh Reddy
Majumdar, Satya N.
Guiselin, Benjamin
Sadhu, Tridib
contents We present a class of stochastic processes in which the large deviation functions of time-integrated observables exhibit singularities that relate to dynamical phase transitions of trajectories. These illustrative examples include Brownian motion with a death rate or in the presence of an absorbing wall, for which we consider a set of empirical observables such as the net displacement, local time, residence time, and area under the trajectory. Using a backward Fokker-Planck approach, we derive the large deviation functions of these observables, and demonstrate how singularities emerge from a competition between survival and diffusion. Furthermore, we analyse this scenario using an alternative approach with tilted operators, showing that at the singular point, the effective dynamics undergoes an abrupt transition. Extending this approach, we show that similar transitions may generically arise in Markov chains with transient states. This scenario is robust and generalizable for non-Markovian dynamics and for many-body systems, potentially leading to multiple dynamical phase transitions. We have confirmed most of our findings on the singular large-deviation function using rare-event simulation techniques.
format Preprint
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publishDate 2024
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spellingShingle Dynamical phase transitions in certain non-ergodic stochastic processes
Yerrababu, Yogeesh Reddy
Majumdar, Satya N.
Guiselin, Benjamin
Sadhu, Tridib
Statistical Mechanics
We present a class of stochastic processes in which the large deviation functions of time-integrated observables exhibit singularities that relate to dynamical phase transitions of trajectories. These illustrative examples include Brownian motion with a death rate or in the presence of an absorbing wall, for which we consider a set of empirical observables such as the net displacement, local time, residence time, and area under the trajectory. Using a backward Fokker-Planck approach, we derive the large deviation functions of these observables, and demonstrate how singularities emerge from a competition between survival and diffusion. Furthermore, we analyse this scenario using an alternative approach with tilted operators, showing that at the singular point, the effective dynamics undergoes an abrupt transition. Extending this approach, we show that similar transitions may generically arise in Markov chains with transient states. This scenario is robust and generalizable for non-Markovian dynamics and for many-body systems, potentially leading to multiple dynamical phase transitions. We have confirmed most of our findings on the singular large-deviation function using rare-event simulation techniques.
title Dynamical phase transitions in certain non-ergodic stochastic processes
topic Statistical Mechanics
url https://arxiv.org/abs/2412.19516