Phase transition in the Jarzynski estimator of free energy differences

Suárez, Alberto; Silbey, R.; Oppenheim, Irwin

doi:10.1103/physreve.85.051108

Cited by 9 publications

(13 citation statements)

References 42 publications

(102 reference statements)

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“…As noted previously1819202122232425262728, the Jarzynski equality may break down for many practical and intrinsic reasons. Its breakdown in our case is peculiar as the deviation is determined by an universal combination of L and ε 0 , which is inherited from the equilibrium scaling behavior of second-order phase transitions.…”

Section: Resultsmentioning

confidence: 90%

Scaling Law for Irreversible Entropy Production in Critical Systems

Hoang

Venkatesh

Han

et al. 2016

Sci Rep

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We examine the Jarzynski equality for a quenching process across the critical point of second-order phase transitions, where absolute irreversibility and the effect of finite-sampling of the initial equilibrium distribution arise in a single setup with equal significance. We consider the Ising model as a prototypical example for spontaneous symmetry breaking and take into account the finite sampling issue by introducing a tolerance parameter. The initially ordered spins become disordered by quenching the ferromagnetic coupling constant. For a sudden quench, the deviation from the Jarzynski equality evaluated from the ideal ensemble average could, in principle, depend on the reduced coupling constant ε0 of the initial state and the system size L. We find that, instead of depending on ε0 and L separately, this deviation exhibits a scaling behavior through a universal combination of ε0 and L for a given tolerance parameter, inherited from the critical scaling laws of second-order phase transitions. A similar scaling law can be obtained for the finite-speed quench as well within the Kibble-Zurek mechanism.

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Section: Resultsmentioning

confidence: 90%

Scaling Law for Irreversible Entropy Production in Critical Systems

Hoang

Venkatesh

Han

et al. 2016

Sci Rep

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“…We illustrate in this section the previous results about estimator convergence for four types of distributions: Gaussian, exponential, Bernoulli, and power-law. Gaussian distributions have been extensively studied in the context of the Jarzynski estimator [31][32][33][34][35][36] and are revisited here to illustrate the case of unbounded random variables. The exponential distribution is considered as a limiting case of the saddle-point analysis, whereas Bernoulli random variables illustrate our results for the bounded case and are relevant for data network applications [37][38][39][40].…”

Section: Test Casesmentioning

confidence: 99%

“…Convergence problems have also been studied for the so-called Jarzynski estimator, which is an estimator similar to (2) used to obtain free energy differences from nonequilibrium experiments [24][25][26][27][28][29][30]. The focus of these studies, however, is mostly on the statistical bias ofĜ M (k) [31][32][33][34][35][36], which disappears in the limit M → ∞, rather than the convergence ofĜ M (k) as a function of k and M .…”

Section: Introductionmentioning

confidence: 99%

Convergence of large-deviation estimators

2015

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We study the convergence of statistical estimators used in the estimation of large-deviation functions describing the fluctuations of equilibrium, nonequilibrium, and manmade stochastic systems. We give conditions for the convergence of these estimators with sample size, based on the boundedness or unboundedness of the quantity sampled, and discuss how statistical errors should be defined in different parts of the convergence region. Our results shed light on previous reports of "phase transitions" in the statistics of free energy estimators and establish a general framework for reliably estimating large-deviation functions from simulation and experimental data and identifying parameter regions where this estimation converges.

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“…as, respectively, the entropy flux between system and environment and the total entropy production. Equations (7), (8) and (9) describe the time dependence of entropy due to the ensemble dynamics described by a TCL master equation. The irreversibility of the process is characterized by a nonzero rate of entropy productionṠ i (t) inside the system which, furthermore, in the case of a Markovian dynamics never becomes negative.…”

Section: A Entropiesmentioning

confidence: 99%

Fluctuation theorems for non-Markovian quantum processes

et al. 2013

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Exploiting previous results on Markovian dynamics and fluctuation theorems, we study the consequences of memory effects on single realizations of nonequilibrium processes within an open system approach. The entropy production along single trajectories for forward and backward processes is obtained with the help of a recently proposed classical-like non-Markovian stochastic unravelling, which is demonstrated to lead to a correction of the standard entropic fluctuation theorem. This correction is interpreted as resulting from the interplay between the information extracted from the system through measurements and the flow of information from the environment to the open system: Due to memory effects single realizations of a dynamical process are no longer independent, and their correlations fundamentally affect the behavior of entropy fluctuations.

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Phase transition in the Jarzynski estimator of free energy differences

Cited by 9 publications

References 42 publications

Scaling Law for Irreversible Entropy Production in Critical Systems

Scaling Law for Irreversible Entropy Production in Critical Systems

Convergence of large-deviation estimators

Fluctuation theorems for non-Markovian quantum processes

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