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Large Deviations for Continuous Time Random Walks

Wanli Wang, Eli Barkai, Stanislav Burov

2020Entropy39 citationsDOIOpen Access PDF

Abstract

Recently observation of random walks in complex environments like the cell and other glassy systems revealed that the spreading of particles, at its tails, follows a spatial exponential decay instead of the canonical Gaussian. We use the widely applicable continuous time random walk model and obtain the large deviation description of the propagator. Under mild conditions that the microscopic jump lengths distribution is decaying exponentially or faster i.e., Lévy like power law distributed jump lengths are excluded, and that the distribution of the waiting times is analytical for short waiting times, the spreading of particles follows an exponential decay at large distances, with a logarithmic correction. Here we show how anti-bunching of jump events reduces the effect, while bunching and intermittency enhances it. We employ exact solutions of the continuous time random walk model to test the large deviation theory.

Topics & Concepts

Random walkIntermittencyLarge deviations theoryStatistical physicsJumpLogarithmExponential functionContinuous-time random walkMathematicsExponential distributionExponential growthExponential decayPower lawDistribution (mathematics)Probability distributionRate functionRandom walker algorithmStandard deviationCascadeHeterogeneous random walk in one dimensionJump processStochastic processMathematical analysisFirst-hitting-time modelLogarithmic growthRare eventsDiffusion and Search DynamicsStochastic processes and statistical mechanicsTheoretical and Computational Physics
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