Litcius/Paper detail

Statistical properties of avalanches via the<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mi>c</mml:mi></mml:math>-record process

Vincenzo Maria Schimmenti, Satya N. Majumdar, Alberto Rosso

2021Physical review. E14 citationsDOIOpen Access PDF

Abstract

We study the statistics of avalanches, as a response to an applied force, undergone by a particle hopping on a one-dimensional lattice where the pinning forces at each site are independent and identically distributed (i.i.d.), each drawn from a continuous f(x). The avalanches in this model correspond to the interrecord intervals in a modified record process of i.i.d. variables, defined by a single parameter c>0. This parameter characterizes the record formation via the recursive process R_{k}>R_{k-1}-c, where R_{k} denotes the value of the kth record. We show that for c>0, if f(x) decays slower than an exponential for large x, the record process is nonstationary as in the standard c=0 case. In contrast, if f(x) has a faster than exponential tail, the record process becomes stationary and the avalanche size distribution π(n) has a decay faster than 1/n^{2} for large n. The marginal case where f(x) decays exponentially for large x exhibits a phase transition from a nonstationary phase to a stationary phase as c increases through a critical value c_{crit}. Focusing on f(x)=e^{-x} (with x≥0), we show that c_{crit}=1 and for c<1, the record statistics is nonstationary. However, for c>1, the record statistics is stationary with avalanche size distribution π(n)∼n^{-1-λ(c)} for large n. Consequently, for c>1, the mean number of records up to N steps grows algebraically ∼N^{λ(c)} for large N. Remarkably, the exponent λ(c) depends continuously on c for c>1 and is given by the unique positive root of c=-ln(1-λ)/λ. We also unveil the presence of nontrivial correlations between avalanches in the stationary phase that resemble earthquake sequences.

Topics & Concepts

Statistical physicsIndependent and identically distributed random variablesExponentExponential distributionExponential functionMathematicsLattice (music)Exponential growthExponential decayDistribution (mathematics)Stochastic processStationary distributionStatisticsPhase transitionPhysicsProcess (computing)Initial value problemExtreme value theoryDiscrete time and continuous timePhase (matter)Stationary processMathematical analysisValue (mathematics)Renewal theoryWeibull distributionExpected valueMarginal distributionRandom variableCritical exponentCounting processPhase-type distributionParticle (ecology)Gamma distributionShape parameterContact process (mathematics)Theoretical and Computational PhysicsStochastic processes and statistical mechanicsStatistical Mechanics and Entropy