Critical behavior of the geometrical spin clusters and interfaces in the two-dimensional thermalized bond Ising model

Davatolhagh, S.; Moshfeghian, Mahmood; Saberi, Abbas Ali

doi:10.1088/1742-5468/2012/02/p02015

Cited by 6 publications

(7 citation statements)

References 30 publications

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“…In 2010, Smirnov was awarded the Fields medal for the proof of conformal invariance of percolation and the planar Ising model in statistical physics. SLE has soon found many applications and turned out to describe the vorticity lines in turbulence [26,86], domain walls of spin glasses [87,88,89], the nodal lines of random wave functions [90,91], the iso-height lines of random grown surfaces [92,93,94,95,96,97], the avalanche lines in sandpile models [98] and the coastlines and watersheds on Earth [99,101,102]. Among which, SLE could provide quite unexpected connections between some features of interacting systems and ordinary uncorrelated percolation [26,90].…”

Section: Introductionmentioning

confidence: 99%

Recent advances in percolation theory and its applications

2015

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Percolation is the simplest fundamental model in statistical mechanics that exhibits phase transitions signaled by the emergence of a giant connected component. Despite its very simple rules, percolation theory has successfully been applied to describe a large variety of natural, technological and social systems. Percolation models serve as important universality classes in critical phenomena characterized by a set of critical exponents which correspond to a rich fractal and scaling structure of their geometric features. We will first outline the basic features of the ordinary model.Over the years a variety of percolation models has been introduced some of which with completely different scaling and universal properties from the original model with either continuous or discontinuous transitions depending on the control parameter, dimensionality and the type of the underlying rules and networks. We will try to take a glimpse at a number of selective variations including Achlioptas process, half-restricted process and spanning cluster-avoiding process as examples of the so-called explosive percolation. We will also introduce non-self-averaging percolation and discuss correlated percolation and bootstrap percolation with special emphasis on their recent progress. Directed percolation process will be also discussed as a prototype of systems displaying a nonequilibrium phase transition into an absorbing state.In the past decade, after the invention of stochastic Löwner evolution (SLE) by Oded Schramm, two-dimensional (2D) percolation has become a central problem in probability theory leading to the two recent Fields medals. After a short review on SLE, we will provide an overview on existence of the scaling limit and conformal invariance of the critical percolation. We will also establish a connection with the magnetic models based on the percolation properties of the Fortuin-Kasteleyn and geometric spin clusters. As an application we will discuss how percolation theory leads to the reduction of the 3D criticality in a 3D Ising model to a 2D critical behavior.Another recent application is to apply percolation theory to study the properties of natural and artificial landscapes. We will review the statistical properties of the coastlines and watersheds and their relations with percolation. Their fractal structure and compatibility with the theory of SLE will also be discussed. The present mean sea level on Earth will be shown to coincide with the critical threshold in a percolation description of the global topography.

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Section: Introductionmentioning

confidence: 99%

Recent advances in percolation theory and its applications

2015

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“…Finally, we discuss the concept of phase transition and percolation by examining some thermodynamic quantities 25 and the moments of the probability distribution, including free energy, magnetization, kurtosis, mean, and variance. We observed that the fluctuations of most of the quantities studied for the RCM with the connection function

g(x)&amp;#x0003D;{I}_{\left\{&amp;#x0007C;x&amp;#x0007C;\le 1\right\}}

or the Poisson plob model in terms of temperature parameter are similar to the fluctuations in the two‐dimensional Ising model 26,27 . These fluctuations play a central role in our understanding of phase transition.…”

Section: Introductionmentioning

confidence: 82%

“…We observed that the fluctuations of most of the quantities studied for the RCM with the connection function g (x) = I {|x|≤1} or the Poisson plob model in terms of temperature parameter are similar to the fluctuations in the two-dimensional Ising model. 26,27 These fluctuations play a central role in our understanding of phase transition. Their behavior near a critical point provides important information about the underlying many-particle interactions.…”

Section: Introductionmentioning

confidence: 99%

Phase transition in a stochastic geometry model with applications to statistical mechanics

Kazemi

Pourdarvish

Sadeghi

2022

Math Methods in App Sciences

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We study the connected components of the stochastic geometry model on Poisson points which is obtained by connecting points with a probability that depends on their relative position. Equivalently, we investigate the random clusters of the random connection model defined on the points of a Poisson process in d-dimensional space where the links are added with a particular probability function. We use the thermodynamic relations between free energy, entropy, and internal energy to find the functions of the cluster size distribution in the statistical mechanics of extensive and nonextensive. By comparing these obtained functions with the probability function predicted by Penrose, we provide a suitable approximate probability function. Moreover, we relate this stochastic geometry model to the physics literature by showing how the fluctuations of the thermodynamic quantities of this model correspond to other models when a phase transition (10.1002/mma.6965, 2020) occurs. Also, we obtain the critical point using a new analytical method.

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“…Percolation is one of the simplest models in probability theory which provides a suitable platform to formulate and model various natural phenomena that exhibit geometric phase transitions with universal characteristics [1][2][3][4]. Percolation has been applied to describe a wide range of critical behavior such as, among many others, flow through porous media for connectivity [5,6], networks [7][8][9], magnetic models [10][11][12][13][14][15][16][17], colloids [18,19], growth models [20], topography of planets [21][22][23] and epidemic models [24]. The concept of universality lets many microscopically different physical systems exhibit the same critical behavior with quantitatively identical features, assigned by a set of critical exponents.…”

Section: Introductionmentioning

confidence: 99%

Universality class of epidemic percolation transitions driven by random walks

Feshanjerdi,

Saberi

2021

Preprint

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Inspired by the recent viral epidemic outbreak and its consequent worldwide pandemic, we devise a model to capture the dynamics and the universality of the spread of such infectious diseases. The transition from a pre-critical to the post-critical phase is modeled by a percolation problem driven by random walks on a two-dimensional lattice with an extra average number ρ of nonlocal links per site. Using the finite-size scaling analysis, we find that the effective exponents of the percolation transitions as well as the corresponding time thresholds, extrapolated to the infinite system size, are ρ-dependent. We argue that the ρ-dependence of our estimated exponents represents a crossovertype behavior caused by the finite-size effects between the two limiting regimes of the system. We also find that the universal scaling functions governing the critical behavior in every single realization of the model, can be well described by the theory of extreme values for the maximum jumps in the order parameter and by the central limit theorem for the transition threshold.

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Critical behavior of the geometrical spin clusters and interfaces in the two-dimensional thermalized bond Ising model

Cited by 6 publications

References 30 publications

Recent advances in percolation theory and its applications

Recent advances in percolation theory and its applications

Phase transition in a stochastic geometry model with applications to statistical mechanics

Universality class of epidemic percolation transitions driven by random walks

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