Percolation thresholds for discrete-continuous models with nonuniform probabilities of bond formation

Bartłomiej Szczygieł; Marek Dudyński; Kamil Kwiatkowski; Maciej Lewenstein; Gerald John Lapeyre; Jan Wehr

doi:10.1103/PhysRevE.93.022127

Percolation thresholds for discrete-continuous models with nonuniform probabilities of bond formation

Bartłomiej Szczygieł, Marek Dudyński, Kamil Kwiatkowski, Maciej Lewenstein, Gerald John Lapeyre, Jan Wehr

Research output: Contribution to journal › Article › peer-review

Abstract

We introduce a class of discrete-continuous percolation models and an efficient Monte Carlo algorithm for computing their properties. The class is general enough to include well-known discrete and continuous models as special cases. We focus on a particular example of such a model, a nanotube model of disintegration of activated carbon. We calculate its exact critical threshold in two dimensions and obtain a Monte Carlo estimate in three dimensions. Furthermore, we use this example to analyze and characterize the efficiency of our algorithm, by computing critical exponents and properties, finding that it compares favorably to well-known algorithms for simpler systems.

Original language	English (US)
Article number	022127
Journal	Physical Review E
Volume	93
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevE.93.022127
State	Published - Feb 18 2016

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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10.1103/PhysRevE.93.022127

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title = "Percolation thresholds for discrete-continuous models with nonuniform probabilities of bond formation",

abstract = "We introduce a class of discrete-continuous percolation models and an efficient Monte Carlo algorithm for computing their properties. The class is general enough to include well-known discrete and continuous models as special cases. We focus on a particular example of such a model, a nanotube model of disintegration of activated carbon. We calculate its exact critical threshold in two dimensions and obtain a Monte Carlo estimate in three dimensions. Furthermore, we use this example to analyze and characterize the efficiency of our algorithm, by computing critical exponents and properties, finding that it compares favorably to well-known algorithms for simpler systems.",

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AU - Szczygieł, Bartłomiej

AU - Dudyński, Marek

AU - Kwiatkowski, Kamil

AU - Lewenstein, Maciej

AU - Lapeyre, Gerald John

AU - Wehr, Jan

PY - 2016/2/18

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N2 - We introduce a class of discrete-continuous percolation models and an efficient Monte Carlo algorithm for computing their properties. The class is general enough to include well-known discrete and continuous models as special cases. We focus on a particular example of such a model, a nanotube model of disintegration of activated carbon. We calculate its exact critical threshold in two dimensions and obtain a Monte Carlo estimate in three dimensions. Furthermore, we use this example to analyze and characterize the efficiency of our algorithm, by computing critical exponents and properties, finding that it compares favorably to well-known algorithms for simpler systems.

AB - We introduce a class of discrete-continuous percolation models and an efficient Monte Carlo algorithm for computing their properties. The class is general enough to include well-known discrete and continuous models as special cases. We focus on a particular example of such a model, a nanotube model of disintegration of activated carbon. We calculate its exact critical threshold in two dimensions and obtain a Monte Carlo estimate in three dimensions. Furthermore, we use this example to analyze and characterize the efficiency of our algorithm, by computing critical exponents and properties, finding that it compares favorably to well-known algorithms for simpler systems.

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Percolation thresholds for discrete-continuous models with nonuniform probabilities of bond formation

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