Open AccessWorms exploring geometrical features of phase transitions
Author(s) -
Wolfhard Janke,
Thomas Neuhaus,
Adriaan M. J. Schakel
Publication year - 2011
Publication title -
physics procedia
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.26
H-Index - 61
ISSN - 1875-3892
DOI - 10.1016/j.phpro.2011.05.059
Subject(s) - statistical physics , ising model , observable , scaling , lattice (music) , monte carlo method , random graph , phase transition , random walk , computer science , directed percolation , series (stratigraphy) , fractal , graph , physics , critical exponent , theoretical computer science , mathematics , geometry , mathematical analysis , statistics , quantum mechanics , acoustics , biology , paleontology
The loop-gas approach to statistical physics provides an alternative, geometrical description of phase transitions in terms of line-like objects. The resulting statistical random-graph ensemble composed of loops and (open) chains can be e_ciently generated by Monte Carlo simulations using the so-called “worm” update algorithm. Concepts from percolation theory and the theory of self-avoiding random walks are used to derive estimators of physical observables that utilize the nature of the worm algorithm. The fractal structure of random loops and chains as well as their scaling properties encode the critical behavior of the statistical system. The general approach is illustrated for the hightemperature series expansion of the Ising model, or O(1) loop model, on a honeycomb lattice, with its known exact results as valuable benchmarks
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