Ising model in small-world networks

A. Barrat; A. L. Barabási; A. Scala; B. J. Kim; C. Moore; C. Moore; C. P. Zhu; C. P. Zhu; Carlos P. Herrero; D. J. Watts; L. F. Lago-Fernández; M. A. de Menezes; M. Barthélémy; M. Barthélémy; M. E. J. Newman; M. E. J. Newman; M. Gitterman; M. Kuperman; P. Svenson; R. Albert; S. H. Strogatz; V. Latora

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Ising model in small-world networks

Authors: A. Barrat
A. L. Barabási
A. Scala
B. J. Kim
C. Moore
C. Moore
C. P. Zhu
C. P. Zhu
Carlos P. Herrero
D. J. Watts
L. F. Lago-Fernández
M. A. de Menezes
M. Barthélémy
M. Barthélémy
M. E. J. Newman
M. E. J. Newman
M. Gitterman
M. Kuperman
P. Svenson
R. Albert
S. H. Strogatz
V. Latora
Publication date: 6 June 2002
Publisher: 'American Physical Society (APS)'
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Abstract

The Ising model in small-world networks generated from two- and three-dimensional regular lattices has been studied. Monte Carlo simulations were carried out to characterize the ferromagnetic transition appearing in these systems. In the thermodynamic limit, the phase transition has a mean-field character for any finite value of the rewiring probability p, which measures the disorder strength of a given network. For small values of p, both the transition temperature and critical energy change with p as a power law. In the limit p -> 0, the heat capacity at the transition temperature diverges logarithmically in two-dimensional (2D) networks and as a power law in 3D.Comment: 6 pages, 7 figure

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