Towards a large deviation theory for statistical-mechanical complex systems
Abstract
The theory of large deviations constitutes a mathematical cornerstone in the foundations of Boltzmann-Gibbs statistical mechanics, based on the additive entropy . Its optimization under appropriate constraints yields the celebrated BG weight . An elementary large-deviation connection is provided by independent binary variables, which, in the limit yields a Gaussian distribution. The probability of having out of throws is governed by the exponential decay , where the rate function is directly related to the relative BG entropy. To deal with a wide class of complex systems, nonextensive statistical mechanics has been proposed, based on the nonadditive entropy (). Its optimization yields the generalized weight (. We numerically study large deviations for a strongly correlated model which depends on the indices and . This model provides, in the limit (), -Gaussian distributions, ubiquitously observed in nature ( recovers the independent binary model). We show that its corresponding large deviations are governed by ( if ) where . This -generalized illustration opens wide the door towards a desirable large-deviation foundation of nonextensive statistical mechanics.
Keywords
Cite
@article{arxiv.1110.6303,
title = {Towards a large deviation theory for statistical-mechanical complex systems},
author = {Guiomar Ruiz and Constantino Tsallis},
journal= {arXiv preprint arXiv:1110.6303},
year = {2011}
}
Comments
6 pages, 4 figures