English

Towards a large deviation theory for statistical-mechanical complex systems

Statistical Mechanics 2011-10-31 v1 Mathematical Physics math.MP Probability

Abstract

The theory of large deviations constitutes a mathematical cornerstone in the foundations of Boltzmann-Gibbs statistical mechanics, based on the additive entropy SBG=kBi=1WpilnpiS_{BG}=- k_B\sum_{i=1}^W p_i \ln p_i. Its optimization under appropriate constraints yields the celebrated BG weight eβEie^{-\beta E_i}. An elementary large-deviation connection is provided by NN independent binary variables, which, in the NN\to\infty limit yields a Gaussian distribution. The probability of having nN/2n \ne N/2 out of NN throws is governed by the exponential decay eNre^{-N r}, where the rate function rr 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 Sq=kB1i=1Wpiqq1S_q=k_B\frac{1- \sum_{i=1}^W p_i^q}{q-1} (qR;S1=SBGq \in {\cal R}; \,S_1=S_{BG}). Its optimization yields the generalized weight eqβqEie_q^{-\beta_q E_i} (eqz[1+(1q)z]1/(1q);e1z=ez)e_q^z \equiv [1+(1-q)z]^{1/(1-q)};\,e_1^z=e^z). We numerically study large deviations for a strongly correlated model which depends on the indices Q[1,2)Q \in [1,2) and γ(0,1)\gamma \in (0,1). This model provides, in the NN\to\infty limit (γ\forall \gamma), QQ-Gaussian distributions, ubiquitously observed in nature (Q1Q\to 1 recovers the independent binary model). We show that its corresponding large deviations are governed by eqNrqe_q^{-N r_q} (1/N1/(q1)\propto 1/N^{1/(q-1)} if q>1q>1) where q=Q1γ(3Q)+11q= \frac{Q-1}{\gamma (3-Q)}+1 \ge 1. This qq-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

R2 v1 2026-06-21T19:27:27.286Z