In physics, the Tsallis entropy is a generalization of the standard Boltzmann–Gibbs entropy.
Overview
The concept was introduced in 1988 by Constantino Tsallis as a basis for generalizing the standard statistical mechanics and is identical in form to Havrda–Charvát structural α-entropy, introduced in 1967 within information theory. In scientific literature, the physical relevance of the Tsallis entropy has been debated. However, from the years 2000 on, an increasingly wide spectrum of natural, artificial and social complex systems have been identified which confirm the predictions and consequences that are derived from this nonadditive entropy, such as nonextensive statistical mechanics, which generalizes the Boltzmann–Gibbs theory. Among the various experimental verifications and applications presently available in the literature, the following ones deserve a special mention:
The distribution characterizing the motion of cold atoms in dissipative optical lattices predicted in 2003 and observed in 2006.
The fluctuations of the magnetic field in the solar wind enabled the calculation of the q-triplet.
The velocity distributions in a driven dissipative dusty plasma.
High energy collisional experiments at LHC/CERN and RHIC/Brookhaven.
Among the various available theoretical results which clarify the physical conditions under which Tsallis entropy and associated statistics apply, the following ones can be selected:
Thermostatistics of overdamped motion of interacting particles.
Nonlinear generalizations of the Schroedinger, Klein–Gordon and Dirac equations.
Blackhole entropy calculation.
For further details a bibliography is available at http://tsallis.cat.cbpf.br/biblio.htm Given a discrete set of probabilities with the condition, and any real number, the Tsallis entropy is defined as where is a real parameter sometimes called entropic-index. In the limit as, the usual Boltzmann–Gibbs entropy is recovered, namely For continuous probability distributions, we define the entropy as where is a probability density function. The Tsallis Entropy has been used along with the Principle of maximum entropy to derive the Tsallis distribution.
Given two independent systems A and B, for which the jointprobability density satisfies the Tsallis entropy of this system satisfies From this result, it is evident that the parameter is a measure of the departure from additivity. In the limit when q = 1, which is what is expected for an additive system. This property is sometimes referred to as "pseudo-additivity".
Several interesting physical systems abide by entropic functionals that are more general than the standard Tsallis entropy. Therefore, several physically meaningful generalizations have been introduced. The two most generals of those are notably: Superstatistics, introduced by C. Beck and E. G. D. Cohen in 2003 and Spectral Statistics, introduced by G. A. Tsekouras and Constantino Tsallis in 2005. Both these entropic forms have Tsallis and Boltzmann–Gibbs statistics as special cases; Spectral Statistics has been proven to at least contain Superstatistics and it has been conjectured to also cover some additional cases.
