Generalized Algebra Grounded on Nonadditive Entropies

Abstract

The class of N-body complex systems with total number of microscopic states given by W(N) Nγ\;( >1, \,γ > 0) can be thermostatistically handled with the nonadditive entropic functional Sδ(\pi\) = kΣi=1W pi ( 1pi )δ \;(δ>0,\,S1=SBG), SBG=kΣi=1W pi 1pi being the Boltzmann-Gibbs functional. Indeed, Sδ=1/γ(\1/W(N)\)=k[ W(N)]1γ N, as mandated by thermodynamics. Another wide class is that with W(N) N\;(>0) and a generalized statistical mechanics grounded on the nonadditive entropic functional Sq(\pi\)=kΣi=1W pi q 1pi \;(q∈ R,\;S1=SBG), with q z =z1-q-11-q\; (z≥0,\;q∈R,\;1 z= z), satisfactorily handles such systems with q=1-1/. Furthermore, for this class, the size of the corresponding admissible phase space is characterized by q (xq y) =q x + q y,\, x,y≥1,\,q≤ 1, and the q-product xq y=[x1-q+y1-q-1]11-q+\;(x1 y=xy) also leads to the definition of a q-algebra. The entropic functional Sq,δ(\pi\)=kΣi=1W pi (q 1pi )δ\;(q∈R,δ>0) unifies both cases above: Sq,1=Sq, S1,δ=Sδ and S1,1=SBG. In this paper, we generalize the q-algebra associated with Sq to a new one associated with Sq,δ, namely the (q,δ)-algebra.