A new special function related to a discrete Gauss-Poisson distribution and some physics of the cell model with Curie-Weiss interactions

Abstract

Inspired by previous studies in statistical physics [see, in particular, Kozitsky at al., A phase transition in a Curie-Weiss system with binary interactions, Condens. Matter Phys. 23, 23502 (2020)] we introduce a discrete Gauss-Poisson probability distribution function equationGPDA1 pGP(n ;z,r)=[R(r;z)]-1eznn!\,e- 12\,rn2 equation with support on N0 and parameters z∈ R and r∈ R+. The probability mass function pGP(n ;z,r) is normalized by the special function R(r;z), given by the infinite sum equationRA2 R(r;z)=Σn=0∞eznn!\,e- 12\,rn2, equation possessing extremely intersting mathematical properties. We present an asymptotic estimate R( as)(r;z1) for the function R(r;z) with large arguments z, along with similar formulas for its logarithm and logarithmic derivative. These functions exhibit very interesting oscillatory behavior around their asymptotics, for parameters r above some threshold value r*. Some implications of our findings are discussed in the context of the Curie-Weiss cell model of simple fluids.

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