An analytic relation between the fractional parameter in the Mittag-Leffler function and the chemical potential in the Bose-Einstein distribution through the analysis of the NASA COBE monopole data

TL;DR

This paper introduces a fractional generalization of the Bose-Einstein distribution using Mittag-Leffler functions and analyzes COBE data to relate the fractional parameter to the chemical potential.

Contribution

It establishes a novel connection between the fractional parameter in the Mittag-Leffler function and the chemical potential in the Bose-Einstein distribution through cosmic microwave background data analysis.

Findings

Identifies an approximate relation p ≈ e^{-eru} between fractional parameter and chemical potential.

Derives a fractional Bose-Einstein distribution using Mittag-Leffler functions.

Analyzes COBE data to support the theoretical relation.

Abstract

To extend the Bose-Einstein (BE) distribution to fractional order, we turn our attention to the differential equation, $df/dx =-f-f^2$. It is satisfied with the stationary solution, $f(x)=1/(e^{x+\mu}-1)$, of the Kompaneets equation, where $\mu$ is the constant chemical potential. Setting $R=1/f$, we obtain a linear differential equation for $R$. Then, the Caputo fractional derivative of order $p$ ($p>0$) is introduced in place of the derivative of $x$, and fractional BE distribution is obtained, where function ${\rm e}^x$ is replaced by the Mittag-Leffler (ML) function $E_p(x^p)$. Using the integral representation of the ML function, we obtain a new formula. Based on the analysis of the NASA COBE monopole data, an identity $p\simeq e^{-\mu}$ is found.