Topological Insights into Black Hole Thermodynamics: Non-Extensive Entropy in CFT framework

Abstract

In this paper, We conducted an in-depth investigation into the thermodynamic topology of Einstein-Gauss-Bonnet black holes within the framework of Conformal Field Theory (CFT), considering the implications of non-extensive entropy formulations. Our study reveals that the parameter λ (R\'enyi entropy) plays a crucial role in the phase behavior of black holes. Specifically, when λ is below the critical value (C), it has a negligible impact on the phase behavior. However, when λ exceeds the critical value, it significantly alters the phase transition outcomes. Determining the most physically representative values of λ will require experimental validation, but this parameter flexibility allows researchers to better explain black hole phase transitions under varying physical conditions. Furthermore, the parameters α and β affect the phase structure and topological charge for the Sharma-Mittal entropy. Only in the case of C>Cc and in the condition of α≈β will we have a first-order phase transition with topological charge + 1. Additionally, for the loop quantum gravity non-extensive entropy as the parameter q approaches 1, the classification of topological charges changes. We observe configurations with one and three topological charges with respect to critical value C, resulting in a total topological charge W = +1, and configurations with two topological charges (ω = +1, -1), leading to a total topological charge W = 0. These findings provide new insights into the complex phase behavior and topological characteristics of black holes in the context of CFT and non-extensive entropy formulations.