Gauss-Bonnet black holes supported by a nonlinear electromagnetic field

TL;DR

This paper investigates higher-dimensional Gauss-Bonnet black holes coupled with nonlinear electromagnetic fields, revealing diverse behaviors and structures depending on dimensions, parameters, and cosmological constants, extending previous specific cases.

Contribution

It provides a comprehensive analysis of charged Gauss-Bonnet black holes with nonlinear electrodynamics in various dimensions and cosmological backgrounds, introducing new explicit solutions and classifications.

Findings

Different metric behaviors in 5D and higher dimensions.

Existence of solutions with or without branch singularities.

New structures in AdS and dS spaces with non-zero cosmological constant.

Abstract

We study $D$-dimensional charged static spherically symmetric black hole solutions in Gauss-Bonnet theory coupled to nonlinear electrodynamics defined as arbitrary functions of the field invariant and constrained by several physical conditions. These solutions are characterized in terms of the mass parameter $m$, the electromagnetic energy $\varepsilon$ and the Gauss-Bonnet parameter $l_{\alpha}^2$. We find that a general feature of these solutions is that the metric behaves in a different way in $D=5$ and $D>5$ space-time dimensions. Moreover, such solutions split into two classes, according to whether they are defined everywhere or show branch singularities, depending on ($m, \varepsilon, l_{\alpha}^2$). We describe qualitatively the structures comprised within this scenario, which largely extends the results obtained in the literature for several particular families of nonlinear electrodynamics. An explicit new example, illustrative of our results, is introduced. Finally we allow non-vanishing values of the cosmological constant length $l_{\Lambda}^2$, and study the existence of new structures, in both asymptotically Anti-de Sitter and de Sitter spaces.