Black Holes with Global Monopoles in 4D Noncommutative Einstein Gauss Bonnet Gravity

TL;DR

This paper constructs and analyzes a novel four-dimensional noncommutative Einstein-Gauss-Bonnet black hole with a global monopole, exploring its horizon structure, thermodynamics, shadow, and quasinormal modes, revealing effects of noncommutativity and Gauss-Bonnet coupling.

Contribution

It presents the first exact spherically symmetric black hole solution with a global monopole in 4D noncommutative Einstein-Gauss-Bonnet gravity, including thermodynamic and shadow analyses.

Findings

Black hole can have two horizon configurations or none.

Hawking temperature and entropy are corrected by noncommutative and Gauss-Bonnet parameters.

Black hole shadow size decreases with increasing noncommutativity and Gauss-Bonnet coupling.

Abstract

In this work, we construct an exact spherically symmetric black hole solution with a global monopole in the context of four-dimensional noncommutative Einstein-Gauss-Bonnet gravity. We modeled the spacetime noncommutativity via a Lorentzian-smeared mass distribution. Then we study the horizon structure and find that this black hole can have two configurations: one degenerate horizon or no horizon, depending on the black hole parameters. We also analyze thermodynamics and thermal stability by computing the Hawking temperature, entropy, and heat capacity. Our analysis reveals that the Hawking temperature and entropy acquire corrections from the noncommutative parameter $\Theta$, the energy scale of symmetry breaking $\eta$, and the Gauss-Bonnet coupling constant $\alpha$. The heat capacity exhibits divergences that signal second-order phase transitions. Thereafter, we study the black hole shadow employing the null geodesics and the Hamiltonian-Jacobi equation. Our results show that the shadow decreases with increasing $\Theta$ or $\alpha$ and increases with increasing $\eta$. Finally, we analyze quasinormal modes or scalar perturbations, we compute them via the 6th-order WKB method, and compare them to the shadow radius methods in the eikonal limit.