Four $\mathbb{S}\mathbb{T}\mathbb{U}$ Black Holes Shadows

TL;DR

This paper investigates the optical shadows and thermodynamic phases of four $ ext{STU}$ black holes, revealing how charge configurations influence shadow size, evaporation rates, and phase transitions, with implications for observational constraints.

Contribution

It introduces a detailed analysis of shadow geometries and phase structures for $ ext{STU}$ black holes, highlighting novel effects of charge parameters on black hole evolution and observable features.

Findings

Shadow size depends on electric charge and parameter space.

Charge and parameter space influence energy emission rate.

Phase transition correlates with shadow and horizon radii.

Abstract

In this work, we examine the optical behaviors and thermodynamic phase structures using shadow analysis for four $\mathbb{S}\mathbb{T}\mathbb{U}$ black holes. The study is conducted for four cases of charge configurations on the parameter space $\mathcal{M}\left(q_1,q_2,q_3,q_4\right)$. As a matter of fact, both the electric charge as a parameter and the parameter space $\mathcal{M}\left(q_1,q_2,q_3,q_4\right)$ affect the geometry of the black hole shadow, particularly the size of the shadow. We also introduce a constraint on the charge of the black hole from the observational results of the M87$^\star$ {\color{black}and Sgr A$^\star$} shadow. Furthermore, we show that the electric charge and the parameter space $\mathcal{M}\left(q_1,q_2,q_3,q_4\right)$ have a non-trivial impact on the variation of the energy emission rate. Interestingly enough, we find novel scenarios in which the evaporation is slower, which causes the lifetime of the black holes to be considerably elongated. On the other side, the phase structure of four $\mathbb{S}\mathbb{T}\mathbb{U}$ black holes is explored for two cases of electric charge configuration. The findings show a perfect correlation between the shadow and event horizon radii. This correlation is, in fact, helpful in discovering the phase transition in terms of the shadow radius. In addition, the microstructure is being analyzed in terms of shadow analysis, providing similar behavior to the ordinary situation of the Ruppeiner formalism.