Black hole in a generalized Chaplygin–Jacobi dark fluid: Shadow and light deflection angle

IF 5 2区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS
Mohsen Fathi , J.R. Villanueva , Gilberto Aguilar-Pérez , Miguel Cruz
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引用次数: 0

Abstract

We investigate a generalized Chaplygin-like gas with an anisotropic equation of state, characterizing a dark fluid within which a static spherically symmetric black hole is assumed. By solving the Einstein equations for this black hole spacetime, we explicitly derive the metric function. The spacetime is parametrized by two critical parameters, B and α, which measure the deviation from the Schwarzschild black hole and the extent of the dark fluid’s anisotropy, respectively. We explore the behavior of light rays in the vicinity of the black hole by calculating its shadow and comparing our results with the Event Horizon Telescope observations. This comparison constrains the parameters to 0B0.03 and 0<α0.1. Additionally, we calculate the deflection angles to determine the extent to which light is bent by the black hole. These calculations are further utilized to formulate possible Einstein rings, estimating the angular radius of the rings to be approximately 37.6μas. Throughout this work, we present analytical solutions wherever feasible, and employ reliable approximations where necessary to provide comprehensive insights into the spacetime characteristics and their observable effects.

广义 Chaplygin-Jacobi 暗流体中的黑洞:阴影与光偏转角
我们研究了一种具有各向异性状态方程的广义查普里金样气体,它是一种暗流体,内部假设有一个静态球对称黑洞。通过求解该黑洞时空的爱因斯坦方程,我们明确推导出了度量函数。该时空由两个临界参数和 ,分别度量与施瓦兹柴尔德黑洞的偏差和暗流体的各向异性程度。我们通过计算黑洞的阴影来探索光线在黑洞附近的行为,并将我们的结果与事件地平线望远镜的观测结果进行比较。通过比较,我们可以将参数约束为 和 。此外,我们还计算了偏转角,以确定光线被黑洞弯曲的程度。我们进一步利用这些计算来推算可能的爱因斯坦环,估计环的角半径大约为 。在整个研究过程中,只要可行,我们都会给出分析解,并在必要时采用可靠的近似值,以提供对时空特征及其可观测效应的全面见解。
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来源期刊
Physics of the Dark Universe
Physics of the Dark Universe ASTRONOMY & ASTROPHYSICS-
CiteScore
9.60
自引率
7.30%
发文量
118
审稿时长
61 days
期刊介绍: Physics of the Dark Universe is an innovative online-only journal that offers rapid publication of peer-reviewed, original research articles considered of high scientific impact. The journal is focused on the understanding of Dark Matter, Dark Energy, Early Universe, gravitational waves and neutrinos, covering all theoretical, experimental and phenomenological aspects.
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