Schwarzschild black hole surrounded by a cavity and phase transition in the non-commutative gauge theory of gravity

IF 4.2 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Astroparticle Physics Pub Date : 2024-05-16 DOI:10.1016/j.astropartphys.2024.102988

Abdellah Touati, Slimane Zaim

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Abstract

In this work, we investigate the phase transition of the Schwarzschild black hole (SBH) inside an isothermal spherical cavity in the context of the non-commutative (NC) gauge theory of gravity, by using the Seiberg–Witten (SW) map and the star product. Firstly, we compute the NC correction to the Hawking temperature and derive the logarithmic correction to the entropy, then we derive the local temperature and local energy of NC SBH in isothermal cavity. Our results show that the non-commutativity removes the commutative divergence behavior of temperature, and prevents the SBH from the complete evaporation, which leads to a remnant black hole, and this geometry has predicted a minimal length in the order of Planck scale $Θ \sim l_{p l a n c k}$ . Therefore, the thermodynamic stability and phase transition is studied by analyzing the behavior of the local heat capacity and the Helmholtz free energy in the NC spacetime, where the results show that, the NC SBH has a two second-order phase transition and one first-order phase transition, with two Hawking–Page phase transition in the NC gauge theory.

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被空腔包围的施瓦兹柴尔德黑洞与非交换引力规理论中的相变

在这项研究中，我们在非交换（NC）引力规理论的背景下，利用塞伯格-维滕（Seiberg-Witten，SW）图和星积研究了等温球腔内施瓦兹柴尔德黑洞（Schwarzschild black hole，SBH）的相变。首先，我们计算了霍金温度的NC修正，并推导了熵的对数修正，然后推导了NC SBH在等温腔中的局部温度和局部能量。我们的结果表明，非交换性消除了温度的交换发散行为，阻止了SBH的完全蒸发，从而导致了残余黑洞，而且这种几何预言了普朗克尺度Θ∼lplanck数量级的最小长度。因此，通过分析数控时空中的局域热容和亥姆霍兹自由能的行为，研究了数控 SBH 的热力学稳定性和相变，结果表明，数控 SBH 有两个二阶相变和一个一阶相变，在数控规理论中有两个霍金-帕格相变。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astroparticle Physics 地学天文-天文与天体物理

CiteScore

8.00

自引率

2.90%

发文量

审稿时长

79 days

期刊介绍： Astroparticle Physics publishes experimental and theoretical research papers in the interacting fields of Cosmic Ray Physics, Astronomy and Astrophysics, Cosmology and Particle Physics focusing on new developments in the following areas: High-energy cosmic-ray physics and astrophysics; Particle cosmology; Particle astrophysics; Related astrophysics: supernova, AGN, cosmic abundances, dark matter etc.; Gravitational waves; High-energy, VHE and UHE gamma-ray astronomy; High- and low-energy neutrino astronomy; Instrumentation and detector developments related to the above-mentioned fields.