克尔-纽曼黑洞轨道周期的下界

IF 4.8 2区物理与天体物理 Q2 PHYSICS, PARTICLES & FIELDS

The European Physical Journal C Pub Date : 2025-10-08 DOI:10.1140/epjc/s10052-025-14828-0

Yan Peng

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引用次数: 0

摘要

在克尔黑洞时空轨道周期研究的基础上，霍德推测了致密天体轨道周期的普遍下界的存在。在这项工作中，我们使用解析和数值方法对克尔-纽曼黑洞进行了测试。通过选择克尔-纽曼黑洞的不同电荷和自旋，我们建立了克尔-纽曼黑洞轨道周期的下界，表示为\(T(r)\geqslant 4\pi M\)，其中r为轨道半径，T(r)为从无穷远处观测到的轨道周期，M为黑洞质量。这个边界与霍德的猜想是一致的。此外，我们用数值方法证明了在无电荷情况下，下限是在克尔极限的极值处实现的。我们的发现支持了Hod推测的Kerr-Newman家族的下限。然而，它们并不能构成任意黑洞存在的普遍证据。

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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The lower bound on the orbital period of Kerr–Newman black holes

Based on studies of orbital periods in Kerr black hole spacetimes, Hod conjectured the existence of a universal lower bound on the orbital period for compact objects. In this work, we test this bound for Kerr–Newman black holes using both analytical and numerical methods. By choosing different charge and spin of Kerr–Newman black holes, we establish a lower bound on the orbital period for Kerr–Newman black holes expressed as \(T(r)\geqslant 4\pi M\), where r is the orbital radius, T(r) is the orbital period observed from infinity and M is the black hole mass. This bound is consistent with Hod’s conjecture. Moreover, we numerically demonstrate that the lower bound is achieved at the extreme Kerr limit in the absence of charge. Our findings support Hod’s conjectured lower bound within the Kerr–Newman family. However, they do not constitute a universal proof for arbitrary black holes.

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来源期刊

The European Physical Journal C 物理-物理：粒子与场物理

CiteScore

8.10

自引率

15.90%

发文量

1008

审稿时长

2-4 weeks

期刊介绍： Experimental Physics I: Accelerator Based High-Energy Physics Hadron and lepton collider physics Lepton-nucleon scattering High-energy nuclear reactions Standard model precision tests Search for new physics beyond the standard model Heavy flavour physics Neutrino properties Particle detector developments Computational methods and analysis tools Experimental Physics II: Astroparticle Physics Dark matter searches High-energy cosmic rays Double beta decay Long baseline neutrino experiments Neutrino astronomy Axions and other weakly interacting light particles Gravitational waves and observational cosmology Particle detector developments Computational methods and analysis tools Theoretical Physics I: Phenomenology of the Standard Model and Beyond Electroweak interactions Quantum chromo dynamics Heavy quark physics and quark flavour mixing Neutrino physics Phenomenology of astro- and cosmoparticle physics Meson spectroscopy and non-perturbative QCD Low-energy effective field theories Lattice field theory High temperature QCD and heavy ion physics Phenomenology of supersymmetric extensions of the SM Phenomenology of non-supersymmetric extensions of the SM Model building and alternative models of electroweak symmetry breaking Flavour physics beyond the SM Computational algorithms and tools...etc.