论静态紧凑物体形成过程中的最大能量释放

IF 3.2 Q2 ASTRONOMY & ASTROPHYSICS

Galaxies Pub Date : 2023-11-21 DOI:10.3390/galaxies11060116

Abhas Mitra, Krishna Kumar Singh

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引用次数: 0

摘要

1987年观测到的II型超新星1987A（SN 1987A）释放了Q≈3×1053 erg的能量。这个巨大的能量基本上相当于一颗新诞生的冷中子星的引力势能或自引力能量（PE）的大小，这颗中子星的引力紧密度或红移zb≈0.15。人们可能想知道，形成任意高 zb 的冷超紧密天体（UCO）时可能释放的能量上限是多少。因此，在这里，我们首次获得了均质广义相对论 UCO 的 PE 的分析表达式，假设它是冷的和静态的。结果发现，质量为 M 的均质 UCO 的 PE 可能超过 Mc2，最大可达 1.34 Mc2。这一结果虽然令人惊讶，但却是基于标准广义相对论 (GTR) 的精确和正确的分析计算得出的。此外，由切向应力支撑的 UCO 可能是不均匀的，其质量比 PE ∼ 2.1 Mc2 的中子星大得多，因此，原则上，形成几个太阳质量（M⊙）的 UCO 可能会释放出 Q∼1055 erg 的能量。

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On the Maximum Energy Release from Formation of Static Compact Objects

Type II Supernova 1987A (SN 1987A), observed in 1987, released an energy of Q≈3×1053 erg. This huge energy is essentially the magnitude of gravitational potential or self-gravitational energy (PE) of a new born cold neutron star having a gravitational compactness or redshift zb≈0.15. One may wonder what could be the upper limit on the amount of energy that might be released with the formation of a cold Ultra Compact Object (UCO) with an arbitrary high zb. Accordingly, here, for the first time, we obtain an analytical expression for the PE of a homogeneous general relativistic UCO assuming it to be cold and static. It is found that the PE of a homogeneous UCO of mass M may exceed Mc2 and be as large as 1.34 Mc2. This result, though surprising, follows from an exact and correct analytical calculation based on the standard General Theory of Relativity (GTR). Further, UCOs supported by tangential stresses may be inhomogeneous and much more massive than neutron stars with PE ∼ 2.1 Mc2 Thus, in principle, formation of an UCO of a few solar masses (M⊙) might release an energy Q∼1055 erg.

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来源期刊

Galaxies Physics and Astronomy-Astronomy and Astrophysics

CiteScore

4.90

自引率

12.00%

发文量

100

审稿时长

11 weeks

期刊介绍： Es una revista internacional de acceso abierto revisada por pares que proporciona un foro avanzado para estudios relacionados con astronomía, astrofísica y cosmología. Areas temáticas Astronomía Astrofísica Cosmología Astronomía observacional: radio, infrarrojo, óptico, rayos X, neutrino, etc. Ciencia planetaria Equipos y tecnologías de astronomía. Ingeniería Aeroespacial Análisis de datos astronómicos. Astroquímica y Astrobiología. Arqueoastronomía Historia de la astronomía y cosmología. Problemas filosóficos en cosmología.