Growth of accreting intermediate mass black hole seeds

Communications of the Byurakan Astrophysical Observatory Pub Date : 2022-09-02 DOI:10.52526/25792776-22.69.1-47

G. Ter-Kazarian

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Abstract

This communication aims to review the mass assembly history of seed black holes to the present time of accreting intermediate mass black hole (IMBH)-candidates. Given the masses and redshifts at present time of 137 IMBH-candidates collected from the literature, we have undertaken a large series of numerical simulations to achieve this goal. The crux is that, we utilize the microscopic theory of black hole (MTBH), which explores the most important novel aspects expected from considerable change of properties of spacetime continuum at spontaneous breaking of gravitation gauge symmetry far above nuclear density. As a corollary, this theory has smeared out the central singularities of BHs, and makes room for their growth and merging behavior. We compute among the others the masses, the growth-time scales, TBH, and the redshifts of seed BHs. In particular, for the present masses log(M/[M⊙]) = 2.20 to 5.99 of IMBH-candidates, the computed seed masses are ranging from log(Mseed/[M⊙]) = −0.50 to 3.29, with corresponding growth-time scales TBH ranging from log(TBH/[yr]) = 8.82 to 10.09. We derived scaling mass-luminosity relation, by means of which we compute the luminosities of IMBH-candidates ranging from log(L/[erg s−1 ]) = 39.13 to 41.653.

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吸积中等质量黑洞种子的生长

本通讯旨在回顾种子黑洞的质量聚集历史，直到现在的吸积中质量黑洞(IMBH)候选者。考虑到目前从文献中收集到的137颗imbh候选者的质量和红移，我们进行了大量的数值模拟来实现这一目标。关键在于，我们利用了黑洞的微观理论(mthh)，该理论从远高于核密度的引力规范对称自发破溃时时空连续体性质的显著变化中探索了最重要的新方面。作为必然结果，这一理论抹去了黑洞的中心奇点，为它们的成长和合并行为腾出了空间。我们计算了质量、生长时间尺度、TBH和种子黑洞的红移。特别地，对于目前质量log(M/[M⊙])= 2.20 ~ 5.99的imbh -候选者，计算得到的种子质量范围为log(M种子/[M⊙])= - 0.50 ~ 3.29，相应的生长时间尺度TBH范围为log(TBH/[yr]) = 8.82 ~ 10.09。我们推导了标度质量-光度关系，通过该关系我们计算了候选imbh的光度，范围为log(L/[erg s−1])= 39.13 ~ 41.653。

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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Communications of the Byurakan Astrophysical Observatory

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