J. M. Piotrowska, J. A. García, D. Walton, R. S. Beckmann, D. Stern, D. Ballantyne, D. R. Wilkins, S. Bianchi, P. Boorman, J. Buchner, C.-T. Chen, P. Coppi, T. Dauser, A. Fabian, E. Kammoun, K. Madsen, L. Mallick, G. Matt, G. Matzeu, E. Nardini, A. Pizzetti, S. Puccetti, C. Ricci, F. Tombesi, N. Torres-Albà, K.-W. Wong
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引用次数: 0
摘要
制约超大质量黑洞(SMBHs)的主要生长通道仍然是宇宙学结构形成方面争论最激烈的问题之一。由于超大质量黑洞自旋参数演化与单个黑洞的吸积和合并历史之间的预期联系,群体自旋测量为了解超大质量黑洞的宇宙成长提供了一个难得的观测窗口。到目前为止,估算 SMBH 自旋最常用的方法是对 X 射线反射光谱中相对论拓宽的原子轮廓进行建模。在本文中,我们研究了根据 Horizon-AGN 宇宙学模拟预测的不同自旋-质量分布,有把握地区分主要 SMBH 生长通道所需的观测条件。在此过程中,我们描述了与现有测量相关的突出局限性,并讨论了未来 X 射线天文台可以计划和执行的未来观测活动的前景。我们将注意力集中在高能 X 射线探测器(HEX-P)上,这是一项拟议中的探测器级任务,旨在 2030 年代为高能界服务。
The high energy X-ray probe (HEX-P): constraining supermassive black hole growth with population spin measurements
Constraining the primary growth channel of supermassive black holes (SMBHs) remains one the most actively debated questions in the context of cosmological structure formation. Owing to the expected connection between SMBH spin parameter evolution and the accretion and merger history of individual black holes, population spin measurements offer a rare observational window into the cosmic growth of SMBHs. As of today, the most common method for estimating SMBH spin relies on modeling the relativistically broaden atomic profiles in the reflection spectrum observed in X-rays. In this paper, we study the observational requirements needed to confidently distinguish between the primary SMBH growth channels based on their distinct spin-mass distributions predicted by the Horizon-AGN cosmological simulation. Indoing so, we characterize outstanding limitations associated with the existing measurements and discuss the landscape of future observational campaigns which could be planned and executed with future X-ray observatories. We focus our attention on the High-Energy X-ray Probe (HEX-P), a proposed probe-class mission designed to serve the high-energy community in the 2030s.
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