Physical Processes Behind the Co-Evolution of Halos, Galaxies and Supermassive Black Holes in the IllustrisTNG Simulation

arXiv - PHYS - Astrophysics of Galaxies Pub Date : 2024-09-10 DOI:arxiv-2409.06208

Hao Li, Yangyao Cheng, Huiyuan Wang, Houjun Mo

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Abstract

We explore the co-evolution of dark matter halos, their central galaxies, and central supermassive black holes (SMBHs) using the IllustrisTNG (TNG) simulation. We find that the evolutionary histories of individual galaxies in the $M_{\rm BH}$-$M_*$ plane can be decomposed into four distinct phases, separated by three transition points. We identify the driving processes of galaxy evolution within each phase and derive the conditions necessary and sufficient for transitions to subsequent phases. The first phase is dominated by star formation, with its duration primarily determined by the mass of the SMBH seed and the surrounding gas environment. The second phase is characterized by rapid SMBH growth, and the transition to the next phase occurs when the thermal-mode feedback of active galactic nucleus (AGN) can unbind gas from the galaxy. The third phase involves self-regulation of the SMBH, and the transition to the quenched phase occurs when the kinetic-mode feedback of AGN counterbalances gas cooling within the subhalo. The final phase is dominated by mergers. We investigate the use of scaling relations among different mass components and evolutionary phases to understand processes implemented in TNG and other simulations, and discuss how current and forthcoming observations can be used to constrain models.

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IllustrisTNG模拟中晕、星系和超大质量黑洞共同演化背后的物理过程

我们利用IllustrisTNG（TNG）模拟探索了暗物质光环、其中心星系和中心超大质量黑洞（SMBHs）的共同演化过程。我们发现，在$M_{\rm BH}$-$M_*$ 平面上，单个星系的演化历史可以分解成四个不同的阶段，中间有三个过渡点。我们确定了每个阶段中星系演化的驱动过程，并推导出过渡到后续阶段的必要和充分条件。第一阶段以恒星形成为主，其持续时间主要取决于SMBH种子的质量和周围的气体环境。第二阶段的特征是 SMBH 的快速增长，当活动星系核（AGN）的热模式反馈能够从星系中释放出气体时，就会过渡到下一阶段。第三阶段涉及 SMBH 的自我调节，当 AGN 的动模反馈抵消了亚halo 内的气体冷却时，就过渡到了淬火阶段。最后一个阶段是由并合主导的。我们研究了如何利用不同质量成分和演化阶段之间的比例关系来理解 TNG 和其他模拟中实现的过程，并讨论了如何利用当前和即将进行的观测来约束模型。

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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arXiv - PHYS - Astrophysics of Galaxies

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