The evolving role of astrophysical modelling in dark matter halo relaxation response

Premvijay Velmani, Aseem Paranjape
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Abstract

We study the change in the radial distribution of dark matter within haloes in response to baryonic astrophysical processes in galaxies at different epochs, investigating the role of astrophysical modeling in cosmological hydrodynamic simulations in producing the response. We find that the linear quasi-adiabatic relaxation with additional dependence on the halo-centric distance provides a good description not only at $z=0$, but also at an earlier epoch ($z=1$) in the IllustrisTNG simulation suite, with parameters being more universal across a much larger variety of haloes at $z=1$ than at $z=0$. Through systematic analysis of a large collection of simulations from the CAMELS project, we find that the baryonic prescriptions for both AGN and stellar feedbacks have a strong influence on the relaxation response of the dark matter halo. In particular, only the parameters controlling the overall feedback energy flux have an effect on the relaxation response, while the wind speed and burstiness have negligible effect on the relaxation at a fixed amount of energy flux. However, the exact role of these parameters on the relaxation depends on the redshift. We also study the role of a variety of baryonic astrophysical processes through the EAGLE physics variation simulations. While these depict a similar picture regarding the importance of feedback effects, they also reveal that the gas equation of state has one of the strongest influences on the relaxation response, consistent with the expectation from self-similar analyses.
天体物理建模在暗物质晕弛豫响应中不断演变的作用
我们研究了不同时点星系中暗物质在光环内径向分布的变化对重子天体物理过程的响应,研究了宇宙流体力学模拟中的天体物理建模在产生响应中的作用。我们发现,在IllustrisTNG模拟套件中,线性类绝热弛豫(linearquasi-adiabatic relaxation)附加了对光环中心距离的依赖,不仅在$z=0$时提供了良好的描述,而且在早期($z=1$)也提供了良好的描述,在$z=1$时比在$z=0$时参数在更多的光环中更为普遍。通过对CAMELS项目的大量模拟进行系统分析,我们发现AGN和恒星反馈的重子参数对暗物质晕的弛豫响应有很大影响。特别是,只有控制总体反馈能量通量的参数才会对弛豫响应产生影响,而风速和爆发度在固定能量通量下对弛豫的影响可以忽略不计。然而,这些参数对弛豫的确切作用取决于红移。我们还通过 EAGLE 物理变异模拟研究了各种重子物理过程的作用。虽然这些模拟在反馈效应的重要性方面描述了类似的情况,但也揭示出气体状态方程对弛豫响应的影响是最强的,这与自相似分析的预期是一致的。
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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