How Do the Velocity Anisotropies of Halo Stars, Dark Matter, and Satellite Galaxies Depend on Host Halo Properties?

We investigate the mass ( M 200 ) and concentration ( c 200 ) dependencies of the velocity anisotropy ( β ) profiles for different components in the dark matter halo—including halo stars, dark matter, and subhalos—using systems from the IllustrisTNG simulations. Beyond a critical radius, β becomes m...

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Bibliographic Details
Published in:The Astrophysical journal 2024-12, Vol.976 (2), p.187
Main Authors: He, Jiaxin, Wang, Wenting, Li, Zhaozhou, Han, Jiaxin, Rodriguez-Gomez, Vicente, Zhao, Donghai, Meng, Xianguang, Jing, Yipeng, Shao, Shi, Shi, Rui, Tan, Zhenlin
Format: Article
Language:English
Subjects:
Anisotropy
Dark matter
Galactic halos
Galaxies
Galaxy dark matter halos
Galaxy stellar halos
Hydrodynamical simulations
Milky Way stellar halo
N-body simulations
Stars
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Summary:We investigate the mass ( M 200 ) and concentration ( c 200 ) dependencies of the velocity anisotropy ( β ) profiles for different components in the dark matter halo—including halo stars, dark matter, and subhalos—using systems from the IllustrisTNG simulations. Beyond a critical radius, β becomes more radial with the increase of M 200 , reflecting more prominent radial accretion around massive halos. The critical radius is r ∼ r s , 0.3 r s , and r s for halo stars, dark matter, and subhalos, with r s being the scale radius of the host halos. This dependence on M 200 is the strongest for subhalos and the weakest for halo stars. In central regions, the β of halo stars and dark matter particles get more isotropic with the increase of M 200 in TNG300 due to baryons. By contrast, the β of dark matter from the dark-matter-only TNG300-Dark run shows much weaker dependence on M 200 within r s . Dark matter in TNG300 is slightly more isotropic than in TNG300-Dark at 0.2 r s < r < 10 r s and log 10 M 200 / M ⊙ < 13.8 . Halo stars and dark matter also become more radial with the increase in c 200 , at fixed M 200 . Halo stars are more radial than the β profile of dark matter by approximately a constant beyond r s . Dark matter particles are more radial than subhalos. The differences can be understood, as subhalos on more radial orbits are more easily stripped, contributing more stars and dark matter to the diffuse components. We provide the fitting formula for the differences between the β of halo stars and dark matter at r s < r < 3 r s as β star − β DM = ( − 0.034 ± 0.012 ) log 10 M 200 / M ⊙ + ( 0.772 ± 0.163 ) for log 10 M 200 / M ⊙ ≥ 13 and as β star − β DM = 0.328 for log 10 M 200 / M ⊙ < 13 .
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ad8882