The tidal evolution of anisotropic subhaloes: a new pathway to creating isotropic and cored satellites
Journal
Monthly Notices of the Royal Astronomical Society
Journal Volume
544
Journal Issue
1
Start Page
36
End Page
52
ISSN
0035-8711
1365-2966
Date Issued
2025-09-26
Author(s)
Abstract
It is common practice, both in dynamical modelling and in idealized numerical simulations, to assume that galaxies and/or dark matter haloes are spherical and have isotropic velocity distributions, such that their distribution functions are ergodic. However, there is no good reason to assume that this assumption is accurate. In this paper we use idealized N-body simulations to study the tidal evolution of subhaloes that are anisotropic at infall. We show that the detailed velocity anisotropy has a large impact on the subhalo’s mass-loss rate. In particular, subhaloes that are radially anisotropic experience much more mass-loss than their tangentially anisotropic counterparts. In fact, in the former case, the stripping of highly radial orbits can cause a rapid cusp-to-core transformation, without having to resort to any baryonic feedback processes. Once the tidal radius becomes comparable to the radius of the core thus formed, the subhalo is tidally disrupted. Subhaloes that at infall are tangentially anisotropic are far more resilient to tidal stripping, and are never disrupted when simulated with sufficient resolution. We show that the preferential stripping of more radial orbits, combined with re-virialization post stripping, causes an isotropization of the subhalo’s velocity distributions. This implies that subhaloes that have experienced significant mass-loss are expected to be close to isotropic, which may alleviate the mass-anisotropy degeneracies that hamper the dynamical modelling of Milky Way satellites.
Subjects
dark matter
galaxies: haloes
galaxies: kinematics and dynamics
methods: numerical
Publisher
Oxford University Press (OUP)
Type
journal article