Penarrubia, Jorge

Ferguson, Annette

Errani, Raphaël

2019-12-20T11:45:03Z

2019-12-20T11:45:03Z

2019-11-07

Understanding the distribution of dark matter (DM) on galactic scales is at the root of constraining the nature of DM and processes of galaxy formation like baryonic feedback. Dwarf spheroidal galaxies (dSphs), lying at the faintest end of the galaxy luminosity function, are the most DM dominated systems known to date. They are a promising candidates to probe the DM distribution on kpc scales. In this work, we study the tidal evolution, abundance and observable properties of dSphs embedded in DM subhaloes. Tidal evolution of subhaloes and dwarf galaxies We run controlled simulations of the tidal evolution of a single cold dark matter subhalo with a centrally-divergent density cusp, tailored to follow the evolution of the subhalo for arbitrarily large fractions of tidally stripped mass. Based on simple dynamical arguments and numerical experiments, we argue that cuspy DM subhaloes cannot be completely disrupted by smooth tidal fields. Using a model of the Tucana III dSph galaxy as an example, we show that tides can strip dSph galaxies down to sub-solar luminosities. The remnant micro-galaxies would appear as co-moving groups of metal-poor, low-mass stars of similar age, embedded in sub-kpc DM subhaloes. Subhalo depletion driven by the galactic disc To further quantify the abundance of subhaloes in Milky Way-like galaxies containing a galactic disc, we use high-resolution re-simulations of all subhaloes of the Aquarius A2 merger tree with masses M > 10^8 Msol at accretion. We model the tidal evolution of subhaloes with both cuspy and cored DM profiles, finding that cuspy models have twice as many surviving subhaloes within the virial radius of the host at redshift z=0 as their cored counterparts. The presence of a galactic disc reduces the number of surviving subhaloes further by a factor of < 2 for subhaloes on orbits that pass through the disc. Mass estimates for Milky Way dwarf galaxies With the aim of comparing observed properties of Milky Way dSph galaxies to simulations, we construct an estimator for enclosed masses based on the virial theorem, insensitive to anisotropy in the velocity dispersion and tailored to yield masses with minimum uncertainty introduced by our ignorance on (i) the shape of the inner DM profile, and (ii) how deeply the stellar component is embedded within the subhalo. Tests against controlled simulations show that the estimator provides unbiased masses with an accuracy of ~10 per cent. Application to published kinematic data of Milky Way dSph galaxies reveals a tight correlation between enclosed mass and luminosity. Comparison against cuspy and cored DM haloes extracted from controlled cosmological simulations shows that the high mass densities of ultrafaint galaxies are not compatible with large DM cores, and that the (total) halo masses of the classical Milky Way dSph galaxies span a remarkably narrow range (8 < log10 M/Msol < 10) at present, showing no clear trend with either galaxy size or luminosity.

https://hdl.handle.net/1842/36662

en

The University of Edinburgh

Errani R., Peñarrubia J., 2019, arXiv e-prints, arXiv:1906.01642

Errani R., Peñarrubia J., Tormen G., 2015, MNRAS, 449, L46

Errani R., Peñarrubia J., Laporte C. F. P., Gómez F. A., 2017, MNRAS, 465, L59

Errani R., Peñarrubia J., Walker M. G., 2018, MNRAS, 481, 5073

dark matter

subhaloes

haloes

dwarf spheroidal galaxies

gravity

centrally-divergent density

Tidal evolution of dwarf spheroidal galaxies and dark matter subhalos

Thesis or Dissertation

Doctoral

PhD Doctor of Philosophy