The Local Group on FIRE: Dwarf galaxy populations across a suite of hydrodynamic simulations

TL;DR

This study uses high-resolution hydrodynamic simulations to explore dwarf galaxy populations in the Local Group, finding no evidence for the missing satellites or TBTF problems and predicting several undiscovered galaxies.

Contribution

First to apply FIRE physics to both LG-like and isolated MW-like volumes, providing detailed predictions for dwarf galaxy populations and their properties.

Findings

Reproduces stellar mass function and densities of MW satellites for M* ≥ 10^5.5 M_sun.

Predicts ~3 undiscovered satellites with M* ~10^5 M_sun within 300 kpc of MW.

Finds no classical missing satellites or TBTF problems in the simulations.

Abstract

We present a new set of high-resolution hydrodynamic cosmological zoom-in simulations that apply the Feedback In Realistic Environments (FIRE) physics to both Local Group (LG)-like and isolated Milky Way (MW)-like volumes (ten host systems in total with baryonic particle mass $\simeq 3,500-7,000\,M_\odot$). We study the stellar mass functions, circular velocity or mass profiles, and velocity dispersions of the dwarf galaxy populations. The simulations reproduce the stellar mass function and central densities of MW satellite dwarfs for $M_\ast \geq10^{5.5}\,M_\odot$ and predict the existence of $\sim3$ unidentified galaxies with $M_\ast\sim10^5\,M_\odot$ within $300$ kpc of the MW. Overall, we find no evidence for the classical missing satellites or too-big-to-fail (TBTF) problems for satellite galaxies in our sample. Among the satellites, TBTF is resolved primarily by subhalo disruption and overall mass loss; central density profiles of subhalos are of secondary importance. For non-satellite galaxies, our LG-like simulations predict as many as $\sim10$ as-of-yet unseen galaxies at distances $0.3-1$ Mpc from both hosts, with $M_\ast\simeq10^{5-6}\,M_\odot$ (in halos with $V_\mathrm{max}\sim 20~\mathrm{km\,s}^{-1}$), albeit with large halo-to-halo variance. None of our simulations produces a compact, baryon-dominated, high-density dwarf elliptical-type galaxy (with $V_\mathrm{circ} \gtrsim 35~\mathrm{km\,s}^{-1}$ at $r<1\,$kpc), of which six may appear in the LG (but none in the MW). It may therefore remain a challenge to reproduce the full diversity of the dwarf population, including both the highest and lowest density systems.