Sweating the small stuff: simulating dwarf galaxies, ultra-faint dwarf galaxies, and their own tiny satellites

Abstract

We present FIRE/Gizmo hydrodynamic zoom-in simulations of isolated dark matter halos, two each at the mass of classical dwarf galaxies (M vir 1010 M) and ultra-faint galaxies (M vir 109 M), and with two feedback implementations. The resultant central galaxies lie on an extrapolated abundance matching relation from M 106 to 104 M without a break. Every host is filled with subhalos, many of which form stars. Our dwarfs with M 106 M each have 1-2 well-resolved satellites with M = 3-200 × 103 M. Even our isolated ultra-faint galaxies have star-forming subhalos. If this is representative, dwarf galaxies throughout the universe should commonly host tiny satellite galaxies of their own. We combine our results with the ELVIS simulations to show that targeting 50~ kpc regions around nearby isolated dwarfs could increase the chances of discovering ultra-faint galaxies by 35\% compared to random halo pointings, and specifically identify the region around the Phoenix dwarf galaxy as a good potential target. The well-resolved ultra-faint galaxies in our simulations (M 3 - 30 × 103 M) form within M peak 0.5 - 3 × 109 M halos. Each has a uniformly ancient stellar population ( > 10~ Gyr) owing to reionization-related quenching. More massive systems, in contrast, all have late-time star formation. Our results suggest that M halo 5 × 109 M is a probable dividing line between halos hosting reionization "fossils" and those hosting dwarfs that can continue to form stars in isolation after reionization.