The no-spin zone: rotation vs dispersion support in observed and simulated dwarf galaxies

Abstract

We perform a systematic Bayesian analysis of rotation vs. dispersion support (v rot / σ) in 40 dwarf galaxies throughout the Local Volume (LV) over a stellar mass range 103.5 M < M < 108 M . We find that the stars in 80\% of the LV dwarf galaxies studied -- both satellites and isolated systems -- are dispersion-supported. In particular, we show that 6/10 *isolated* dwarfs in our sample have v rot / σ < 1.0. All have v rot / σ 2.0. These results challenge the traditional view that the stars in gas-rich dwarf irregulars (dIrrs) are distributed in cold, rotationally-supported stellar disks, while gas-poor dwarf spheroidals (dSphs) are kinematically distinct in having dispersion-supported stars. We see no clear trend between v rot / σ and distance to the closest L galaxy, nor between v rot / σ and M within our mass range. We apply the same Bayesian analysis to four FIRE hydrodynamic zoom-in simulations of isolated dwarf galaxies (109 M < M vir < 1010 M ) and show that the simulated *isolated* dIrr galaxies have stellar ellipticities and stellar v rot / σ ratios that are consistent with the observed population of dIrrs *and* dSphs without the need to subject these dwarfs to any external perturbations or tidal forces. We posit that most dwarf galaxies form as puffy, dispersion-dominated systems, rather than cold, angular momentum-supported disks. If this is the case, then transforming a dIrr into a dSph may require little more than removing its gas.