Abstract
We study the impact of a warm dark matter (WDM) cosmology on dwarf galaxy formation through a suite of cosmological hydrodynamical zoom-in simulations of $M_{\rm halo} \approx10^{10}\,M_{\odot}$ dark matter halos as part of the Feedback in Realistic Environments (FIRE) project. A main focus of this paper is to evaluate the combined effects of dark matter physics and stellar feedback on the well-known small-scale issues found in cold dark matter (CDM) models. We find that the $z=0$ stellar mass of a galaxy is strongly correlated with the central density of its host dark matter halo at the time of formation, $z_{\rm f}$, in both CDM and WDM models. WDM halos follow the same $M_{\star}(z=0)-V_{\rm max}(z_{\rm f})$ relation as in CDM, but they form later, are less centrally dense, and therefore contain galaxies that are less massive than their CDM counterparts. As a result, the impact of baryonic effects on the central gravitational potential is typically diminished relative to CDM. However, the combination of delayed formation in WDM and energy input from stellar feedback results in dark matter profiles with lower overall densities. The WDM galaxies studied here have a wider diversity of star formation histories (SFHs) than the same systems simulated in CDM, and the two lowest $M_{\star}$ WDM galaxies form all of their stars at late times. The discovery of young ultra-faint dwarf galaxies with no ancient star formation -- which do not exist in our CDM simulations -- would therefore provide evidence in support of WDM.
Highlights
The leading class of dark matter particle candidates is phenomenologically ‘cold’, which is consistent with the weakly interacting massive particle (WIMP) paradigm, axion dark matter, and many other particle physics models
We study the impact of a warm dark matter (WDM) cosmology on dwarf galaxy formation through a suite of cosmological hydrodynamical zoom-in simulations of Mhalo ≈ 1010 M⊙ dark matter haloes as part of the Feedback in Realistic Environments (FIRE) project
We find that the z = 0 stellar mass of a galaxy is strongly correlated with the central density of its host dark matter halo at the time of formation, zf, in both cold dark matter (CDM) and WDM models
Summary
The leading class of dark matter particle candidates is phenomenologically ‘cold’, which is consistent with the weakly interacting massive particle (WIMP) paradigm, axion dark matter, and many other particle physics models. On smaller scales, comparing predictions of the CDM model from dark matter-only (DMO) simulations with observations of low-mass galaxies reveals several issues (Bullock & Boylan-Kolchin 2017). Those issues include the overprediction of low-mass subhaloes compared with counts of dwarf galaxies in the Local Group (Missing Satellites Problem – Klypin et al 1999; Moore et al 1999) and a mismatch of the predicted dark matter content of dark matter haloes and the dark matter. High-resolution hydrodynamical simulations of the Milky Way-mass haloes including these two components have reproduced a satellite stellar mass function that is consistent with observations down to M⋆ 105 M⊙ (Sawala et al 2016; Wetzel et al 2016)
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