Galactic satellite systems in CDM, WDM and SIDM

We simulate the formation and evolution of the satellite system of haloes with masses within a factor of two of the Milky Way in cold, warm and self-interacting dark matter models (CDM, WDM & SIDM) using hydrodynamical simulations. We consider different baryonic physics models where supernovae gas blowouts are able or unable to flatten the density profiles of dwarf-scale haloes. These changes cause differences in the abundance and/or structural properties of field haloes relative to the fiducial hydrodynamical CDM simulation. In WDM, this is primarily a reduction of the total number of galaxies that form, due to a suppression of low mass DM haloes and lower galaxy formation efficiency. For SIDM, the only changes are structural and restricted to the central regions of haloes. Nonetheless, the inclusion of baryons suppresses the differences of density profiles relative to CDM. Consequently, the infall time properties of the satellites to-be are different across models, and thus their stripping and survival rate also differ. For SIDM, larger cross sections yield larger differences with respect to CDM. Versions in which cores form in CDM and WDM also show enhanced stripping. This leads to reductions in the total number of satellites above \(M_{*} \geq 10^{5}\) and lowered maximum circular velocity values at \(z=0\). The radial distribution functions are also affected, which are less concentrated in all SIDM models relative to CDM and WDM, regardless of whether the number of satellites is similar or lower.