Mergers Matter: Gravothermal Collapse in Dwarf Halos with Self-Interacting Dark Matter

Abstract

Self-Interacting Dark Matter (SIDM) models with large cross sections at relative velocities below 100\, km \, s-1 can be tested with dwarf galaxy observations. We analyze six dark-matter-only zoom-in 1010\, M halos with diverse assembly histories, adopting a cross section over mass of σ/m = 70\,cm2 \, g-1. We find that mergers inject orbital kinetic energy into the halo, altering the heat transport and the gravothermal evolution of the core. Three of the six halos -- those with the most quiescent merger histories -- show clear signs of core collapse in these simulations. Halos with sustained mergers do not collapse. Furthermore, merger-induced heat transport drives two non-collapsing halos to central densities well below the predictions of the gravothermal fluid model. These findings suggest a novel mechanism for producing dark-matter-deficient galaxies and expanding the diversity of rotation curves beyond what halo concentration alone predicts. Merger histories are thus essential for understanding central density distributions of dwarf galaxy halos in SIDM.