Bulgeless dwarf galaxies and dark matter cores from supernova-driven outflows

Abstract

For almost two decades the properties of 'dwarf' galaxies have challenged the cold dark matter (CDM) model of galaxy formation^1. Most observed dwarf galaxies consist of a rotating stellar disk^2 embedded in a massive dark-matter halo with a near-constant-density core^3. Models based on the dominance of CDM, however, invariably form galaxies with dense spheroidal stellar bulges and steep central dark-matter profiles^(4,5,6,) because low-angular-momentum baryons and dark matter sink to the centres of galaxies through accretion and repeated mergers^7. Processes that decrease the central density of CDM halos^8 have been identified, but have not yet reconciled theory with observations of present-day dwarfs. This failure is potentially catastrophic for the CDM model, possibly requiring a different dark-matter particle candidate^9. Here we report hydrodynamical simulations (in a framework^(10) assuming the presence of CDM and a cosmological constant) in which the inhomogeneous interstellar medium is resolved. Strong outflows from supernovae remove low-angular-momentum gas, which inhibits the formation of bulges and decreases the dark-matter density to less than half of what it would otherwise be within the central kiloparsec. The analogues of dwarf galaxies—bulgeless and with shallow central dark-matter profiles—arise naturally in these simulations.

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