Warm, not Fuzzy: Generalized Ultralight Dark Matter Limits from Milky Way Satellites

Abstract

We generalize lower limits on the dark matter (DM) particle mass m derived from Milky Way (MW) satellite galaxy abundances to scenarios in which DM is an ultralight scalar field produced with a field power spectrum peaked at a subhorizon wavenumber k*. In these models, the DM field free-streams similar to warm dark matter while also exhibiting significant small-scale wave interference effects. The resulting dimensionless density power spectrum shows two effects: (i) free-streaming suppression at k fs k eq/[(k*/a eqm)(a eqm/k*)]; (ii) Poisson-like enhancement related to wave interference, at k10-2k*, which saturates near the Jeans scale k J k eq/(k*/a eqm). Comparing these predictions with established constraints on a free-streaming cutoff in the linear matter power spectrum from the MW satellite population, we obtain m>6×10-18\, eV\,(k*/104\, Mpc-1) for k*>104\, Mpc-1 at 95\% confidence. For smaller k*, Poisson-noise enhancement on MW satellite scales weakens the constraint, yielding m>6×10-18\, eV\,(k*/104\, Mpc-1)2 for k*<104\, Mpc-1 at 95\% confidence.