Constraints on dark matter-neutrino scattering from the Milky-Way satellites and subhalo modeling for dark acoustic oscillations

Abstract

The elastic scattering between dark matter (DM) and radiation can potentially explain small-scale observations that the cold dark matter faces as a challenge, as damping density fluctuations via dark acoustic oscillations in the early universe erases small-scale structure. We study a semi-analytical subhalo model for interacting dark matter with radiation, based on the extended Press-Schechter formalism and subhalos' tidal evolution prescription. We also test the elastic scattering between DM and neutrinos using observations of Milky-Way satellites from the Dark Energy Survey and PanSTARRS1. We conservatively impose strong constraints on the DM-neutrino scattering cross section of σ DM-,n En (n=0,2,4) at 95\% confidence level (CL), σ DM-,0< 10-32\ cm2\ (m DM/ GeV), σ DM-,2< 10-43\ cm2\ (m DM/ GeV)(E/E0)2 and σ DM-,4< 10-54\ cm2\ (m DM/ GeV)(E/E0)4, where E is the neutrino energy and E0 is the average momentum of relic cosmic neutrinos today, E0 6.1\ K. By imposing a satellite forming condition, we obtain the strongest upper bounds on the DM-neutrino cross section at 95\% CL, σ DM-,0< 4× 10-34\ cm2\ (m DM/ GeV), σ DM-,2< 10-46\ cm2\ (m DM/ GeV)(E/E0)2 and σ DM-,4< 7× 10-59\ cm2\ (m DM/ GeV)(E/E0)4.