Using CMB spectral distortions to distinguish between dark matter solutions to the small-scale crisis

Abstract

The dissipation of small-scale perturbations in the early universe produces a distortion in the blackbody spectrum of cosmic microwave background photons. In this work, we propose to use these distortions as a probe of the microphysics of dark matter on scales 1\,Mpc-1 k 104\,Mpc-1. We consider in particular models in which the dark matter is kinetically coupled to either neutrinos or photons until shortly before recombination, and compute the photon heating rate and the resultant μ-distortion in both cases. We show that the μ-parameter is generally enhanced relative to for interactions with neutrinos, and may be either enhanced or suppressed in the case of interactions with photons. The deviations from the signal are potentially within the sensitivity reach of a PRISM-like experiment if σDM-γ 1.1×10-30 (mDM/GeV) cm2 and σDM- 4.8× 10-32 (mDM/GeV) cm2 for time-independent cross sections, and σ0DM-γ 1.8 × 10-40 (mDM/GeV) cm2 and σ0DM- 2.5 × 10-47 (mDM/GeV) cm2 for cross sections scaling as temperature squared, coinciding with the parameter regions in which late kinetic decoupling may serve as a solution to the small-scale crisis. Furthermore, these μ-distortion signals differ from those of warm dark matter (no deviation from ) and a suppressed primordial power spectrum (strongly suppressed or a negative μ-parameter), demonstrating that CMB spectral distortion can potentially be used to distinguish between solutions to the small-scale crisis.