Dark matter halos in the multicomponent model. I. Substructure

Abstract

Multicomponent dark matter with self-interactions, which allows for inter-conversions of species into one another, is a promising paradigm that is known to successfully and simultaneously resolve major problems of the conventional cosmology at galactic and sub-galactic scales. In this paper, we present N-body simulations of the simplest two-component (2cDM) model aimed at studying the distribution of dark matter halos with masses M1012M. In particular, we investigate how the maximum circular velocity function of the halos is affected by the velocity dependence of the self-interaction cross-sections, σ(v) va, and compare them with available observational data. The results demonstrate that the 2cDM paradigm with the range of self-interaction cross-section per particle mass (evaluated at v=100 km s-1) of 0.01 σ0/m 1 cm2g-1 and the mass degeneracy m/m 10-7-10-8 is robustly resolving the substructure and too-big-to-fail problems by suppressing the substructure having small maximum circular velocities, V max100 km s-1. We also discuss the disagreement between the radial distribution of dwarfs in a host halo observed in the Local Group and simulated with CDM. This can be considered as one more small-scale problem of CDM. We demonstrate that such a disagreement is alleviated in 2cDM. Finally, the computed matter power-spectra of the 2cDM structure indicate the model's consistency with the existing Ly-α forest constraints.