Impact of a rapid diluted energy density on the halo mass function

We study dark energy cosmological models, extensions of the standard model of particles, characterized by having an extra relativistic energy density at very early times, and that rapidly dilute after a phase transition occurs. These models generate well-localized features (or bumps) in the matter power spectrum for modes crossing the horizon during the phase transition epoch. This is because the presence of the additional energy component enhances the growth of matter fluctuations. Instead of considering a particular model, we focus on a parametric family of Gaussian bumps in the matter power spectrum, which otherwise would be a Lambda CDM one. We study the evolution of such bump cosmologies and their effects in the halo mass function and halo power spectrum using N-body simulations, the halo-model based HMcode method, and the peak background split framework. The bumps are subject to different nonlinear effects that become physically well understood, and from them we are able to predict that the most distinctive features will show up for intermediate halo masses 10(12.3) h(-1)M(circle dot) < M < 10(13.6) h(-1)M(circle dot). Out of this range, we expect halos are not significantly affected regardless of the location of the primordial bump in the matter power spectrum. Our analytical results are accurate and in very satisfactory agreement with the simulated data.