The Birth and Growth of Neutralino Haloes

TL;DR

This study uses the EPS formalism and Monte Carlo simulations to analyze the assembly histories of neutralino dark matter halos, revealing their formation times, mass scales, and disruption likelihood in a standard cosmological model.

Contribution

It provides a detailed statistical analysis of neutralino halo formation and growth using EPS, extending understanding to smaller scales beyond current N-body simulations.

Findings

Most neutralinos' first halos are smaller than the free-streaming cutoff mass.

A significant fraction of particles never belonged to smaller halos.

First-generation halos form at relatively low redshifts, around 8 to 13.

Abstract

We use the Extended-Press-Schechter (EPS) formalism to study halo assembly histories in a standard $\Lambda$CDM cosmology. A large ensemble of Monte Carlo random walks provides the {\it entire} halo membership histories of a representative set of dark matter particles, which we assume to be neutralinos. The first generation halos of most particles do not have a mass similar to the free-streaming cut-off $M_{f.s.}$ of the neutralino power spectrum, nor do they form at high redshift. Median values are $M_1 = 10^5$ to $10^7M_{f.s.}$ and $z_1 = 13$ to 8 depending on the form of the collapse barrier assumed in the EPS model. For almost a third of all particles the first generation halo has $M_1>10^9M_{f.s.}$. At redshifts beyond 20, most neutralinos are not yet part of any halo but are still diffuse. These numbers apply with little modification to the neutralinos which are today part of halos similar to that of the Milky Way. Up to 10% of the particles in such halos were never part of a smaller object; the typical particle has undergone $\sim 5$ "accretion events' where the halo it was part of falls into a more massive object. Available N-body simulations agree well with the EPS predictions for an "ellipsoidal" collapse barrier, so these may provide a reliable extension of simulation results to smaller scales. The late formation times and large masses of the first generation halos of most neutralinos imply that they will be disrupted with high efficiency during halo assembly.