Merger rates of dark matter haloes from merger trees in the extended Press-Schechter theory

TL;DR

This paper constructs merger trees using extended Press-Schechter theory to analyze dark matter halo merger rates across various masses, progenitor ratios, and redshifts, showing good agreement with N-body simulations.

Contribution

It introduces a method to compute halo merger rates using EPS theory with a moving barrier, extending previous models to better match simulation results.

Findings

Merger rate depends on halo mass as M^{0.2}

Merger rate depends on redshift as (dδ_c/dz)^{1.1}

Results agree with N-body simulation predictions

Abstract

We construct merger trees based on the extended Press-Schechter theory (EPS) in order to study the merger rates of dark matter haloes over a range of present day mass ($10^{10}M_{\sun}\leq M_0 \leq10^{15}M_{\sun}$), progenitor mass $(5\times10^{-3}\leq \xi \leq1$) and redshift ($0\leq z\leq 3$). We used the first crossing distribution of a moving barrier of the form $B(S,z)=p(z)+q(z)S^{\gamma}$, proposed by Sheth & Tormen, to take into account the ellipsoidal nature of collapse. We find that the mean merger rate per halo $B_m/n$ depends on the halo mass $M$ as $M^{0.2}$ and on the redshift as $(\mathrm{d}\delta_c(z)/\mathrm{d}z)^{1.1}$. Our results are in agreement with the predictions of N-body simulations and this shows the ability of merger-trees based on EPS theory to follow with a satisfactory agreement the results of N-body simulations and the evolution of structures in a hierarchical Universe.