Speaker
Description
We show that the merger tree of dark matter halos is approximately self-similar by investigating the universality of the subhalo peak mass function (PMF) describing the mass distribution of progenitor halos. Using a set of cosmological simulations and identifying subhalos of different merger levels with HBT+, we verify that the level-1 subhalo PMF is close to universal across halo mass, redshift, and cosmology. This approximate self-similarity allows us to analytically derive the subhalo PMF for subhalos accreted at any level (i.e., for sub-sub...halos) through self-convolutions of the level-1 PMF, and the resulting model shows good agreement with simulation measurements. We further derive a number of analytical properties on the hierarchical origin of subhalos, including the level distribution, accretion rate at each level, initial merger ratio distribution, and accretion redshift distribution. We find that higher-level subhalos dominate at progressively lower peak mass in the PMF and are more likely to originate from major mergers than lower-level ones. Among the top 100 subhaloes, both level 1 and level 2 populations contribute about 40 percent. At a given mass ratio at accretion time, the subhalo accretion rates at each level track the growth rate of the host halo. At a fixed final mass ratio, however, the accretion redshift distribution of subhalos depends on the subhalo level, peak mass, and host mass. Higher-level and higher-mass-ratio subhalos tend to be accreted more recently, and more massive halos also accrete their subhalos more recently. Finally, we claim that a well-defined halo boundary, which aligns with the orbits of particles and subhalos during mergers, is essential to preserve the self-similarity observed in halo merger trees.
