The Density Structure of Simulated Stellar Streams

Abstract

Simulations are run with and without a normal cold dark matter sub-halo population below 4x108 Msun to examine the role of the lower mass sub-halos in the creation of density variations, "gaps", within thin tidal star streams. Dense star clusters composed of stellar mass particles are started within a redshift 3 sub-galactic dark matter halo distribution which assembles to create a Milky Way like halo. Hierarchical assembly causes the early-time tidal star streams from the clusters to later be dispersed as thick streams around the thin streams that develop in the main late-time halo as it settles towards equilibrium. The two simulations are set up to be essentially dynamically identical and result in about 140 star clusters within a radius of 50 kpc, of which 40 some have thin tidal streams longer than 40\ with a separation of more than 20\ from the cluster as viewed from the halo center. Averaged over about 20 separate snapshots, the fraction of streams with significant density variations inside 50 kpc is 0.580.02 in the simulation with low mass sub-halos and 0.520.02 in the simulation without low mass halos. That is, only 125\% of the stream density variations can be attributed to the sub-halos below 4x108 Msun. The dominant source of density variations in streams is the varying tidal fields along the complex trajectories of the clusters and their streams as the galaxy assembles.