Angular momentum - mass relation for dark matter haloes

Abstract

We study the empirical relation between an astronomical object's angular momentum J and mass M, J=β Mα, the J-M relation, using N-body simulations. In particular, we investigate the time evolution of the J-M relation to study how the initial power spectrum and cosmological model affect this relation, and to test two popular models of its origin - mechanical equilibrium and tidal torque theory. We find that in the model, α starts with a value of 1.5 at high redshift z, increases monotonically, and finally reaches 5/3 near z=0, whereas β evolves linearly with time in the beginning, reaches a maximum and decreases, and stabilizes finally. A three-regime scheme is proposed to understand this newly observed picture. We show that the tidal torque theory accounts for this time evolution behaviour in the linear regime, whereas α=5/3 comes from the virial equilibrium of haloes. The J-M relation in the linear regime contains the information of the power spectrum and cosmological model. The J-M relations for haloes in different environments and with different merging histories are also investigated to study the effects of a halo's non-linear evolution. An updated and more complete understanding of the J-M relation is thus obtained.