On the origin of the angular momentum properties of gas and dark matter in galactic halos and its implications

TL;DR

This study uses hydrodynamical simulations to analyze the origin and distribution of angular momentum in galactic halos, proposing mechanisms for disk formation and explaining halo spin properties during mergers.

Contribution

It reveals how mergers shape angular momentum distributions and introduces a geometric criterion for forming exponential galactic disks by removing low AM material.

Findings

Mergers produce a universal AM distribution with excess low AM material.

A simple geometric removal of low AM material can lead to exponential disk formation.

Dark matter and gas exhibit different AM transfer mechanisms during mergers.

Abstract

We perform a set of non-radiative hydrodynamical simulations of merging spherical halos in order to understand the angular momentum (AM) properties of the galactic halos seen in cosmological simulations. The universal shape of AM distributions seen in simulations is found to be generically produced as a result of mergers. The universal shape is such that it has an excess of low AM material and hence cannot explain the exponential structure of disk galaxies. A resolution to this is suggested by the spatial distribution of low AM material which is found to be in the centre and a conical region close to the axis of rotation. A mechanism that preferentially discards the material in the centre and prevents the material along the poles from falling onto the disc is proposed as a solution. We implement a simple geometric criteria for selective removal of low AM material and show that in order for 90% of halos to host exponential discs one has to reject at least 40% of material. Next, we explore the physical mechanisms responsible for distributing the AM within the halo during a merger. For dark matter there is an inside-out transfer of AM, whereas for gas there is an outside-in transfer, which is due to differences between collisionless and gas dynamics. We also explain the apparent high spin of dark matter halos undergoing mergers and show that a criteria stricter than what is currently used, would be required to detect such unrelaxed halos. Finally, we demonstrate that the misalignment of AM between gas and dark matter only occurs when the intrinsic spins of the merging halos are not aligned with the orbital AM of the system. The self-misalignment (orientation of AM when measured in radial shells not being constant), which could be the cause of warps and anomalous rotation in disks galaxies, also occurs under similar conditions.