How Do Disk Galaxies Form?

TL;DR

This paper presents a simple analytical model explaining galaxy disk formation based on the competition between rotation and turbulence, validated against cosmological simulations, and accounts for observed redshift trends.

Contribution

The model links galaxy morphology to halo properties and predicts size behaviors before and after disk formation, aligning with simulation and observational data.

Findings

Disk formation depends on halo concentration and baryonic mass accumulation.

Post-disk formation sizes are governed by halo spin, pre-formation sizes by turbulence scale.

The critical halo mass for disk formation increases with redshift, matching observations.

Abstract

In both observed and simulated galaxies, disk morphologies become more prevalent at higher masses and lower redshifts. To elucidate the physical origin of this trend, we develop a simple analytical model in which galaxy morphology is governed by the competition between rotational support and turbulence in a gravitational potential of a dark matter halo and the galaxy itself, and a disk forms when the potential steepens due to the accumulation of baryons in the halo center. The minimum galaxy mass required for this transition decreases with an increasing dark matter contribution within the galaxy, making more concentrated halos more prone to forming disks. Our model predicts that galaxy sizes behave qualitatively differently before and after disk formation: after disks form, sizes are governed by the halo spin, in agreement with classical models, whereas before disk formation, sizes are larger and set by the scale on which turbulent motions, which dominate over rotation, can be contained. We validate our model against the results of the TNG50 cosmological simulation and, despite the simplicity of the model, find remarkable agreement. In particular, our model explains the increase with redshift in the critical halo mass for disk formation, reported in both simulations and observations, as a consequence of the evolution of the halo mass-concentration and baryonic mass-halo mass relations. This redshift trend therefore supports the recent proposal that it is the steepening of the gravitational potential that causes disk formation, while other effects discussed in the literature, such as potential deepening and hot gaseous halo formation, can still play important roles in the transition from early turbulent to dynamically cold disks.