Radial Mixing in Galactic Disks: The Effects of Disk Structure and Satellite Bombardment

TL;DR

This study uses numerical simulations to explore how disk structure and satellite interactions influence stellar radial migration in galaxies like the Milky Way, revealing distinct mechanisms and their effects on stellar dynamics.

Contribution

It demonstrates that satellite perturbations significantly enhance radial migration, especially at large radii, and identifies observable signatures to distinguish migration mechanisms.

Findings

Satellite perturbations cause stars to migrate more at large radii.

Radial migration increases dispersion in the age-metallicity relation.

Migration mechanisms leave observable dynamical signatures.

Abstract

We use a suite of numerical simulations to investigate the mechanisms and effects of radial migration of stars in disk galaxies like the Milky Way (MW). An isolated, collisionless stellar disk with a MW-like scale-height shows only the radial "blurring" expected from epicyclic orbits. Reducing the disk thickness or adding gas to the disk substantially increases the level of radial migration, induced by interaction with transient spiral arms and/or a central bar. We also examine collisionless disks subjected to gravitational perturbations from a cosmologically motivated satellite accretion history. In the perturbed disk that best reproduces the observed properties of the MW, 20% of stars that end up in the solar annulus 7 kpc < R < 9 kpc started at R < 6 kpc, and 7% started at R > 10 kpc. This level of migration would add considerable dispersion to the age-metallicity relation of solar neighborhood stars. In the isolated disk models, the probability of migration traces the disk's radial mass profile, but in perturbed disks migration occurs preferentially at large radii, where the disk is more weakly bound. The orbital dynamics of migrating particles are also different in isolated and perturbed disks: satellite perturbations drive particles to lower angular momentum for a given change in radius. Thus, satellite perturbations appear to be a distinct mechanism for inducing radial migration, which can operate in concert with migration induced by bars and spiral structure. We investigate correlations between changes in radius and changes in orbital circularity or vertical energy, identifying signatures that might be used to test models and distinguish radial migration mechanisms in chemo-dynamical surveys of the MW disk.