The effect of radial migration on galactic disks

TL;DR

This study uses simulations to show that radial migration driven by spiral arms redistributes stars within galactic disks with minimal heating, affecting thin disk structure but challenging the idea that the thick disk results from migration.

Contribution

It provides detailed insights into how spiral-driven radial migration preserves orbit circularity and influences vertical stellar distributions, clarifying migration's role in disk evolution.

Findings

Migrators are biased towards low vertical velocity dispersions.

Radial migration preserves orbit circularity with minimal heating.

Migration impacts thin disk structure but not the thick disk formation.

Abstract

We study the radial migration of stars driven by recurring multi-arm spiral features in an exponential disk embedded in a dark matter halo. The spiral perturbations redistribute angular momentum within the disk and lead to substantial radial displacements of individual stars, in a manner that largely preserves the circularity of their orbits and that results, after 5 Gyr (~40 full rotations at the disk scalelength), in little radial heating and no appreciable changes to the vertical or radial structure of the disk. Our results clarify a number of issues related to the spatial distribution and kinematics of migrators. In particular, we find that migrators are a heavily biased subset of stars with preferentially low vertical velocity dispersions. This "provenance bias" for migrators is not surprising in hindsight, for stars with small vertical excursions spend more time near the disk plane and thus respond more readily to non-axisymmetric perturbations. We also find that the vertical velocity dispersion of outward migrators always decreases, whereas the opposite holds for inward migrators. To first order, newly arrived migrators simply replace stars that have migrated off to other radii, thus inheriting the vertical bias of the latter. Extreme migrators might therefore be recognized, if present, by the unexpectedly small amplitude of their vertical excursions. Our results show that migration, understood as changes in angular momentum that preserve circularity, can affect strongly the thin disk, but cast doubts on models that envision the Galactic thick disk as a relic of radial migration.