Evolution of Galactic Discs: Multiple Patterns, Radial Migration and Disc Outskirts

TL;DR

This study uses N-body simulations to explore how galactic disks evolve, revealing that secular processes can significantly extend disks, influence surface-brightness profiles, and are affected by multiple density wave patterns and gas inflow.

Contribution

It demonstrates that secular evolution, multiple pattern interactions, and gas accretion can explain observed disk profile types and their outer structures, providing new insights into disk formation.

Findings

Disks can triple their radial extent through secular evolution.

Multiple density wave patterns interact non-linearly, affecting disk structure.

Gas inflow leads to increased stellar velocity dispersion and Type III profiles.

Abstract

We investigate the evolution of galactic disks in N-body Tree-SPH simulations. We find that disks, initially truncated at three scale-lengths, can triple their radial extent, solely driven by secular evolution. Both Type I (single exponential) and Type II (down-turning) observed disk surface-brightness profiles can be explained by our findings. We relate these results to the strong angular momentum outward transfer, resulting from torques and radial migration associated with multiple patterns, such as central bars and spiral waves of different multiplicity. We show that even for stars ending up on cold orbits, the changes in angular momentum exhibit complex structure as a function of radius, unlike the expected effect of transient spirals alone. Focussing on one of our models, we find evidence for non-linear coupling among m=1, 2, 3 and 4 density waves, where m is the pattern multiplicity. We suggest that the naturally occurring larger resonance widths at galactic radii beyond four scale-lengths may have profound consequences on the formation and location of breaks in disk density profiles, provided spirals are present at such large distances. We also consider the effect of gas inflow and show that when in-plane smooth gas accretion of ~5 M_sun/yr is included, the outer disks become more unstable, leading to a strong increase in the stellar velocity dispersion. This, in turn, causes the formation of a Type III (up-turning) profile in the old stellar population. We propose that observations of Type III surface brightness profiles, combined with an up-turn in the stellar velocity dispersions beyond the disk break, could be a signature of ongoing gas-accretion. The results of this study suggest that disk outskirts comprised of stars migrated from the inner disk would have relatively large radial velocity dispersions, and significant thickness when seen edge-on. [Abridged]