The Contribution of Spiral Arms to the Thick Disk along the Hubble Sequence

TL;DR

This study investigates how spiral arms influence the formation of thick disks across different galaxy types, revealing that their impact varies with galaxy morphology and induces chaotic stellar scattering rather than resonant excitation.

Contribution

It provides the first comprehensive numerical analysis of spiral arms' role in thick disk formation across the Hubble sequence, highlighting the importance of galaxy morphology and spiral parameters.

Findings

Vertical heating increases with later galaxy types.

Spiral arms induce chaotic scattering, not resonances.

Effect on the Milky Way is negligible.

Abstract

The first mechanism invoked to explain the existence of the thick disk in the Milky Way Galaxy, were the spiral arms. Up-to-date work summon several other possibilities that together seem to better explain this component of our Galaxy. All these processes must affect differently in distinct types of galaxies, but the contribution of each one has not been straightforward to quantify. In this work, we present a first comprehensive study of the effect of the spiral arms in the formation of thick disks, as going from early to late type disk galaxies, in an attempt to characterize and quantify this specific mechanism in galactic potentials. To this purpose, we perform numerical simulations of test particles in a three-dimensional spiral galaxy potential of normal spiral galaxies (from early to late types). By varying the parameters of the spiral arms we found that the vertical heating of the stellar disk becomes very important in some cases, and strongly depends on the galaxy morphology, pitch angle, arms mass and its pattern speed. The later the galaxy type, the larger is the effect on the disk heating. This study shows that the physical mechanism causing the vertical heating is different from simple resonant excitation. The spiral pattern induce chaotic behavior not linked necessarily to resonances but to direct scattering of disk stars, which leads to an increase of the velocity dispersion. We applied this study to the specific example of the Milky Way Galaxy, for which we have also added an experiment that includes the Galactic bar. From this study we deduce that the effect of spiral arms of a Milky-Way-like potential, on the dynamical vertical heating of the disk is negligible, unlike later galactic potentials for disks.