Spiral arms across stellar populations in simulations via the local dimension method

TL;DR

This study uses a new local dimension method to analyze how different stellar populations in a simulated galaxy support and interact with spiral arms over time, revealing that all ages participate in spiral structures.

Contribution

We introduce the local dimension method to quantify spiral arm support across stellar populations in simulations, providing new insights into their dynamic interplay.

Findings

All stellar ages support spiral arms, including very old stars.

Spiral strength decreases with stellar age up to 2 Gyr and then stabilizes.

Old stars leave spiral arms faster than young stars, within 140-180 Myr.

Abstract

Context. The origin and nature of spiral arms remain unclear. Star forming regions and young stars are generally strongly associated to the spiral structure, but there are few quantitative predictions from simulations about the involvement of stars of different ages. Aims. We aim to quantify the interplay between spiral arms and different populations. Methods. We use a hydrodynamical simulation of an isolated disc galaxy displaying a dynamic multi-armed spiral structure. Inspired by cosmological structure metrics, we develop a new method, the local dimension, that robustly delineates arms across populations and through space and time. Results. We find that all stars, including those as old as 11Gyr, support the arms. The spiral strength decreases with stellar age up to 2Gyr-old stars and remains nearly constant for older stars. However, the scaling between arm strength and age (or velocity dispersion) depends on the strength of the global spiral structure at each time. Almost all stars formed in arms remain within them for no more than 140-180Myr, whereas old stars leave arms about three times faster. Even if the youngest populations dominate in the production of the spiral torques at early times, all populations contribute equally at later times. Conclusions. Our results highlight the power of the local dimension for studying complex spiral structures and show that all stellar populations in the disc partake in the arms. Since in our model we see spiral arms in populations with velocity dispersions up to 90km/s, which are comparable to those of the Milky Way, we predict that old Galactic populations could also exhibit spiral structure.