# The Radial Distribution of Mono-Metallicity Populations in the Galactic   Disk as Evidence for Two-Phase Disk Formation

**Authors:** R. Dom\'inguez-Tenreiro, A. Obreja, C.B. Brook, F. J., Mart\'inez-Serrano, A. Serna

arXiv: 1706.05031 · 2017-09-06

## TL;DR

This paper combines observational data and hydrodynamical simulations to show that the two-phase halo mass assembly in the universe explains the radial distribution of mono-metallicity populations in the galactic disk, challenging traditional disk models.

## Contribution

It introduces a two-phase halo formation model to explain the radial metallicity patterns in the galactic disk, linking halo assembly history with disk star formation.

## Key findings

- Two-phase halo assembly influences MMP distributions.
- Radial mixing plays a secondary role in metallicity gradients.
- Halo virialization marks the transition in disk formation.

## Abstract

Recent determinations of the radial distributions of mono-metallicity populations (MMPs, i.e., stars in narrow bins in [Fe/H] within wider [$\alpha$/Fe] ranges) by the SDSS-III/APOGEE DR12 survey cast doubts on the classical thin - thick disk dichotomy. The analysis of these observations lead to the non-$[\alpha$/Fe] enhanced populations splitting into MMPs with different surface densities according to their [Fe/H]. By contrast, $[\alpha$/Fe] enhanced (i.e., old) populations show an homogeneous behaviour. We analyze these results in the wider context of disk formation within non-isolated halos embedded in the Cosmic Web, resulting in a two-phase mass assembly. By performing hydrodynamical simulations in the context of the $\rm \Lambda CDM$ model, we have found that the two phases of halo mass assembly (an early, fast phase, followed by a slow one, with low mass assembly rates) are very relevant to determine the radial structure of MMP distributions, while radial mixing has only a secondary role, depending on the coeval dynamical and/or destabilizing events. Indeed, while the frequent dynamical violent events occuring at high redshift remove metallicity gradients, and imply efficient stellar mixing, the relatively quiescent dynamics after the transition keeps [Fe/H] gaseous gradients and prevents newly formed stars to suffer from strong radial mixing. By linking the two-component disk concept with the two-phase halo mass assembly scenario, our results set halo virialization (the event marking the transition from the fast to the slow phases) as the separating event marking periods characterized by different physical conditions under which thick and thin disk stars were born.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1706.05031/full.md

## References

127 references — full list in the complete paper: https://tomesphere.com/paper/1706.05031/full.md

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Source: https://tomesphere.com/paper/1706.05031