Icarus revisited: An Ancient, Metal-poor Accreted Stellar Stream in the Disk of the Milky Way

TL;DR

This study revisits the Icarus stellar stream in the Milky Way disk, using Gaia and spectroscopic data to analyze its properties, origins, and relation to dwarf galaxy accretion, revealing its ancient, accreted nature and chemical distinctiveness.

Contribution

It provides a detailed chemo-dynamical characterization of Icarus, confirming its origin as debris from a dwarf galaxy and refining its properties with new spectroscopic data.

Findings

Icarus is older than 12 Gyr and has properties similar to the metal-weak thick disk.

Chemical analysis confirms Icarus as accreted from a dwarf galaxy.

Icarus's properties are consistent with debris from a $ ext{~}10^9 M_ ext{sun}$ dwarf galaxy.

Abstract

The search for accreted satellites in the Galactic disk is a challenging task, to which Gaia plays a crucial role in synergy with ground-based spectroscopic surveys. In 2021, Re Fiorentin et al. discovered five substructures with disk kinematics including Icarus. To gain more insight into the origin of Icarus as a remnant of a dwarf galaxy rather than a signature of secular processes of disk formation, we complement astrometric Gaia DR3 data with spectroscopy from APOGEE DR17 and GALAH DR3, and explore the chemo-dynamical distributions within 3 kpc of the Sun. We select 622 stars in the accreted/unevolved regions of [Mg/Mn]-[Al/Fe] and [Mg/Fe]-[Fe/H], where we identify 81 and 376 stars with $-2<{\rm[Fe/H]}<-0.7$ belonging to Icarus and Gaia-Sausage-Enceladus (GSE), respectively. The revised properties of Icarus are: $\langle V+V_{\rm LSR}\rangle\simeq171~\rm{km~s}^{-1}$, $\sigma_{V}\simeq37\rm{km~s}^{-1}$, $\langle e\rangle\simeq0.36$, $\langle{\rm[Fe/H]}\rangle\simeq-1.35$, $\langle{\rm[Mg/Fe]}\rangle\simeq+0.27$, $\langle{\rm[Al/Fe]}\rangle\simeq-0.13$, and $\langle{\rm[Mn/Fe]}\rangle\simeq-0.39$. From the CMD of its members, Icarus appears older than 12 Gyr. Such age and dynamical properties are reminiscent of the metal-weak thick disk. However, detailed chemical analysis in the diagnostic spaces [Ni/Fe]-[(C+N)/O], [Y/Eu]-[Fe/H], [Eu/Mg]-[Fe/H], [Ba/Y]-[Fe/H], and [Ba/Mg]-[Mg/H] evidences that Icarus and GSE occupy the accreted region, well separated from the bulk of in situ disk stars. Updated comparisons with N-body simulations confirm that Icarus' stars are consistent with the debris of a dwarf galaxy with a stellar mass of $\sim~10^9~M_\odot$ accreted onto a primordial disk on an initial prograde low-inclination orbit.