The observable properties of galaxy accretion events in Milky Way-like galaxies in the FIRE-2 cosmological simulations

TL;DR

This study uses FIRE-2 cosmological simulations to analyze how satellite galaxy accretion influences the observable properties of stellar halos in Milky Way-like galaxies, highlighting key parameters that shape debris distribution and composition.

Contribution

It provides a detailed analysis of satellite accretion effects on stellar halo properties using high-resolution cosmological simulations, emphasizing the roles of accretion time and satellite mass.

Findings

Inner halo contains well-mixed debris from various satellites.

Outer halo retains unphased debris from early, lower-mass satellites.

Accretion parameters influence debris distribution and composition.

Abstract

In the $\Lambda$-Cold Dark Matter model of the Universe, galaxies form in part through accreting satellite systems. Previous work have built an understanding of the signatures of these processes contained within galactic stellar halos. This work revisits that picture using seven Milky Way-like galaxies in the \textit{Latte} suite of FIRE-2 cosmological simulations. The resolution of these simulations allows a comparison of contributions from satellites above M$_{*}$$\gtrsim$10$\times$$^{7}$M$_{\odot}$, enabling the analysis of observable properties for disrupted satellites in a fully self-consistent and cosmological context. Our results show that, the time of accretion and the stellar mass of an accreted satellite are fundamental parameters that in partnership dictate the resulting spatial distribution, orbital energy, and [$\alpha$/Fe]-[Fe/H] compositions of the stellar debris of such mergers $at$ $present$ $day$. These parameters also govern the resulting dynamical state of an accreted galaxy at $z=0$, leading to the expectation that the inner regions of the stellar halo (R$_{\mathrm{GC}}$ $\lesssim$30 kpc) should contain fully phase-mixed debris from both lower and higher mass satellites. In addition, we find that a significant fraction of the lower mass satellites accreted at early times deposit debris in the outer halo (R$_{\mathrm{GC}}$ $>$50 kpc) that are $not$ fully phased-mixed, indicating that they could be identified in kinematic surveys. Our results suggest that, as future surveys become increasingly able to map the outer halo of our Galaxy, they may reveal the remnants of long-dead dwarf galaxies whose counterparts are too faint to be seen $in$ $situ$ in higher redshift surveys.