HALO7D III: Chemical Abundances of Milky Way Halo Stars from Medium Resolution Spectra

TL;DR

This study analyzes the chemical abundances and orbital dynamics of Milky Way halo stars using medium-resolution spectra, revealing chemodynamical differences across multiple fields that inform galaxy formation history.

Contribution

It provides detailed [Fe/H] and [$ ext{α}$/Fe] abundances for 113 stars and measures their velocity anisotropy, uncovering field-dependent chemodynamical variations in the MW halo.

Findings

Two fields have stars on radial orbits; two are more isotropic.

Chemodynamical differences suggest varied progenitor contributions.

Field-to-field variations in orbital anisotropy and metallicity bins.

Abstract

The Halo Assembly in Lambda Cold Dark Matter: Observations in 7 Dimensions (HALO7D) survey measures the kinematics and chemical properties of stars in the Milky Way (MW) stellar halo to learn about the formation of our Galaxy. HALO7D consists of Keck II/DEIMOS spectroscopy and Hubble Space Telescope-measured proper motions of MW halo main sequence turn-off (MSTO) stars in the four CANDELS fields. HALO7D consists of deep pencil beams, making it complementary to other contemporary wide-field surveys. We present the [Fe/H] and [$\alpha$/Fe] abundances for 113 HALO7D stars in the Galactocentric radial range of $\sim 10-40$ kpc. Using the full 7D chemodynamical data (3D positions, 3D velocities, and abundances) of HALO7D, we measure the velocity anisotropy, $\beta$, of the halo velocity ellipsoid for each field and for different metallicity-binned subsamples. We find that two of the four fields have stars on very radial orbits, while the remaining two have stars on more isotropic orbits. Separating the stars into high, mid, and low [Fe/H] bins at $-2.2$ dex and $-1.1$ dex for each field separately, we find differences in the anisotropies between the fields and between the bins; some fields appear dominated by radial orbits in all bins while other fields show variation between the [Fe/H] bins. These chemodynamical differences are evidence that the HALO7D fields have different fractional contributions from the progenitors that built up the MW stellar halo. Our results highlight the additional information that is available on smaller spatial scales when compared to results from a spherical average of the stellar halo.