The APOSTLE project: Local Group kinematic mass constraints and simulation candidate selection

TL;DR

The APOSTLE project uses cosmological simulations to identify Local Group-like systems, enabling detailed studies of galaxy formation and testing cosmological models against local universe observations.

Contribution

This work introduces a selection of halo pairs matching Local Group kinematics for hydrodynamical simulations, improving the realism of galaxy formation models within the b5CDM framework.

Findings

Halo pairs matching Local Group kinematics have lower masses than the timing argument suggests.

Simulations reproduce key features of the Milky Way and Andromeda satellite systems.

Selected systems serve as a testbed for b5CDM predictions against local observations.

Abstract

We use a large sample of isolated dark matter halo pairs drawn from cosmological N-body simulations to identify candidate systems whose kinematics match that of the Local Group of Galaxies (LG). We find, in agreement with the "timing argument" and earlier work, that the separation and approach velocity of the Milky Way (MW) and Andromeda (M31) galaxies favour a total mass for the pair of $\sim 5\times 10^{12} \,M_{\odot}$. A mass this large, however, is difficult to reconcile with the small relative tangential velocity of the pair, as well as with the small deceleration from the Hubble flow observed for the most distant LG members. Halo pairs that match these three criteria have average masses a factor of $\sim 2$ times smaller than suggested by the timing argument, but with large dispersion. Guided by these results, we have selected $12$ halo pairs with total mass in the range $1.6$-$3.6 \times 10^{12}\,M_{\odot}$ for the APOSTLE project (A Project Of Simulating The Local Environment), a suite of hydrodynamical resimulations at various numerical resolution levels (reaching up to $\sim10^{4}\,M_{\odot}$ per gas particle) that use the subgrid physics developed for the EAGLE project. These simulations reproduce, by construction, the main kinematics of the MW-M31 pair, and produce satellite populations whose overall number, luminosities, and kinematics are in good agreement with observations of the MW and M31 companions. The APOSTLE candidate systems thus provide an excellent testbed to confront directly many of the predictions of the $\Lambda$CDM cosmology with observations of our local Universe.