Identifying true satellites of the Magellanic Clouds

TL;DR

This paper investigates which recently discovered dwarf galaxies are true satellites of the Magellanic Clouds by analyzing their positions, velocities, and simulated orbital dynamics within the LCDM cosmological model.

Contribution

It introduces a method combining cosmological simulations and observational data to identify likely Magellanic satellites among new dwarf galaxies.

Findings

Hydra II and Hor 1 are consistent with Magellanic origin based on current data.

Six additional dwarfs have positions and distances compatible with Magellanic association, pending kinematic confirmation.

Predicted proper motions and radial velocities for all dwarfs to test their association with the Magellanic Clouds.

Abstract

The hierarchical nature of LCDM suggests that the Magellanic Clouds must have been surrounded by a number of satellites before their infall into the Milky Way. Many of those satellites should still be in close proximity to the Clouds, but some could have dispersed ahead/behind the Clouds along their Galactic orbit. Either way, prior association with the Clouds results in strong restrictions on the present-day positions and velocities of candidate Magellanic satellites: they must lie close to the nearly-polar orbital plane of the Magellanic stream, and their distances and radial velocities must follow the latitude dependence expected for a tidal stream with the Clouds at pericenter. We use a cosmological numerical simulation of the disruption of a massive subhalo in a Milky Way-sized LCDM halo to test whether any of the 20 dwarfs recently-discovered in the DES, SMASH, Pan-STARRS, and ATLAS surveys are truly associated with the Clouds. Of the 6 systems with kinematic data, only Hydra II and Hor 1 have distances and radial velocities consistent with a Magellanic origin. Of the remaining dwarfs, six (Hor 2, Eri 3, Ret 3, Tuc 4, Tuc 5, and Phx 2) have positions and distances consistent with a Magellanic origin, but kinematic data are needed to substantiate that possibility. Conclusive evidence for association would require proper motions to constrain the orbital angular momentum direction, which, for true Magellanic satellites, must coincide with that of the Clouds. We use this result to predict radial velocities and proper motions for all new dwarfs. Our results are relatively insensitive to the assumption of first or second pericenter for the Clouds.