Dynamical evidence for a strong tidal interaction between the Milky Way and its satellite, Leo V

Abstract

We present a chemodynamical analysis of the Leo~V dwarf galaxy, based on Keck II DEIMOS spectra of 8 member stars. We find a systemic velocity for the system of vr = 170.9+ 2.1-1.9kms-1, and barely resolve a velocity dispersion for the system, with σvr = 2.3+3.2-1.6kms-1, consistent with previous studies of Leo~V. The poorly resolved dispersion means we are unable to adequately constrain the dark matter content of Leo~V. We find an average metallicity for the dwarf of [Fe/H] = -2.480.21, and measure a significant spread in the iron abundance of its member stars, with -3.1[Fe/H]-1.9 dex, which cleanly identifies Leo~V as a dwarf galaxy that has been able to self-enrich its stellar population through extended star formation. Owing to the tentative photometric evidence for tidal substructure around Leo~V, we also investigate whether there is any evidence for tidal stripping or shocking of the system within its dynamics. We measure a significant velocity gradient across the system, of dv d = -4.1+2.8-2.6kms-1 per arcmin (or dv d = -71.9+50.8-45.6kms-1~kpc-1), which points almost directly toward the Galactic centre. We argue that Leo~V is likely a dwarf on the brink of dissolution, having just barely survived a past encounter with the centre of the Milky Way.