Study of the Sextans dwarf spheroidal galaxy from the DART CaII triplet survey

TL;DR

This study uses spectroscopic data of red giant stars in Sextans dwarf galaxy to analyze its metallicity distribution, internal kinematics, and dark matter profile, revealing complex chemo-dynamical behavior and a possible disrupted star cluster.

Contribution

First detailed velocity dispersion profile of Sextans out to 1.6 degrees, with Jeans modeling supporting both cored and cuspy dark matter halos.

Findings

Sextans has a metallicity gradient with central regions more metal-rich.

Detection of a cold substructure possibly from a disrupted star cluster.

Mass-to-light ratio estimates indicate a dominant dark matter component.

Abstract

We use VLT/FLAMES intermediate resolution (R~6500) spectra of individual red giant branch stars in the near-infrared CaII triplet (CaT) region to investigate the wide-area metallicity properties and internal kinematics of the Sextans dwarf spheroidal galaxy (dSph). Our final sample consists of 174 probable members of Sextans with accurate line-of-sight velocities (+- 2 km/s) and CaT [Fe/H] measurements (+- 0.2 dex). We use the MgI line at 8806.8 \AA\, as an empirical discriminator for distinguishing between probable members of the dSph (giant stars) and probable Galactic contaminants (dwarf stars). Sextans shows a similar chemo-dynamical behaviour to other Milky Way dSphs, with its central regions being more metal rich than the outer parts and with the more metal-rich stars displaying colder kinematics than the more metal-poor stars. Hints of a velocity gradient are found along the projected major axis and along an axis at P.A.=191 deg, however a larger and more spatially extended sample may be necessary to pin down the amplitude and direction of this gradient. We detect a cold kinematic substructure at the centre of Sextans, consistent with being the remnant of a disrupted very metal poor stellar cluster. We derive the most extended line-of-sight velocity dispersion profile for Sextans, out to a projected radius of 1.6 deg. From Jeans modelling of the observed line-of-sight velocity dispersion profile we find that this is consistent with both a cored dark matter halo with large core radius and cuspy halo with low concentration. The mass within the last measured point is in the range 2-4 x 10^8 M_sun, giving very large mass-to-light ratios, from 460 to 920 (M/L)_(V,sun).