Dynamical modelling of luminous and dark matter in 17 Coma early-type galaxies

TL;DR

This study models the distribution of luminous and dark matter in 17 early-type galaxies in the Coma cluster using axisymmetric Schwarzschild models, revealing significant dark matter presence and orbital anisotropies.

Contribution

It provides detailed dynamical models of 17 galaxies, quantifying dark matter content and orbital anisotropies with improved statistical significance over previous studies.

Findings

Dark matter is present in all galaxies, with 10-50% inside the half-light radius.

Central dark matter density is much lower than luminous mass density.

Galaxies show slight radial or tangential orbital anisotropies.

Abstract

Dynamical models for 17 Coma early-type galaxies are presented. The galaxy sample consists of flattened, rotating as well as non-rotating early-types including cD and S0 galaxies with luminosities between M=-18.79 and M=-22.56. Kinematical long-slit observations cover at least the major and minor axis and extend to 1-4 effective radii. Axisymmetric Schwarzschild models are used to derive stellar mass-to-light ratios and dark halo parameters. In every galaxy models with a dark matter halo match the data better than models without. The statistical significance is over 95 percent for 8 galaxies, around 90 percent for 5 galaxies and for four galaxies it is not significant. For the highly significant cases systematic deviations between observed and modelled kinematics are clearly seen; for the remaining galaxies differences are more statistical in nature. Best-fit models contain 10-50 percent dark matter inside the half-light radius. The central dark matter density is at least one order of magnitude lower than the luminous mass density. The central phase-space density of dark matter is often orders of magnitude lower than in the luminous component, especially when the halo core radius is large. The orbital system of the stars along the major-axis is slightly dominated by radial motions. Some galaxies show tangential anisotropy along the minor-axis, which is correlated with the minor-axis Gauss-Hermite coefficient H4. Changing the balance between data-fit and regularisation constraints does not change the reconstructed mass structure significantly. Model anisotropies tend to strengthen if the weight on regularisation is reduced, but the general property of a galaxy to be radially or tangentially anisotropic, respectively, does not change. (abridged)