The dynamics of z~1 clusters of galaxies from the GCLASS survey

TL;DR

This study analyzes the internal dynamics of galaxy clusters at z~1 using the GCLASS survey, revealing mass profiles, galaxy orbit anisotropies, and phase-space density relations consistent with dark matter simulations.

Contribution

It provides the first detailed dynamical analysis of z~1 galaxy clusters, comparing observational results with theoretical models and simulations.

Findings

Mass profile consistent with NFW and other models

Galaxy orbits are isotropic near centers and radial outward

Phase-space density profiles match dark matter simulations

Abstract

We constrain the internal dynamics of a stack of 10 clusters from the GCLASS survey at 0.87<z<1.34. We determine the stack cluster mass profile M(r) using the MAMPOSSt algorithm of Mamon et al., the velocity anisotropy profile beta(r) from the inversion of the Jeans equation, and the pseudo-phase-space density profiles Q(r) and Qr(r), obtained from the ratio between the mass density profile and the third power of the (total and, respectively, radial) velocity dispersion profiles of cluster galaxies. Several M(r) models are statistically acceptable for the stack cluster (Burkert, Einasto, Hernquist, NFW). The total mass distribution has a concentration c=r200/r-2=4.0-0.6+1.0, in agreement with theoretical expectations, and is less concentrated than the cluster stellar-mass distribution. The stack cluster beta(r) is similar for passive and star-forming galaxies and indicates isotropic galaxy orbits near the cluster center and increasingly radially elongated with increasing cluster-centric distance. Q(r) and Qr(r) are almost power-law relations with slopes similar to those predicted from numerical simulations of dark matter halos. Combined with results obtained for lower-z clusters we determine the dynamical evolution of galaxy clusters, and compare it with theoretical predictions. We discuss possible physical mechanisms responsible for the differential evolution of total and stellar mass concentrations, and of passive and star-forming galaxy orbits [abridged].