The cosmic evolution of the stellar mass-velocity dispersion relation of early-type galaxies

Abstract

We study the evolution of the observed correlation between central stellar velocity dispersion σe and stellar mass M* of massive (M* 3× 1010\,M) early-type galaxies (ETGs) out to redshift z≈ 2.5, exploiting a Bayesian hierarchical inference formalism. Collecting ETGs from state-of-the-art literature samples, we build a fiducial sample (0 z 1), which is obtained with homogeneous selection criteria, but also a less homogeneous extended sample (0 z 2.5). Based on the fiducial sample, we find that the M*-σe relation is well represented by σe M*β(1+z)ζ, with β 0.18 independent of redshift and ζ 0.4 (at given M*, σe decreases for decreasing z, for instance by a factor of ≈1.3 from z=1 to z=0). When the slope β is allowed to evolve, we find it increasing with redshift: β(z) 0.16+0.26(1+z) describes the data as well as constant β 0.18. The intrinsic scatter of the M*-σe relation is 0.08 dex in σe at given M*, independent of redshift. Our results suggest that, on average, the velocity dispersion of individual massive (M* 3× 1011\,M) ETGs decreases with time while they evolve from z≈ 1 to z≈ 0. The analysis of the extended sample leads to results similar to that of the fiducial sample, with slightly stronger redshift dependence of the normalisation (ζ 0.5) and weaker redshift dependence of the slope ( d β/ d (1+z) 0.18) when β varies with time. At z=2 ETGs with M*≈ 1011\,M have, on average, ≈1.7 higher σe than ETGs of similar stellar mass at z=0.