Morpho-kinematics of z~1 galaxies probe the hierarchical scenario

TL;DR

This study combines kinematic and morphological analyses of z~1 galaxies to assess their dynamical states, revealing that most are involved in mergers, supporting hierarchical galaxy formation models.

Contribution

It introduces a combined morpho-kinematic classification method to distinguish isolated disks from mergers at z~1, validating the hierarchical scenario.

Findings

Only one third of z~1 galaxies are isolated, virialized spirals.

58% of galaxies are involved in merger sequences.

Results support merger-driven galaxy formation in the last 8 billion years.

Abstract

We have studied a representative sample of intermediate-mass galaxies at z~1, observed by the kinematic survey KMOS3D. We have re-estimated the kinematical parameters from the published kinematic maps and analysed photometric data from HST to measure optical disk inclinations and PAs. We find that only half of the z~1 galaxies show kinematic properties consistent with rotating disks, using the same classification scheme than that adopted by the KMOS3D team. Because merger orbital motions can also brought rotation, we have also analysed galaxy morphologies from the available HST imagery. Combining these results to those from kinematics, it leads to a full morpho-kinematic classification. To test the robustness of the latter for disentangling isolated disks from mergers, we confronted the results with an analysis of pairs from the open-grism redshift survey 3D-HST. All galaxies found in pairs are affected by either kinematic and/or morphological perturbations. Conversely, all galaxies classified as virialized spirals are found to be isolated. A significant fraction (one fourth) of rotating disks classified from kinematics by the KMOS3D team are found in pairs, which further supports the need for a morpho-kinematic classification. It results that only one third of z~1 galaxies are isolated and virialized spirals, while 58% of them are likely involved in a merger sequence, from first approach to disk rebuilding. The later fraction is in good agreement with the results of semi-empirical {\Lambda}CDM models, supporting a merger-dominated hierarchical scenario as being the main driver of galaxy formation at least during the last 8 billion years.