Regular rotation and low turbulence in a diverse sample of z ~ 4.5 galaxies observed with ALMA

TL;DR

This study reveals that diverse galaxies at z ~ 4.5 exhibit regular rotation and low turbulence, indicating early disc formation with dominant rotation over turbulence, challenging previous models of chaotic early galaxy kinematics.

Contribution

Introduces the CANNUBI algorithm for 3D disc geometry fitting and demonstrates early disc formation with rotation dominance across various galaxy types at high redshift.

Findings

Most galaxies in the sample are rotating discs.

Rotation velocities range from 198 to 562 km/s.

Gas velocity dispersions are between 49 and 75 km/s.

Abstract

The discovery of galaxies with regularly rotating discs at redshifts $\geq$ has been a puzzling challenge to galaxy formation models that tend to predict chaotic gas kinematics in the early Universe as a consequence of gas accretion, mergers and efficient feedback. In this work, we investigated the kinematics of five highly resolved galaxies at z $\sim$ 4.5 observed with ALMA in the [CII] 158 $\mu$m emission line. The sample is diverse: AzTEC1 (starburst galaxy), BRI1335-0417 (starburst and quasar host galaxy), J081740 (normal star-forming galaxy) and SGP38326 (two starburst galaxies in a group). The five galaxies show velocity gradients, but four were found to be rotating discs while the remaining, AzTEC1, is likely a merger. We studied the gas kinematics of the discs using 3DBAROLO and found that they rotate with maximum rotation velocities between 198 and 562 km/s while the gas velocity dispersions, averaged across the discs, are between 49 and 75 km/s. The rotation curves are generally flat and the galaxies have ratios of ordered-to-random motion (V/$\sigma$) between 2.7 and 9.8. We present CANNUBI, an algorithm for fitting the disc geometry of rotating discs in 3D emission-line observations prior to modelling the kinematics, with which we find indications that these discs may have thicknesses of the order of 1 kpc. This study shows that early disc formation with a clear dominance of rotation with respect to turbulent motions is present across a variety of galaxy types.