The assembly and fate of a giant disc galaxy in a protocluster at z = 3

Abstract

Recent JWST observations revealed two massive (M 1011\,M), unexpectedly large spiral galaxies at z 3, both in overdense environments. We focus on one of these, ADF22.1 at z = 3.09, which hosts an active galactic nucleus (AGN), exploiting its extended [CII] emission (30 kpc in diameter) with high-resolution observations from the Atacama Large Millimetre Array and JWST. We find a flat outer rotation curve reaching 530 km s-1, and perform, for the first time for a system of this type, a rotation-curve decomposition. We infer a dark-matter halo mass of (M200/M)=12.9+0.4-0.3, a baryon-to-halo mass ratio of 0.4+0.6-0.3 in units of the cosmological baryon fraction, and a ratio between the baryonic and dark-matter halo specific angular momentum of 1.0+0.7-0.5. Comparing these quantities with those of local galaxies, we find that ADF22.1 is indistinguishable from z=0 giant discs, pointing to the inefficiency of AGN feedback in halting disc growth. Using the Mapping Nearby Galaxies at Apache Point Observatory survey, we identify potential z=0 descendants of ADF22.1, suggesting it will evolve into an extreme (in either mass or angular momentum) early-type galaxy. Finally, we argue that cold-stream accretion, invoked to explain disc formation at z > 1, cannot simultaneously account for its size, dynamical properties, high specific angular momentum, and baryon-to-halo mass ratio. Instead, sustained accretion from the hot circumgalactic medium, either via spontaneous or fountain-driven condensation, offers a more physically plausible formation pathway.