The galaxy-halo connection and the dynamical evolution of a giant disc in a massive node of the Cosmic Web at z~3

TL;DR

This study combines dynamical modeling and ALMA data to analyze the dark matter halo and baryonic content of a massive, large disc galaxy at z~3, revealing an unusually high stellar-to-halo mass ratio.

Contribution

It provides new constraints on the dark matter halo and stellar mass of the Big Wheel galaxy, suggesting a more efficient stellar assembly than typical for its epoch.

Findings

The dark matter halo mass is log(M_h/M_sun)=12.11^{+0.29}_{-0.17}.

The stellar mass is log(M_*/M_sun)=11.00^{+0.11}_{-0.12}.

The stellar-to-halo mass ratio is higher than expected, indicating efficient stellar assembly.

Abstract

Recent JWST observations revealed the surprising presence of a giant and massive disc galaxy in a Cosmic Web node at z$\sim3$. This galaxy, named the Big Wheel, has a size almost three times larger than expected for typical disc galaxies at the same redshift and similar stellar masses. Constraining the origin and formation history of the Big Wheel requires knowledge of its dark matter halo properties, which are difficult to derive from JWST observations alone. Here, we investigate the dark matter halo of the Big Wheel and provide further constraints on the galaxy baryonic content, combining a physically motivated dynamical model with deep ALMA kinematical data. By using priors based on JWST photometric data and CO kinematics, we infer a dark matter halo mass of $\log (M_{h}/M_{\odot})= 12.11^{+0.29}_{-0.17}$ and a stellar mass of $\log(M_{\star}/M_{\odot})=11.00^{+0.11}_{-0.12}$, leading to a stellar-to-halo mass (SHM) ratio of $M_\star/M_h=0.06^{+0.04}_{-0.03}$. This value is significantly higher than expected from state-of-the-art empirical SHM relations. This implies that the Big Wheel may have assembled its stellar content in a much more efficient way with respect to the general galaxy population at z$\sim3$. Combined with its morphological properties, our results suggest that the Big Wheel had a tranquil recent formation history, with probably no major mergers, violent disc instabilities, or strong ejective feedback. We perform a numerical simulation of an idealised galaxy and let it evolve adiabatically for $2.5$ Gyr to demonstrate that it does not develop gravitational instabilities during its evolution that could alter its resemblance to the observed one. Although systems alike the Big Wheel are arguably rare, our results offer new constraints on the contribution of accretion and feedback to the formation history of the most massive discs within high-redshift Cosmic Web nodes.