When relics were made: vigorous stellar rotation and low dark matter content in the massive ultra-compact galaxy GS-9209 at z=4.66 (2505.06349v1)

Abstract: JWST observations uncovered a large number of massive quiescent galaxies (MQGs) at z>3, which theoretical models struggle to reproduce. Explaining the number density of such objects requires extremely high conversion efficiency of baryons into stars in early dark matter halos. Using stellar kinematics, we can investigate the processes shaping the mass assembly histories of MQGs. We present high-resolution JWST/NIRSpec integral field spectroscopy of GS-9209, a massive, compact quiescent galaxy at z=4.66 ($\log \left (M_{\ast}/M_{\odot} \right) = 10.52 \pm 0.06 $, $R_{eff} = 220 \pm 20$ pc). Full spectral fitting of the spatially resolved stellar continuum reveals a clear rotational pattern, yielding a spin parameter of $\lambda_{R_{eff}} = 0.65 \pm 0.12$. With its high degree of rotational support, this galaxy challenges the scenario of MQGs growing mainly by dry major mergers. This study suggests that at least a fraction of the earliest quiescent galaxies were fast rotators and that quenching was dynamically gentle process, preserving the stellar disc even in highly compact objects. Using Jeans anisotropic modelling (JAM) and a NFW profile, we measure a dark matter fraction of $f_{\rm DM} \left (< R_{eff} \right ) = 6.3^{+2.8}_{-1.7}%$, which is plausible given that this galaxy is extremely compact. Our findings use kinematics to independently confirm the massive nature of early quiescent galaxies, previously inferred from stellar population modelling. We suggest that GS-9209 has a similar structure to low-redshift 'relic' galaxies. However, unlike relic galaxies which have bottom-heavy initial mass functions (IMF), the dynamically inferred stellar mass-to-light ratio of GS-9209 is consistent with a Milky-Way like IMF. The kinematical properties of GS-9209 are different from those of z<1 early-type galaxies and more similar to those of recently quenched post-starburst galaxies at z>2.