Think inside the box: cosmic variance and large-scale conformity of high-redshift massive galaxies in the FLAMINGO simulations
Abstract
We use the highest-resolution FLAMINGO hydrodynamical simulation to quantify cosmic variance and large-scale coherence in the evolution of massive galaxies at high redshift. FLAMINGO combines a (1\,cGpc)3 volume with baryonic resolution sufficient to identify \,103 independent JWST-like survey volumes of (100\,cMpc)3, providing unprecedented statistics to characterize the extremes of cosmic variance. At z\,\,6, the total variance in the number of haloes with M200\,\,1011.5\,M (or M\,\,1010\,M) is 2--3 times the Poisson expectation, while this ratio decreases with redshift. Similarly, at z\,\,4, the variance in the most massive halo per JWST-like field is twice the Poisson prediction. We find a pronounced large-scale conformity: in volumes ranked by the stellar mass of their most massive galaxy (M,max), the stellar-to-halo mass relation and star-formation efficiency are coherently elevated or suppressed throughout the full (100\,cMpc)3 volume. When accounting for galaxies outside the volume, this signal persists only to radii 50\,cMpc, demonstrating that the detectable conformity is enhanced by the survey footprint. Moreover, M,max is a better predictor of the volume-wide efficiency of massive galaxies than the total number counts, which mainly trace clustering. Finally, the stellar fraction of the most massive galaxies peaks at f\,=\,M\,/\,(M200f b,cosmic)\,\,0.2 at z\,\,5, with a narrower dispersion in f at fixed redshift and stronger redshift evolution than commonly assumed. These results show that both cosmic variance and footprint-confined conformity must be modelled when interpreting early massive galaxy populations in JWST fields.
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