The influence of external environment at cosmic noon on the subsequent evolution of galaxy stellar mass
Abstract
Connecting high-redshift galaxies to their low-redshift descendants is one of the most important and challenging tasks of galaxy evolution studies. In this work, we investigate whether incorporating high-redshift environmental factors improves the accuracy of matching high-redshift galaxies to their z0 descendants, using data from the EAGLE and MAGNETICUM simulations. Using random forest regression, we evaluate the relative importance of a set of environmental metrics at z3 in determining the stellar mass of descendant galaxies at z0. We identify the spherical overdensity within 1 cMpc (δ1,sp) as the most important environmental predictor. Tracking galaxies at z3 with similar initial stellar masses but different δ1,sp values, we find that, across all mass bins in both simulations, high-density environments produce z0 descendants with median stellar masses up to eight times higher than the descendants of galaxies in low-density environments. For galaxies with M*1010M, the difference is attributable to more merger-induced mass growth in high-density environments, whereas for higher-mass galaxies, it results from a combination of enhanced in-situ star formation and greater external mass accretion. By assessing the importance of overdensity across multiple scales and redshifts, we find that at z2, environmental factors become as important as stellar mass in predicting the stellar mass of z0 descendants. Compared to using stellar mass at z3 alone, incorporating δ1,sp reduces the scatter in the residuals between the predicted and actual stellar masses by approximately 20% in EAGLE and 35% in MAGNETICUM.
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