The frequency of very young galaxies in the local Universe: I. A test for galaxy formation and cosmological models

TL;DR

This study predicts the fraction of very young galaxies in the local universe using various galaxy formation models, highlighting their potential to constrain galaxy formation theories and cosmological models.

Contribution

It introduces new predictions for VYG fractions based on different models and cosmologies, emphasizing their diagnostic power.

Findings

VYGs constitute about 1% of galaxies up to 10^10 M_sun with starbursts.

VYGs are mainly linked to recent major halo mergers.

Warm Dark Matter models predict more VYGs at low masses.

Abstract

In the local Universe, the existence of very young galaxies (VYGs), having formed at least half their stellar mass in the last 1 Gyr, is debated. We predict the present-day fraction of VYGs among central galaxies as a function of galaxy stellar mass. For this, we apply to high mass resolution Monte-Carlo halo merger trees (MCHMTs) three (one) analytical models of galaxy formation, where the ratio of stellar to halo mass (mass growth rate) is a function of halo mass and redshift. Galaxy merging is delayed until orbital decay by dynamical friction. With starbursts associated with halo mergers, our models predict typically one percent of VYGs up to galaxy masses of $10^{10}$ M$_\odot$, falling rapidly at higher masses, and VYGs are usually associated with recent major mergers of their haloes. Without these starbursts, two of the models have VYG fractions reduced by 1 or 2 dex at low or intermediate stellar masses, and VYGs are rarely associated with major halo mergers. In comparison, the state-of-the-art semi-analytical model (SAM) of Henriques et al. produces only 0.01% of VYGs at intermediate masses. Finally, the Menci et al. SAM run on MCMHTs with Warm Dark Matter cosmology generates 10 times more VYGs at masses below $10^8$ M$_\odot$ than when run with Cold Dark Matter. The wide range in these VYG fractions illustrates the usefulness of VYGs to constrain both galaxy formation and cosmological models.