Building galaxies by accretion and in-situ star formation

TL;DR

This study uses cosmological simulations to analyze galaxy formation, revealing that galaxies grow through a combination of in-situ star formation and accretion, with accreted stars typically older, more metal-poor, and located in the outskirts.

Contribution

It provides new insights into the relative importance of accretion versus in-situ star formation in galaxy growth, supported by high-resolution cosmological simulations.

Findings

Accreted stellar mass fraction increases with galaxy mass.

Accreted stars are older and more metal-poor than in-situ stars.

Massive galaxies grow mainly through minor mergers.

Abstract

We examine galaxy formation in a cosmological AMR simulation, which includes two high resolution boxes, one centered on a 3 \times 10^14 M\odot cluster, and one centered on a void. We examine the evolution of 611 massive (M\ast > 10^10M\odot) galaxies. We find that the fraction of the final stellar mass which is accreted from other galaxies is between 15 and 40% and increases with stellar mass. The accreted fraction does not depend strongly on environment at a given stellar mass, but the galaxies in groups and cluster environments are older and underwent mergers earlier than galaxies in lower density environments. On average, the accreted stars are ~2.5 Gyrs older, and ~0.15 dex more metal poor than the stars formed in-situ. Accreted stellar material typically lies on the outskirts of galaxies; the average half-light radius of the accreted stars is 2.6 times larger than that of the in-situ stars. This leads to radial gradients in age and metallicity for massive galaxies, in qualitative agreement with observations. Massive galaxies grow by mergers at a rate of approximately 2.6% per Gyr. These mergers have a median (mass-weighted) mass ratio less than 0.26 \pm 0.21, with an absolute lower limit of 0.20, for galaxies with M\ast ~ 10^12 M\odot. This suggests that major mergers do not dominate in the accretion history of massive galaxies. All of these results agree qualitatively with results from SPH simulations by Oser et al. (2010, 2012).