Modelling galaxy stellar mass evolution from z~0.8 to today

TL;DR

This paper models the evolution of galaxy stellar mass from redshift 0.8 to today by linking galaxy mass to dark matter halo mass, fitting observational data, and predicting mass functions up to redshift 3.

Contribution

It extends an empirical galaxy-halo mass relation to higher redshift and develops a unified model for galaxy mass evolution over cosmic time.

Findings

Low mass galaxies grow mainly through star formation since z~0.8.

Massive galaxies increase their stellar mass by a factor of ~2 through mergers since z~0.8.

Predicted stellar mass functions up to z~3 match observations.

Abstract

We apply the empirical method built for z=0 in the previous work of Wang et al. to a higher redshift, to link galaxy stellar mass directly with its hosting dark matter halo mass at z~0.8. The relation of the galaxy stellar mass and the host halo mass M_infall is constrained by fitting both the stellar mass function and the correlation functions at different stellar mass intervals of the VVDS observation, where M_infall is the mass of the hosting halo at the time when the galaxy was last the central galaxy. We find that for low mass haloes, their residing central galaxies are less massive at high redshift than those at low redshift. For high mass haloes, central galaxies in these haloes at high redshift are a bit more massive than the galaxies at low redshift. Satellite galaxies are less massive at earlier times, for any given mass of hosting haloes. Fitting both the SDSS and VVDS observations simultaneously, we also propose a unified model of the M_stars-M_infall relation, which describes the evolution of central galaxy mass as a function of time. The stellar mass of a satellite galaxy is determined by the same M_stars-M_infall relation of central galaxies at the time when the galaxy is accreted. With these models, we study the amount of galaxy stellar mass increased from z~0.8 to the present day through galaxy mergers and star formation. Low mass galaxies gain their stellar masses from z~0.8 to z=0 mainly through star formation. For galaxies of higher mass, the increase of stellar mass solely through mergers from z=0.8 can make the massive galaxies a factor ~2 larger than observed at z=0. We can also predict stellar mass functions of redshifts up to z~3, and the results are consistent with the latest observations.