An Increasing Stellar Baryon Fraction in Bright Galaxies at High Redshift

TL;DR

This study reveals that bright galaxies at high redshifts have increasing stellar baryon fractions, suggesting evolving star formation efficiencies and feedback mechanisms in early universe galaxy formation.

Contribution

It provides the first evidence of a significant increase in stellar baryon fraction in bright galaxies from z=4 to z=7, challenging simple galaxy growth models.

Findings

Stellar masses of bright galaxies are similar across z=4-7 but in lower mass halos at higher z.

The stellar baryon fraction increases from 5.1% at z=4 to 11.7% at z=7.

Halo masses decrease with redshift for galaxies of similar luminosity.

Abstract

Recent observations have shown that the characteristic luminosity of the rest-frame ultraviolet (UV) luminosity function does not significantly evolve at 4 < z < 7 and is approximately M*_UV ~ -21. We investigate this apparent non-evolution by examining a sample of 178 bright, M_UV < -21 galaxies at z=4 to 7, analyzing their stellar populations and host halo masses. Including deep Spitzer/IRAC imaging to constrain the rest-frame optical light, we find that M*_UV galaxies at z=4-7 have similar stellar masses of log(M/Msol)=9.6-9.9 and are thus relatively massive for these high redshifts. However, bright galaxies at z=4-7 are less massive and have younger inferred ages than similarly bright galaxies at z=2-3, even though the two populations have similar star formation rates and levels of dust attenuation. We match the abundances of these bright z=4-7 galaxies to halo mass functions from the Bolshoi Lambda-CDM simulation to estimate the halo masses. We find that the typical halo masses in ~M*_UV galaxies decrease from log(M_h/Msol)=11.9 at z=4 to log(M_h/Msol)=11.4 at z=7. Thus, although we are studying galaxies at a similar mass across multiple redshifts, these galaxies live in lower mass halos at higher redshift. The stellar baryon fraction in units of the cosmic mean Omega_b/Omega_m rises from 5.1% at z=4 to 11.7% at z=7; this evolution is significant at the ~3-sigma level. This rise does not agree with simple expectations of how galaxies grow, and implies that some effect, perhaps a diminishing efficiency of feedback, is allowing a higher fraction of available baryons to be converted into stars at high redshifts.