The Number Densities and Stellar Populations of Massive Galaxies at 3 < z < 6: A Diverse, Rapidly Forming Population in the Early Universe

TL;DR

This study identifies and characterizes massive galaxies at redshifts 3 to 6, revealing rapid formation, diverse populations, and early quenching, providing insights into galaxy evolution in the early universe.

Contribution

First comprehensive census of massive galaxies at 3<z<6, highlighting their diverse types, rapid formation, and early quenching, with detailed bias correction and multi-wavelength analysis.

Findings

Massive galaxies emerge significantly at z~4.

Galaxies show rapid formation epochs around z~7.

A fraction of galaxies exhibit suppressed star formation by z~4.

Abstract

We present the census of massive (log(M$_{*}$/M$_{\odot}$)$\geq 11$) galaxies at $3<z<6$ identified over the COSMOS/UltraVISTA Ultra-Deep field stripes: consisting of $\approx100$ and $\approx20$ high-confidence candidates at $3<z<4$ and $4<z<6$, respectively. The $3<z<4$ population is comprised of post-starburst, UV star-forming and dusty-star forming galaxies in roughly equal fractions, while UV-star-forming galaxies dominate at $4<z<6$ . We account for various sources of biases in SED modelling, finding that the treatment of emission line contamination is essential for understanding the number densities and mass growth histories of massive galaxies at $z>3$. The significant increase in observed number densities at $z\sim4$ ($>\times$ 5 in $\lesssim600$ Myrs) implies that this is the epoch at which log(M$_{*}$/M$_{\odot}$)$\geq 11$ galaxies emerge in significant numbers, with stellar ages ($\approx500-900$ Myrs) indicating rapid formation epochs as early as $z\sim7$. Leveraging ancillary multi-wavelength datasets, we perform panchromatic SED modelling to constrain the total star-formation activity of the sample. The star-formation activity of the sample is generally consistent with being on the star-formation main sequence at the considered redshifts, with $\approx15-25\%$ of the population showing evidence of suppressed star-formation rates, indicating that quenching mechanisms are already at play by $z\sim4$. We stack available HST imaging, confirming their compact nature ($r_{e}\lesssim2.2$ kpc), consistent with expected sizes of high-$z$ star-forming galaxies. Finally, we discuss how our results are in-line with the early formation epochs and short formation timescales inferred from the fossil records of the most massive galaxies in the Universe.