Stellar populations, stellar masses and the formation of galaxy bulges and discs at $z < 3$ in CANDELS

TL;DR

This study analyzes the internal structures of high-redshift massive galaxies, revealing that bulges form from disks through mass transfer, with star formation and AGN activity linked to galaxy components.

Contribution

It provides a detailed multi-component analysis of galaxy structures at z<3, highlighting bulge formation from disks and the connection to AGN activity, which is a novel insight.

Findings

Most components are star-forming in UVJ space.

Bulges are dominated by dusty star formation.

Outer regions have higher star formation rates.

Abstract

We present a multi-component structural analysis of the internal structure of $1074$ high redshift massive galaxies at $1<z<3$ from the CANDELS HST Survey. In particular we examine galaxies best-fit by two structural components, and thus likely forming discs and bulges. We examine the stellar mass, star formation rates, and colours of both the inner `bulge' and outer `disc' components for these systems using SED information from the resolved ACS+WFC3 HST imaging. We find that the majority of both inner and outer components lie in the star-forming region of UVJ space ($68$ and $90$ per cent respectively). However, the inner portions, or the likely forming bulges, are dominated by dusty star formation. Furthermore, we show that the outer components of these systems have a higher star formation rate than their inner regions, and the ratio of star formation rate between `disc' and `bulge' increases at lower redshifts. Despite the higher star formation rate of the outer component, the stellar mass ratio of inner to outer component remains constant through this epoch. This suggests that there is mass transfer from the outer to inner components for typical two component forming systems, thus building bulges from disks. Finally, using Chandra data we find that the presence of an AGN is more common in both $1$-component spheroid-like galaxies and $2$-component systems ($13\pm3$ and $11\pm2$ per cent) than in $1$-component disc-like galaxies ($3\pm1$ per cent), demonstrating that the formation of a central inner-component likely triggers the formation of central massive black holes in these galaxies.