Morphology across cosmic time: assessing the evolution and interplay of disk and bulge-dominated galaxies in the CANDELS survey

TL;DR

This study analyzes the evolution of disk and bulge-dominated galaxies over cosmic time using a large, unbiased sample from the CANDELS survey, revealing divergent evolutionary paths driven by different physical processes.

Contribution

It introduces a morphology classification method free from visual or parametric biases and uncovers two distinct evolutionary tracks for bulge-dominated galaxies.

Findings

Bulge-dominated galaxies develop a bimodal sSFR distribution below z<1.6.

Two evolutionary tracks for bulge-dominated galaxies identified: G1 (star-forming) and G2 (quenched).

Bulge-dominated galaxies are not homogeneous but follow divergent evolution paths.

Abstract

We investigate the redshift evolution of disk and bulge-dominated galaxies using a mass-complete sample of $\sim$14,000 galaxies from the CANDELS survey, selected with $H_{\rm mag} \leq 24$, $M_{\rm stellar} \geq 10^9\,{\rm M}_\odot$, and spanning $0.2 \leq z \leq 2.4$. Adopting an unbiased morphological classification, free from visual inspection or parametric assumptions, we explore the evolution of specific star formation rate (sSFR), stellar mass, structural properties, and galaxy fractions as a function of redshift and morphology. We find that while disk and bulge-dominated galaxies exhibit similar sSFR distributions at $z \sim 2.4$, bulge-dominated systems develop a redshift-dependent bimodality below $z < 1.6$, unlike the unimodal behaviour of disks. This bimodality correlates with stellar mass: bulge-dominated galaxies with lower sSFR are significantly more massive and exhibit higher S\'ersic indices than their star-forming counterparts, despite having similar effective radii. Based on a Gaussian mixture decomposition, we identify two evolutionary tracks for bulge-dominated galaxies: G1, a long-lived, star-forming population with disk-like properties; and G2, a quenched, massive population whose prominence increases with decreasing redshift. The evolution of the star formation main sequence and morphology--mass fractions support a scenario in which G2 systems form through merger-driven transformations of massive disks. Our results indicate that bulge-dominated galaxies are not a homogeneous population, but instead follow divergent evolutionary paths driven by distinct physical mechanisms.