The stellar mass function of quiescent and star-forming galaxies and its dependence on morphology in COSMOS-Web
Abstract
We study the stellar mass function (SMF) of quiescent and star-forming galaxies and its dependence on morphology in 10 redshift bins at 0.2<z<5.5 using the COSMOS2025 catalog built from 0.54 \, deg2 JWST imaging from COSMOS-Web. Galaxies are selected by type using the NUVrJ rest-frame color diagram and classified morphologically by bulge-to-total light ratio (B/T). The quiescent SMF shows rapid early build-up, with the most massive systems ( log(M/ M)11) assembled by z1 and evolving little since. The star-forming SMF evolves more slowly, following a mass-evolution scenario where galaxies grow via star formation and quench at the characteristic mass (M*/ M)10.6. Bulge systems (B/T>0.6) dominate the quiescent SMF at log(M/ M)>10 at all redshifts, while disks (B/T<0.2) dominate at log(M/ M)<9. However, most bulge-dominated galaxies are star-forming, with their fraction increasing with redshift and decreasing mass, consistent with being progenitors of quiescent bulges. We find evidence for environmental quenching onset at z3 from the upturn in the quiescent SMF at log(M/ M)<9.5, contributed by disk-dominated galaxies consistent with satellite quenching that retains disk morphologies. Number densities of log(M/ M)>10 quiescent galaxies are lower than recent literature by 0.1-0.7 dex, but agree well with simulations at 2<z<3. At z>3, simulations increasingly underpredict observations. Finally, we build an empirical model describing galaxy number density evolution by parametrizing quenching rates, baryon conversion efficiency, and bulge formation. Our model supports a scenario where star-forming galaxies grow central bulges before quenching in massive halos.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.