Revealing the nature of the starburst galaxies in the z=2.4 overdensity HATLAS J0849
Abstract
Today's most massive ellipticals are proposed to originate from starbursting galaxies in z2 overdensities. To discern what triggers these starbursts, and their z=0 descendants, we performed a detailed case study of five gas-rich galaxies in the z=2.41 overdensity, HATLAS J084933.4+021443. Using 0.15" resolution CO(4-3), [C I] 1-0, and dust-continuum observations, we characterised their cold gas morphology and kinematics. We find two rotating discs, W and C, both exhibiting non-axisymmetric radial gas motions (consistent with bars). Of the two extreme starbursts, W is a lopsided, rotation-dominated disc with a rotation velocity of 520 km s-1, whereas T is most likely a late-stage merger. Combined with recent studies, we find that 42\% of gas-rich, massive starbursts in overdensities are rotation-dominated discs, a fraction not yet systematically reproduced by galaxy evolution models. Beyond z=1, disc galaxies with rotation velocities of >400 km s-1 reside almost exclusively in overdensities, consistent with early mass assembly in dense environments. By comparing to local early-type galaxies with cold gas discs, we confirm that these systems already reside in halos comparable to the most massive z0 ellipticals at the centres of groups and clusters. Despite their extreme star-formation rates, these discs lie on the same σ-SFR locus as lower-SFR field galaxies, implying that stellar feedback remains the dominant turbulence driver. We postulate that this is because inflowing gas is effectively transported through ordered streaming, such that only a small fraction of kinetic energy feeds disc-wide turbulence.
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.