The Heavy Metal Survey: The Evolution of Stellar Metallicities, Abundance Ratios, and Ages of Massive Quiescent Galaxies Since z~2
Abstract
We present the elemental abundances and ages of 19 massive quiescent galaxies at z1.4 and z2.1 from the Keck Heavy Metal Survey. The ultra-deep LRIS and MOSFIRE spectra were modeled using a full-spectrum stellar population fitting code with variable abundance patterns. The galaxies have iron abundances between [Fe/H] = -0.5 and -0.1 dex, with typical values of -0.2 [-0.3] at z1.4 [z2.1]. We also find a tentative σv-[Fe/H] relation at z1.4. The magnesium-to-iron ratios span [Mg/Fe]\,=0.1\,--\,0.6 dex, with typical values of 0.3 [0.5] dex at z1.4 [z2.1]. The ages imply formation redshifts of z form=2-8. Compared to quiescent galaxies at lower redshifts, we find [Fe/H] was 0.2 dex lower at z=1.4-2.1. We find no evolution in [Mg/Fe] out to z1.4, though the z2.1 galaxies are 0.2 dex enhanced compared to z=0-0.7. A comparison of these results to a chemical evolution model indicates that galaxies at higher redshift form at progressively earlier epochs and over shorter star-formation timescales, with the z2.1 galaxies forming the bulk of their stars over 150 Myr at z form4. This evolution cannot be solely attributed to an increased number of quiescent galaxies at later times; several Heavy Metal galaxies have extreme chemical properties not found in massive galaxies at z0.0-0.7. Thus, the chemical properties of individual galaxies must evolve over time. Minor mergers also cannot fully account for this evolution as they cannot increase [Fe/H], particularly in galaxy centers. Consequently, the build-up of massive quiescent galaxies since z2.1 may require further mechanisms such as major mergers and/or central star formation.
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.