Stellar Populations of over one thousand z0.8 Galaxies from LEGA-C: Ages and Star Formation Histories from Dn4000 and Hδ

Abstract

Drawing from the LEGA-C dataset, we present the spectroscopic view of the stellar population across a large volume- and mass-selected sample of galaxies at large lookback time. We measure the 4000\ break (Dn4000) and Balmer absorption line strengths (probed by Hδ) from 1019 high-quality spectra of z=0.6 - 1.0 galaxies with M = 2 × 1010 M - 3 × 1011 M. Our analysis serves as a first illustration of the power of high-resolution, high-S/N continuum spectroscopy at intermediate redshifts as a qualitatively new tool to constrain galaxy formation models. The observed Dn4000-EW(Hδ) distribution of our sample overlaps with the distribution traced by present-day galaxies, but z 0.8 galaxies populate that locus in a fundamentally different manner. While old galaxies dominate the present-day population at all stellar masses > 2×1010 M, we see a bimodal Dn4000-EW(Hδ) distribution at z0.8, implying a bimodal light-weighted age distribution. The light-weighted age depends strongly on stellar mass, with the most massive galaxies >1×1011M being almost all older than 2 Gyr. At the same time we estimate that galaxies in this high mass range are only 3 Gyr younger than their z0.1 counterparts, at odd with pure passive evolution given a difference in lookback time of >5 Gyr; younger galaxies must grow to >1011M in the meantime, and/or small amounts of young stars must keep the light-weighted ages young. Star-forming galaxies at z0.8 have stronger Hδ absorption than present-day galaxies with the same Dn4000, implying larger short-term variations in star-formation activity.