The average stellar population age and metallicity of intermediate-redshift quiescent galaxies

Abstract

The HectoMAP spectroscopic survey provides a unique mass-limited sample of more than 35,000 quiescent galaxies (Dn4000>1.5) covering the redshift range 0.2<z<0.6. We segregate galaxies in bins of properties based on stellar mass, Dn4000, and redshift to construct a set of high signal-to-noise spectra representing massive (M>1010\,M) quiescent population at intermediate redshift. These high-quality summed spectra enable full spectrum fitting and the related extraction of the average stellar population age and metallicity. The average galaxy age increases with the central Dn4000 as expected. The correlation is essentially invariant with stellar mass; thus Dn4000 is a robust proxy for quiescent galaxy stellar population age. HectoMAP provides the first quiescent sample at intermediate redshift comparable with z0 mass-complete datasets. Scaling relations derived from the HectoMAP summed spectra connect stellar age and metallicity with quiescent galaxy stellar mass up to z0.5. Anti-correlation between the equivalent width of the [O II] emission line and stellar age, together with the mild increase in stellar age with stellar mass, supports a broad range of timescales for the mass assembly of intermediate-redshift quiescent systems. On average, the most massive galaxies (M>1011\, M) assemble the bulk of their stars at earlier epochs. A strong increase in the average stellar metallicity with stellar mass, along with the correlation between the [O II] equivalent width and metallicity at 0.2<z<0.4, suggests that lower-mass galaxies are more likely to have recent star formation episodes; related feedback from massive stars affects the chemical enrichment of these galaxies.