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

TL;DR

This study uses the HectoMAP survey to analyze the stellar age and metallicity of intermediate-redshift quiescent galaxies, revealing how these properties correlate with stellar mass and redshift, and providing insights into their formation and evolution.

Contribution

It presents the first intermediate-redshift quiescent galaxy sample comparable to local datasets, establishing scaling relations for stellar age and metallicity up to z~0.5.

Findings

Stellar age correlates with D_n4000 and is invariant with stellar mass.

More massive galaxies formed their stars earlier.

Lower-mass galaxies show signs of recent star formation and chemical enrichment.

Abstract

The HectoMAP spectroscopic survey provides a unique mass-limited sample of more than 35,000 quiescent galaxies ($D_n4000>1.5$) covering the redshift range $0.2<z<0.6$. We segregate galaxies in bins of properties based on stellar mass, $D_n4000$, and redshift to construct a set of high signal-to-noise spectra representing massive ($M_\ast>10^{10}\,M_\odot$) 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 D$_n4000$ as expected. The correlation is essentially invariant with stellar mass; thus $D_n4000$ is a robust proxy for quiescent galaxy stellar population age. HectoMAP provides the first quiescent sample at intermediate redshift comparable with $z\sim0$ mass-complete datasets. Scaling relations derived from the HectoMAP summed spectra connect stellar age and metallicity with quiescent galaxy stellar mass up to $z\sim0.5$. 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 ($M_\ast>10^{11}\, M_\odot$) 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.