Early-type galaxies in the PEARS survey: Probing the stellar populations at moderate redshift

TL;DR

This study uses HST/ACS grism spectra to analyze the stellar populations of early-type galaxies at moderate redshift, revealing a strong mass-age correlation and suggesting a formation pathway bypassing the blue cloud phase.

Contribution

It provides a large, spectroscopically analyzed sample of early-type galaxies at z>0.4, extending previous work and exploring their star formation histories and formation epochs.

Findings

Mass correlates with average stellar age.

Age spread is roughly 1 Gyr, independent of mass.

Formation epoch, not timescale, correlates with galaxy mass.

Abstract

Using HST/ACS slitless grism spectra from the PEARS program, we study the stellar populations of morphologically selected early-type galaxies in the GOODS North and South fields. The sample - extracted from a visual classification of the (v2.0) HST/ACS images and restricted to redshifts z>0.4 - comprises 228 galaxies (F775W<24 ABmag) out to z~1.3 over 320 arcmin2, with a median redshift zM=0.75. This work significantly increases our previous sample from the GRAPES survey in the HUDF (18 galaxies over ~11 arcmin2; Pasquali et al. 2006b). The grism data allow us to separate the sample into `red' and `blue' spectra, with the latter comprising 15% of the total. Three different grids of models parameterising the star formation history are used to fit the low-resolution spectra. Over the redshift range of the sample - corresponding to a cosmic age between 5 and 10 Gyr - we find a strong correlation between stellar mass and average age, whereas the **spread** of ages (defined by the RMS of the distribution) is roughly ~1 Gyr and independent of stellar mass. The best-fit parameters suggest it is formation epoch and not formation timescale, that best correlates with mass in early-type galaxies. This result - along with the recently observed lack of evolution of the number density of massive galaxies - motivates the need for a channel of (massive) galaxy formation bypassing any phase in the blue cloud, as suggested by the simulations of Dekel et al. (2009).