ZFOURGE: Using Composite Spectral Energy Distributions to Characterize Galaxy Populations at 1<z<4

Abstract

We investigate the properties of galaxies as they shut off star formation over the 4 billion years surrounding peak cosmic star formation. To do this we categorize 7000 galaxies from 1<z<4 into 90 groups based on the shape of their spectral energy distributions (SEDs) and build composite SEDs with R 50 resolution. These composite SEDs show a variety of spectral shapes and also show trends in parameters such as color, mass, star formation rate, and emission line equivalent width. Using emission line equivalent widths and strength of the 4000\ break, D(4000), we categorize the composite SEDs into five classes: extreme emission line, star-forming, transitioning, post-starburst, and quiescent galaxies. The transitioning population of galaxies show modest Hα emission (EW REST40) compared to more typical star-forming composite SEDs at 10(M/M)10.5 (EW REST80). Together with their smaller sizes (3 kpc vs. 4 kpc) and higher S\'ersic indices (2.7 vs. 1.5), this indicates that morphological changes initiate before the cessation of star formation. The transitional group shows a strong increase of over one dex in number density from z3 to z1, similar to the growth in the quiescent population, while post-starburst galaxies become rarer at z1.5. We calculate average quenching timescales of 1.6 Gyr at z1.5 and 0.9 Gyr at z2.5 and conclude that a fast quenching mechanism producing post-starbursts dominated the quenching of galaxies at early times, while a slower process has become more common since z2.