Abstract
ABSTRACT Different mechanisms for quenching star formation in galaxies are commonly invoked in the literature, but the relative impact of each one at different cosmic epochs is still unknown. In particular, the relation between these processes and morphological transformation remains poorly understood. In this work, we measure the effectiveness of changes in star formation rates by analysing a new parameter, the Star Formation Acceleration (SFA), as a function of galaxy morphology. This methodology is capable of identifying both bursting and quenching episodes that occurred in the preceding 300 Myr. We use morphological classification catalogues based on Deep Learning techniques. Our final sample has ∼14 200 spirals and ∼2500 ellipticals. We find that elliptical galaxies in the transition region have median shorter quenching time-scales (τ < 1 Gyr) than spirals (τ ≥ 1 Gyr). This result conforms to the scenario in which major mergers and other violent processes play a fundamental role in galaxy evolution for most ellipticals, not only quenching star formation more rapidly but also playing a role in morphological transformation. We also find that ∼two-thirds of galaxies bursting in the green valley in our sample are massive spirals ($M_\star \ge 10^{11.0}\, \mathrm{M}_\odot$) with signs of disturbance. This is in accordance with the scenario where low-mass galaxies are losing their gas in an interaction with a massive galaxy: while the former is quenching, the last is being refueled and going through a burst, showing signs of recent interaction.
Highlights
Galaxies have long been classified according to their apparent shape, ever since the seminal work by Hubble (1927) in the optical
This dichotomous behavior can be visualized in a colormagnitude diagram (CMD) with its well-known bimodality, where the blue cloud is mostly populated by star-forming spirals and the red sequence is mostly populated by passive ellipticals (e.g. Baldry et al 2004; Schawinski et al 2014; Bremer et al 2018)
We study the passage of galaxies across the color magnitude diagram with the aim of understanding the different evolutionary trajectories that galaxies of different morphologies might follow according to distinct physical processes taking place in each case
Summary
Galaxies have long been classified according to their apparent shape, ever since the seminal work by Hubble (1927) in the optical. Star formation rates (SFR), in particular, seem to correlate strongly with galaxy morphologies, with spiral galaxies hosting younger stellar populations and actively forming new stars, while elliptical galaxies are on the most part passive, with ★ This dichotomous behavior can be visualized in a colormagnitude diagram (CMD) with its well-known bimodality, where the blue cloud is mostly populated by star-forming spirals and the red sequence is mostly populated by passive ellipticals (e.g. Baldry et al 2004; Schawinski et al 2014; Bremer et al 2018). Processes responsible for the transition of galaxies through the green valley should somehow correlate with a morphological transformation for most galaxies, since the stellar populations are younger (spirals) versus older (ellipticals)
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