1. H alpha-based star formation rates in and around z similar to 0.5 EDisCS clusters
- Author
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Cooper, Jennifer R., Rudnick, Gregory H., Brammer, Gabriel G., Desjardins, Tyler, Mann, Justin L., Weiner, Benjamin J., Aragon-Salamanca, Alfonso, De Lucia, Gabriella, Desai, Vandana, Finn, Rose A., Jablonka, Pascale, Jaffe, Yara L., Moustakas, John, Sperone-Longin, Damien, Teplitz, Harry I., Vulcani, Benedetta, and Zaritsky, Dennis
- Subjects
lens-amplified survey ,main-sequence ,forming galaxies ,quiescent galaxies ,Astrophysics::Cosmology and Extragalactic Astrophysics ,formation histories ,red sequence ,post-starburst galaxies ,velocity dispersions ,galaxies: clusters: general ,environmental dependence ,galaxies: star formation ,stellar mass ,galaxies: evolution ,Astrophysics::Galaxy Astrophysics - Abstract
We investigate the role of environment on star formation rates (SFRs) of galaxies at various cosmic densities in well-studied clusters. We present the star-forming main sequence for 163 galaxies in four EDisCS clusters in the range 0.4 < z < 0.7. We use Hubble Space Telescope/Wide Field Camera 3 observations of the H alpha emission line to span three distinct local environments: the cluster core, infall region, and external field galaxies. The main sequence defined from our observations is consistent with other published H adistributions at similar redshifts but differs from those derived from star formation tracers such as 24 mu m. We find that the Ha-derived SFRs for the 67 galaxies with stellar masses greater than the mass-completeness limit of M-* > 10(9.75) M-circle dot show little dependence on environment. At face value, the similarities in the SFR distributions in the three environments may indicate that the process of finally shutting down star formation is rapid, however, the depth of our data and size of our sample make it difficult to conclusively test this scenario. Despite having significant H alpha emission, 21 galaxies are classified as UVJ-quiescent and may represent a demonstration of the quenching of star formation caught in the act.