We present initial results from a Ðeld survey for extremely red objects [EROs, deÐned here as (R[K@) º 6 mag] covering 154 arcmin2 of sky, from the Ðrst of seven deep, wide-Ðeld K@ images obtained as part of the Calar Alto Deep Imaging Survey (CADIS). The 5 p point source detection limits are K@ \ 20.5 mag and R \ 25.0 mag, while extended-source limits are up to 0.50È0.75 mag brighter. We identify a total of eight bright EROs with K@ ¹ 19.0 mag. Six of these bright EROs are resolved and are likely to be galaxies, while the remaining two are unresolved, with colors consistent with their being low-mass galactic stars. We derive a surface density for the six bright, extragalactic EROs of 0.039^0.016 arcmin~2, which is higher by a factor of 4 than previous values. We estimate that the volume density of bright EROs to be as high as that of nearby Seyfert galaxies.
Abstract. The emission line survey within the Calar Alto Deep Imaging Survey (CADIS) detects emission line galaxies by a scan with an imaging Fabry-Perot interferometer. It covers 5 fields of >100 each in three wavelengths windows centered on λ 700, 820, and 920 nm, and reaches to a typical limiting line flux of 3× 10 −20 W m −2 . This is the deepest emission line survey covering a field of several 100 . Galaxies between z = 0.25 and z = 1.4 are detected by prominent emission lines (from Hα to [O ]372.7) falling into the FP scans. Additional observations with a dozen medium band filters allow to establish the line identification and thus the redshift of the galaxies to better than σ z = 0.001. On the basis of a total of more than 400 emission line galaxies detected in Hα (92 galaxies), [O ]500.7 (124 galaxies), or [O ]372.7 (222 galaxies) we measure the instantaneous star formation rate (SFR) in the range 0.24 < z < 1.21. With this purely emission line selected sample we are able to reach much fainter emission line galaxies than previous, continuum-selected samples. Thus completeness corrections are much less important. Although the relative [O ] emission line strength depends on excitation and metallicity and shows strong variation, the mean line ratios yield SFR[O ] values consistent with the SFR evolution. Our results substantiates the indications from previous studies (based on small galaxy samples) that the SFR decreases by a factor of ∼20 between z = 1.2 and today. In fact, for a Ω m = 0.3, Ω λ = 0.7 cosmology, we find an exponential declineρ SFR ∝ exp(−t lookback /2.6 Gyr). This decrease of the SFR with time follows an exponential law which is compatible with the decreasing galaxy merger rate as expected from model calculations. The inferred SF density is in perfect agreement with that deduced from the FIR emission of optically selected galaxies which is explained by a large overlap between both populations. We show that self-consistent extinction corrections of both our emission lines and the UV continua lead to consistent results for the SF density.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.