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LYMAN BREAK GALAXIES AT z ≈ 1.8–2.8: GALEX/NUV IMAGING OF THE SUBARU DEEP FIELD**Based on data obtained at the W.M. Keck Observatory (operated as a scientific partnership among the California Institute of Technology, the University of California, and NASA), the Subaru Telescope (operated by the National Astronomical Observatory of Japan), and the MMT Observatory (a joint facility of the University of Arizona and the Smithsonian Institution).
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https://doi.org/10.1088/0004-637x/697/2/1410Abstract
A photometric sample of 8000 V < 25.3 candidate Lyman break galaxies (LBGs) has been selected by combining Subaru/Suprime-Cam BV R C i′z′ optical data with deep GALEX/NUV imaging of the Subaru Deep Field. Follow-up spectroscopy confirmed 24 LBGs at 1.5 ≲ z ≲ 2.7. Among the optical spectra, 12 have Lyα emission with rest-frame equivalent widths of 5-60 . The success rate for identifying LBGs as NUV-dropouts at 1.5 < z < 2.7 is 86%. The rest-frame UV (1700 ) luminosity function (LF) is constructed from the photometric sample with corrections for stellar contamination and z < 1.5 interlopers (lower limits). The LF is 1.7 0.1 (1.4 0.1 with a hard upper limit on stellar contamination) times higher than those of z 2 BXs and z 3 LBGs. Three explanations were considered, and it is argued that significantly underestimating low-z contamination or effective comoving volume is unlikely: the former would be inconsistent with the spectroscopic sample at 93% confidence, and the second explanation would not resolve the discrepancy. The third scenario is that different photometric selection of the samples yields nonidentical galaxy populations, such that some BX galaxies are LBGs and vice versa. This argument is supported by a higher surface density of LBGs at all magnitudes while the redshift distribution of the two populations is nearly identical. This study, when combined with other star formation rate (SFR) density UV measurements from LBG surveys, indicates that there is a rise in the SFR density: a factor of 3-6 (3-10) increase from z 5 (z 6) to z 2, followed by a decrease to z 0. This result, along with past sub-mm studies that find a peak at z 2 in their redshift distribution, suggests that z 2 is the epoch of peak star formation. © 2009. The American Astronomical Society.
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