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L. Yan (SIRTF Science Center, Caltech), D.J. Thompson (CalTech), B.T. Soifer (SIRTF Science Center, Caltech)
We have obtained spectroscopic redshifts for 24 sources from a sample of bright, K-selected EROs using the Keck-II telescope. These EROs have high resolution morphologies from HST and were selected with a median Ks magnitude of 18.7 and (F814W - Ks) > 4m (Yan & Thompson 2003). Among the 24 redshifts, the majority (92%) are at 0.9 < z < 1.5. We derived the rest-frame J-band luminosity function at zmedian =1.14. Our result suggests that the maximum luminosity evolution between bright EROs at z~1 and the present-day >L* massive galaxies is around 0.7~magnitude. Combining the morphologies and deep spectroscopy revealed that the 24 EROs have the following properties. (1) 86%\ of the spectra have absorption features from old stars, suggesting that the dominant stellar populations seen in the rest-frame UV are old stars. 50%\ of the sources have pure absorption lines, while the remaining 50%\ have emission lines, indicating recent star formation. We conclude that the color criterion for EROs is very effective in selecting old stellar populations at z ~1, and a large fraction of these systems with prominent old stellar populations also have recent star formation. (2) The 12 emission line systems have the same number of disk and bulge galaxies as in the remaining 12 pure absorption line systems. We conclude that spectral classes do not have a simple, direct correspondence with morphological types. (3) Three EROs could be isolated, pure passively evolving early-type galaxies at z~1. This implies that only a small fraction (10%--15%) of early-type galaxies are formed in a rapid burst of star formation at high redshifts and evolved passively since then. (4) Three EROs have very red continua and pure emission line spectra. Their redshifts and star formation rates are similar to that of HR~10. These three sources are potential candidates for dusty starbursts. (5) We identified three AGNs (13%), which is consistent with what has been found by deep Chandra observations.
The author(s) of this abstract have provided an email address for comments about the abstract: lyan@ipac.caltech.edu
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Bulletin of the American Astronomical Society, 35#5
© 2003. The American Astronomical Soceity.