This paper examines star formation (SF) in relatively massive, primarily early-type galaxies (ETGs) at z 0.1. A sample is drawn from bulge-dominated Galaxy Evolution Explorer/Sloan Digital Sky Survey (GALEX/SDSS) galaxies on the optical red sequence with strong UV excess and yet quiescent SDSS spectra. High-resolution far-UV imaging of 27 such ETGs using Hubble Space Telescope Advanced Camera for Surveys/Solar Blind Channel (ACS/SBC) reveals structured UV morphology in 93% of the sample, consistent with low-level ongoing SF (0.5 M yr-1). In 3/4 of the sample the SF is extended on galaxy scales (25-75kpc), while the rest contains smaller (5-15kpc) SF patches in the vicinity of an ETG - presumably gas-rich satellites being disrupted. Optical imaging reveals that all ETGs with galaxy-scale SF in our sample have old stellar disks (mostly S0 type). None is classified as a true elliptical. In our sample, galaxy-scale SF takes the form of UV rings of varying sizes and morphologies. For the majority of such objects we conclude that the gas needed to fuel current SF has been accreted from the intergalactic medium, probably in a prolonged, quasi-static manner, leading in some cases to additional disk buildup. The remaining ETGs with galaxy-scale SF have UV and optical morphologies consistent with minor merger-driven SF or with the final stages of SF in fading spirals. Our analysis excludes that all recent SF on the red sequence resulted from gas-rich mergers. We find further evidence that galaxy-scale SF is almost exclusively an S0 phenomenon (20% S0s have SF) by examining the overall optically red SDSS ETGs. Conclusion is that significant number of field S0s maintain or resume low-level SF because the preventive feedback is not in place or is intermittent. True ellipticals, on the other hand, stay entirely quiescent even in the field. © © 2012. The American Astronomical Society. All rights reserved..
CITATION STYLE
Salim, S., Fang, J. J., Rich, R. M., Faber, S. M., & Thilker, D. A. (2012, August 20). Galaxy-scale star formation on the red sequence: The continued growth of S0s and the quiescence of ellipticals. Astrophysical Journal. Institute of Physics Publishing. https://doi.org/10.1088/0004-637X/755/2/105
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