http://arxiv.org/abs/1402.6743
We report the detection of 18 Lyman-break candidates at z>~7.0, in the completed WFC3/IR data Hubble Frontier Fields (HFF) observations of Abell 2744 (z=0.308), plus Spitzer/IRAC data and archival ACS data. Half of these candidates fall in the range of 8 < z < 9, but no convincing detection lies beyond, despite the extreme depth and lens magnification. The sample includes a triple image system with a photometric redshift of z~7.4. This high redshift is geometrically confirmed by our lens model corresponding to deflection angles that are 12% larger than the lower-redshift systems used to calibrate the lens model at z=2.019. The majority of our high-redshift candidates are not expected to be multiply lensed given their locations in the image plane, but are magnified by factors of ~1.3-6, so that we are seeing further down the luminosity function than comparable deep field imaging. It is apparent that the redshift distribution of these sources does not smoothly extend over the full redshift range accessible at z<12, but appears to break above z=8.5. Nine candidates are clustered within a small region of 20″ across, and so it will be necessary to average over the additional HFF clusters to properly examine this potentially steep transition in galaxy density at z~8-9. The physical properties of our candidates are examined using the range of lens models developed for the HFF program by various groups including our own, for a better estimate of underlying systematics. Our spectral-energy-distribution fits for the brightest objects suggest stellar masses of ~1E9 solar masses, star-formation rates of ~5 solar masses per year, and a typical formation redshift of z<~16. The upcoming deep optical data will be helpful in extending the utility of the very deep near-infrared data and potentially enhancing the numbers of lower luminosity dropout galaxies at z>7.
W. Shu, J. Moustakas, A. Zitrin, et. al.
Fri, 28 Feb 14
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