* Astronomy

Title: A candidate z ~ 8 galaxy lensed by a foreground z ~ 1.7 group
Authors: R. L. Barone-Nugent, J. S. B. Wyithe, M. Trenti, T. Treu, P. Oesch, L. Bradley, K. Schmidt

We report the discovery of a candidate z~8 galaxy lensed by a foreground z~1.7 group, found in the pure-parallel HST images taken as part of the BoRG Survey. The system consists of a Y-dropout galaxy with m=25.92 ±0.14 which appears to be strongly lensed by a foreground group with a photometric z~1.7, which would be the highest-z deflector discovered to date. Several pieces of circumstantial evidence point toward the lensing hypothesis: 1) The z~8 dropout is close in projection to the foreground group, 2) it is slightly elongated tangentially in the direction of the putative critical curve, 3) a possible counter image is marginally detected and 4) the Y-dropout is not clustered, implying that it is intrinsically fainter that it appears, i.e. it has been magnified. We show that the configuration can be accurately reproduced by an SIE deflector and a source with a Sersic surface brightness profile. The best fit model has a deflector Einstein Radius of 1.49"+0.03"/-0.01", and the unlensed z~8 source has a Sersic index n=0.92 +0.24/-0.16 and an effective radius of r_e=0.08" ±0.01" with mAB =27.4 ±0.1 which has been magnified by a factor of 3.7 ±0.2. A non-parametric reconstruction of the source with LENSVIEW corroborates the derived source parameters. The lens model yields a group mass of 1.08 +0.10/-0.15*10^12 M_sun and a mass-to-light ratio of M/L_B=30.7 +3.7/-12.6 M_sun/L_sun within the Einstein Radius. Assuming a standard dark matter fraction of 1/3, the main deflector galaxy has a stellar mass-to-light ratio of M/L_B=2.2 +0.4/-1.1 M_sun/L_sun. If confirmed, the system provides a unique opportunity to obtain spectroscopy of a typical z~8 galaxy and an absolute measure of mass for a galaxy at z~1.7. The discovery of this candidate is qualitatively consistent with the theoretical expectation that 10% of z~8 galaxies with luminosity L>2L* are significantly magnified.

Read more (647kb, PDF)