Characterizing SL2S galaxy groups using the Einstein radius

Abstract

We analyzed the Einstein radius, θE, in our sample of SL2S galaxy groups, and compared it with RA (the distance from the arcs to the center of the lens), using three different approaches: 1.- the velocity dispersion obtained from weak lensing assuming a Singular Isothermal Sphere profile (θE,I), 2.- a strong lensing analytical method (θE,II) combined with a velocity dispersion-concentration relation derived from numerical simulations designed to mimic our group sample, 3.- strong lensing modeling (θE,III) of eleven groups (with four new models presented in this work) using HST and CFHT images. Finally, RA was analyzed as a function of redshift z to investigate possible correlations with L, N, and the richness-to-luminosity ratio (N/L). We found a correlation between θE and RA, but with large scatter. We estimate θE,I = (2.2 0.9) + (0.7 0.2)RA, θE,II = (0.4 1.5) + (1.1 0.4)RA, and θE,III = (0.4 1.5) + (0.9 0.3)RA for each method respectively. We found a weak evidence of anti-correlation between RA and z, with LogRA = (0.580.06) - (0.040.1)z, suggesting a possible evolution of the Einstein radius with z, as reported previously by other authors. Our results also show that RA is correlated with L and N (more luminous and richer groups have greater RA), and a possible correlation between RA and the N/L ratio. Our analysis indicates that RA is correlated with θE in our sample, making RA useful to characterize properties like L and N (and possible N/L) in galaxy groups. Additionally, we present evidence suggesting that the Einstein radius evolves with z.