The Effects of Physically Unrelated Near Neighbors on the Galaxy-Galaxy Lensing Signal

Abstract

The effects of near neighbors on the galaxy-galaxy lensing signal are investigated using a suite of Monte Carlo simulations. The redshifts, luminosities, and relative coordinates for the simulated lenses were obtained from a set of galaxies with known spectroscopic redshifts and known luminosities. As expected, when all lenses are assigned a single, fixed redshift, the mean tangential shear is identically equal to the excess surface mass density, scaled by the critical surface mass density: γT = × c-1. When the lenses are assigned their observed redshifts and c is taken to be the critical surface mass density of the central lens, the relationship γT = × c-1 is violated because 90% of the near neighbors are located at redshifts significantly different from the central lenses. For a given central lens, physically unrelated near neighbors give rise to a ratio of γT to × c-1 that spans a wide range of 0.5 to 1.5 at projected distances rp 1 Mpc. The magnitude and sense of the discrepancy between γT and × c-1 are functions of both rp and the velocity dispersions of the central lenses, σv. At large rp, the difference between γT and × c-1 is, on average, much greater for low-σv central lenses than it is for high-σv central lenses.