Is the Number of Giant Arcs in LCDM Consistent With Observations?

Abstract

We use high-resolution N-body simulations to study the galaxy-cluster cross-sections and the abundance of giant arcs in the model. Clusters are selected from the simulations using the friends-of-friends method, and their cross-sections for forming giant arcs are analyzed. The background sources are assumed to follow a uniform ellipticity distribution from 0 to 0.5 and to have an area identical to a circular source with diameter 1. We find that the optical depth scales as the source redshift approximately as τ1'' = 2.25 × 10-6/[1+(/3.14)-3.42] (0.6<<7). The amplitude is about 50% higher for an effective source diameter of 0.5. The optimal lens redshift for giant arcs with the length-to-width ratio (L/W) larger than 10 increases from 0.3 for =1, to 0.5 for =2, and to 0.7-0.8 for >3. The optical depth is sensitive to the source redshift, in qualitative agreement with Wambsganss et al. (2004). However, our overall optical depth appears to be only 10% to 70% of those from previous studies. The differences can be mostly explained by different power spectrum normalizations (σ8) used and different ways of determining the L/W ratio. Finite source size and ellipticity have modest effects on the optical depth. We also found that the number of highly magnified (with magnification |μ|>10) and ``undistorted'' images (with L/W<3) is comparable to the number of giant arcs with |μ|>10 and L/W>10. We conclude that our predicted rate of giant arcs may be lower than the observed rate, although the precise `discrepancy' is still unclear due to uncertainties both in theory and observations.

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