Characterizing the Best Cosmic Telescopes with the Millennium Simulations [CEA]

http://arxiv.org/abs/1402.6326


Certain configurations of massive structures projected along the line of sight maximize the number of detections of gravitationally lensed $z\sim10$ galaxies. We characterize such lines of sight with the \’etendue $\sigma_\mu$, the area in the source plane magnified over some threshold $\mu$. We use the Millennium I and Millennium XXL cosmological simulations to determine the frequency of high $\sigma_\mu$ beams on the sky, their properties, and efficient selection criteria. We define the best beams as having $\sigma_{\mu>3} >2000$ arcsec$^2$, for a $z\sim10$ source plane, and predict $477 \pm 21$ such beams on the sky. The total mass in the beam and $\sigma_{\mu>3}$ are strongly correlated. After controlling for total mass, we find a significant residual correlation between $\sigma_{\mu>3}$ and the number of cluster-scale halos ($>10^{14} M_\odot h^{-1}$) in the beam. Beams with $\sigma_{\mu>3} >2000$ arcsec$^2$, which should be best at lensing $z\sim10$ galaxies, are ten times more likely to contain multiple cluster-scale halos than a single cluster-scale halo. Beams containing an Abell 1689-like massive cluster halo often have additional structures along the line of sight, including at least one additional cluster-scale ($M_{200}>10^{14}M_\odot h^{-1}$) halo 28% of the time. Selecting beams with multiple, massive structures will lead to enhanced detection of the most distant and intrinsically faint galaxies.

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K. French, K. Wong, A. Zabludoff, et. al.
Thu, 27 Feb 14
22/59