Impact of Cosmic Variance on the Galaxy-Halo Connection for Lyman-α Emitters

Abstract

In this paper we study the impact of cosmic variance and observational uncertainties in constraining the mass and occupation fraction, f occ, of dark matter halos hosting Ly-α Emitting Galaxies (LAEs) at high redshift. To this end, we construct mock catalogs from an N-body simulation to match the typical size of observed fields at z=3.1 ( 1 deg2). In our model a dark matter halo with mass in the range M min<M h<M max can only host one detectable LAE at most. We proceed to explore the parameter space determined by M min,M max and f occ with a Markov Chain Monte-Carlo algorithm using the angular correlation function (ACF) and the LAEs number density as observational constraints. We find that the preferred minimum and maximum masses in our model span a wide range 1010.0h-1M≤ M min ≤ 1011.1h-1M , 1011.0h-1M≤ M max ≤ 1013.0h-1M; followed by a wide range in the occupation fraction 0.02≤ f occ ≤ 0.30. As a consequence the median mass, M50, of all the consistent models has a large uncertainty M50 = 3.16+9.34-2.37× 1010h-1M. However, we find that the same individual models have a relatively tight 1σ scatter around the median mass M1σ = 0.55+0.11-0.31 dex. We are also able to show that \ is uniquely determined by M min, regardless of M max. We argue that upcoming large surveys covering at least 25 deg2 should be able to put tighter constraints on M min and f occ through the LAE number density distribution width constructed over several fields of 1 deg2.