Lyman-alpha Emitters During the Early Stages of Reionization

Abstract

We investigate the potential of exploiting Lya Emitters (LAEs) to constrain the volume-weighted mean neutral hydrogen fraction of the IGM, xH, at high redshifts (specifically z~9). We use "semi-numerical'' simulations to efficiently generate density, velocity, and halo fields at z=9 in a 250 Mpc box, resolving halos with masses M>2.2e8 solar masses. We construct ionization fields corresponding to various values of xH. With these, we generate LAE luminosity functions and "counts-in-cell'' statistics. As in previous studies, we find that LAEs begin to disappear rapidly when xH > 0.5. Constraining xH(z=9) with luminosity functions is difficult due to the many uncertainties inherent in the host halo mass <--> Lya luminosity mapping. However, using a very conservative mapping, we show that the number densities derived using the six z~9 LAEs recently discovered by Stark et al. (2007) imply xH < 0.7. On a more fundamental level, these LAE number densities, if genuine, require substantial star formation in halos with M < 109 solar masses, making them unique among the current sample of observed high-z objects. Furthermore, reionization increases the apparent clustering of the observed LAEs. We show that a ``counts-in-cell'' statistic is a powerful probe of this effect, especially in the early stages of reionization. Specifically, we show that a field of view (typical of upcoming IR instruments) containing LAEs has >10% higher probability of containing more than one LAE in a xH>0.5 universe than a xH=0 universe with the same overall number density. With this statistic, a fully ionized universe can be robustly distinguished from one with xH > 0.5 using a survey containing only ~ 20--100 galaxies.