Dark-ages Reionization and Galaxy Formation Simulation XX. The Ly$\alpha$ IGM transmission properties and environment of bright galaxies during the Epoch of Reionization

TL;DR

This study uses simulations to show that brighter galaxies during the Epoch of Reionization are less affected by neutral hydrogen, explaining why Ly$ ext{alpha}$ emission is mainly observed in the brightest galaxies and linking galaxy environment to Ly$ extalpha$ detectability.

Contribution

The paper introduces a model linking galaxy brightness and environment to Ly$ extalpha$ transmission during reionization, providing insights into observed Ly$ extalpha$ emission patterns.

Findings

Brighter galaxies are less affected by damping-wing absorption.

Largest ionized regions host the brightest galaxies with low Ly$ extalpha$ attenuation.

Galaxy environment influences Ly$ extalpha$ detection probability.

Abstract

The highly neutral inter-galactic medium (IGM) during the Epoch of Reionization (EoR) is expected to suppress Ly$\alpha$ emission with damping-wing absorption, causing nearly no Ly$\alpha$ detection from star-forming galaxies at $z{\sim}8$. However, spectroscopic observations of the 4 brightest galaxies (${\rm H}_{160}{\sim}25$ mag) at these redshifts do reveal prominent Ly$\alpha$ line, suggesting locally ionised IGM. In this paper, we explore the Ly$\alpha$ IGM transmission and environment of bright galaxies during the EoR using the Meraxes semi-analytic model. We find brighter galaxies to be less affected by damping-wing absorption as they are effective at ionizing surrounding neutral hydrogen. Specifically, the brightest sources (${\rm H}_{160}{\lesssim}25.5$ mag) lie in the largest ionized regions in our simulation, and have low attenuation of their Ly$\alpha$ from the IGM (optical depth ${<}1$). Fainter galaxies (25.5 mag${<}{\rm H}_{160}{<}27.5$ mag) have transmission that depends on UV luminosity, leading to a lower incidence of Ly$\alpha$ detection at fainter magnitudes. This luminosity-dependent attenuation explains why Ly$\alpha$ has only been observed in the brightest galaxies at $z{\sim}8$. Follow-up observations have revealed counterparts in the vicinity of these confirmed $z{\sim}8$ Ly$\alpha$ emitters. The environments of our modelled analogues agree with these observations in the number of nearby galaxies, which is a good indicator of whether Ly$\alpha$ can be detected among fainter galaxies. At the current observational limit, galaxies with ${\ge}2$--5 neighbours within $2'{\times}2'$ are ${\sim}2$--3 times more likely to show Ly$\alpha$ emission. JWST will discover an order of magnitude more neighbours, revealing ${\gtrsim}50$ galaxies in the largest ionizing bubbles and facilitating direct study of reionization morphology.