Lyα emission from galaxies in the Epoch of Reionization

Abstract

The intrinsic strength of the Lyα line in young, star-forming systems makes it a special tool for studying high-redshift galaxies. However, interpreting observations remains challenging due to the complex radiative transfer involved. Here, we combine state-of-the-art hydrodynamical simulations of 'Althaea', a prototypical Lyman Break Galaxy (LBG, stellar mass M 1010 M) at z=7.2, with detailed radiative transfer computations of dust/continuum, [CII] 158 μm, and Lyα to clarify the relation between the galaxy properties and its Lyα emission. Althaea exhibits low (fα< 1\%) Lyα escape fractions and Equivalent Widths, EW 6 Angstrom for the simulated lines of sight, with a large scatter. The correlation between escape fraction and inclination is weak, as a result of the rather chaotic structure of high-redshift galaxies. Low fα values persist even if we artificially remove neutral gas around star forming regions to mimick the presence of HII regions. The high attenuation is primarily caused by dust clumps co-located with young stellar clusters. We can turn Althaea into a Lyman Alpha Emitter (LAE) only if we artificially remove dust from the clumps, yielding EWs up to 22 Angstrom. Our study suggests that the LBG-LAE duty-cycle required by recent clustering measurements poses the challenging problem of a dynamically changing dust attenuation. Finally, we find an anti-correlation between the magnitude of Lyα-[CII] line velocity shift and Lyα luminosity.