Astraeus III: The environment and physical properties of reionization sources

Abstract

In this work, we use the astraeus (seminumerical rAdiative tranSfer coupling of galaxy formaTion and Reionization in N-body dArk mattEr simUlationS) framework which couples galaxy formation and reionization in the first billion years. Exploring a number of models for reionization feedback and the escape fraction of ionizing radiation from the galactic environment (fesc), we quantify how the contribution of star-forming galaxies (with halo masses Mh>108.2M) to reionization depends on the radiative feedback model, fesc, and the environmental over-density. Our key findings are: (i) for constant fesc models, intermediate-mass galaxies (with halo masses of Mh109-11M and absolute UV magnitudes of MUV -15 to -20) in intermediate-density regions drive reionization; (ii) scenarios where fesc increases with decreasing halo mass shift the galaxy population driving reionization to lower-mass galaxies (Mh109.5M) with lower luminosities (MUV -16) and over-densities; (iii) reionization imprints its topology on the ionizing emissivity of low-mass galaxies (Mh109M) through radiative feedback. Low-mass galaxies experience a stronger suppression of star formation by radiative feedback and show lower ionizing emissivities in over-dense regions; (iv) a change in fesc with galaxy properties has the largest impact on the sources of reionization and their detectability, with the radiative feedback strength and environmental over-density playing a sub-dominant role; (v) JWST-surveys (with a limiting magnitude of MUV = -16) will be able to detect the galaxies providing 60-70\% ( 10\%) of reionization photons at z=7 for constant fesc models (scenarios where fesc increases with decreasing halo mass).