Rapid Reionization by the Oligarchs: The Case for Massive, UV-Bright, Star-Forming Galaxies with High Escape Fractions

Abstract

The protagonists of cosmic reionization remain elusive. Faint star-forming galaxies are leading candidates because they are numerous and may have significant ionizing photon escape fractions (fesc). Here we update this picture via an empirical model that successfully predicts latest observations (e.g., the drop in star-formation density at z>8). We generate an ionizing spectrum for each galaxy in our model and constrain fesc using latest measurements of the reionization timeline (e.g., Lyα damping of quasars and galaxies at z>7). Assuming a constant fesc, we find MUV<-13.5 galaxies need fesc=0.21+0.06-0.04 to complete reionization. The inferred IGM neutral fraction is [0.9, 0.5, 0.1] at z=[8.2, 6.8, 6.2]0.2, i.e., the bulk of reionization transpires in 300 Myrs. Inspired by the emergent sample of Lyman Continuum (LyC) leakers that overwhelmingly displays higher-than-average star-formation surface density (), we propose a model relating fesc to and find fesc0.40.1. Since falls by ~2.5 dex between z=8 and z=0, our model explains the humble upper limits on fesc at lower redshifts and its required evolution to ~0.2 at z>6. Within this model, strikingly, <5% of galaxies with MUV<-18 (the `oligarchs') account for >80% of the reionization budget. In fact, faint sources (MUV>-16) must be relegated to a limited role to ensure high neutral fractions at z=7-8. Shallow faint-end slopes of the UV luminosity function (α>-2) and/or fesc distributions skewed toward bright galaxies produce the required late and rapid reionization. We predict LyC leakers like COLA1 (z=6.6, fesc~30%, MUV=-21.5) become increasingly common towards z~6 and that the drivers of reionization do not lie hidden across the faint-end of the luminosity function, but are already known to us. (abridged)