Revisiting the Lyman Continuum Escape Crisis: Predictions for z > 6 from Local Galaxies

Abstract

The intrinsic escape fraction of ionizing Lyman continuum photons (fesc) is crucial to understand whether galaxies are capable of reionizing the neutral hydrogen in the early universe at z>6. Unfortunately, it is not possible to access fesc at z>4 with direct observations and the handful of measurements from low redshift galaxies consistently find fesc < 10%, while at least fesc ~ 10% is necessary for galaxies dominate reionization. Here, we present the first empirical prediction of fesc at z>6 by combining the (sparsely populated) relation between [OIII]/[OII] and fesc with the redshift evolution of [OIII]/[OII] as predicted from local high-z analogs selected by their Hα equivalent-width. We find fesc = 5.7-3.3+8.3% at z=6 and fesc = 10.4-6.3+15.5% at z=9 for galaxies with log(M/Msun) ~ 9.0 (errors given as 1σ). However, there is a negative correlation with stellar mass and we find up to 50% larger fesc per 0.5 dex decrease in stellar mass. The population averaged escape fraction increases according to fesc = fesc,0 ((1+z)/3)a, with fesc,0 = 2.3 0.05% and a=1.17 0.02 at z > 2 for log(M/Msun) ~ 9.0. With our empirical prediction of fesc (thus fixing an important previously unknown variable) and further reasonable assumption on clumping factor and the production efficiency of Lyman continuum photons, we conclude that the average population of galaxies is just capable to reionize the universe by z ~ 6.