Reconstructing the redshift evolution of escaped ionizing flux from early galaxies with Planck and HST observations

Abstract

While galaxies at 6 z 10 are believed to dominate the epoch of cosmic reionization, the escape fraction of ionizing flux fesc and the photon production rate nγ from these galaxies must vary with redshift to simultaneously match CMB and low-redshift observations. We constrain fesc(z) and nγ(z) with Planck 2015 measurements of the Thomson optical depth τ, recent low multipole E-mode polarization measurements from Planck 2016, SDSS BAO data, and 3 z 10 galaxy observations. We compare different galaxy luminosity functions that are calibrated to HST observations, using both parametric and non-parametric statistical methods that marginalize over the effective clumping factor CHII, the LyC production efficiency ion, and the time-evolution of the UV limiting magnitude dMSF/dz. Using a power-law model, we find fesc 0.5 at z=8 with slope β 2.0 at 68\% confidence with little dependence on the galaxy luminosity function or data, although there is non-negligible probability for no redshift evolution β 0 or small escape fraction fesc 10-2. A non-parametric form for fesc(z) evolves significantly with redshift, yielding fesc 0.2, 0.3, 0.6 at z=6,9,12, respectively. However, a model-independent reconstruction of nγ(z) predicts a suppressed escaped photon production rate at z=9 for the latest Planck data compared to the other models, implying a quicker period of reionization. We find evidence for redshift evolution in the limiting magnitude of the galaxy luminosity function for empirical models of the galaxy luminosity function.