Fireworks at Cosmic Dawn: relieving BAO-CMB tensions with the Pop III.1 Flash

Abstract

A Cosmic Microwave Background (CMB) optical depth of τ 0.09, several σ in excess of the latest Planck low- EE polarization measurement, has been proposed as a way to reconcile the preference for a sub-minimal neutrino mass sum in a combined analysis with CMB and Dark Energy Spectroscopic Instrument (DESI) three-year data. Reionization, however, is not just probed by τ. It is also constrained by Lyα forest observations that indicate a late end of reionization, and the patchy kinetic Sunyaev-Zel'dovich (pkSZ) effect which prefers a short duration. We explore whether an early phase of reionization can achieve a high τ while remaining consistent with both Lyα forest and pkSZ constraints. As a concrete example, we consider supermassive Pop III.1 stars, dark-matter-powered metal-free stars proposed as progenitors of supermassive black holes. Within this framework, self-regulating ionizing feedback imposes a minimum source separation of 1 \, cMpc, consequently limiting large-scale ionization fluctuations and reducing the pkSZ power on observationally relevant scales. Our fiducial model realizes an optical depth of τ= 0.087 with a Pop III.1-driven flash ionization phase centered at z = 20, while evading the most conservative 2σ upper limits on the pkSZ signal from the most recent South Pole Telescope data release. More broadly, our findings motivate further exploration of early reionization models with weakly clustered sources as a possible resolution of tensions between BAO and CMB measurements.