Detecting the Rise and Fall of the First Stars by Their Impact on Cosmic Reionization

TL;DR

This paper presents the first large-scale reionization simulations including the earliest stars in minihalos, showing their significant impact on the timing and observational signatures of cosmic reionization.

Contribution

It introduces novel simulations that incorporate the first stars in minihalos and their radiative feedback, revealing their role in early reionization and CMB polarization signals.

Findings

Minihalo stars initiated earlier reionization.

Reionization was extended and more detectable.

Boosted CMB polarization fluctuations within Planck's sensitivity.

Abstract

The intergalactic medium was reionized before redshift z~6, most likely by starlight which escaped from early galaxies. The very first stars formed when hydrogen molecules (H2) cooled gas inside the smallest galaxies, minihalos of mass between 10^5 and 10^8 solar masses. Although the very first stars began forming inside these minihalos before redshift z~40, their contribution has, to date, been ignored in large-scale simulations of this cosmic reionization. Here we report results from the first reionization simulations to include these first stars and the radiative feedback that limited their formation, in a volume large enough to follow the crucial spatial variations that influenced the process and its observability. We show that, while minihalo stars stopped far short of fully ionizing the universe, reionization began much earlier with minihalo sources than without, and was greatly extended, which boosts the intergalactic electron-scattering optical depth and the large-angle polarization fluctuations of the cosmic microwave background significantly. Although within current WMAP uncertainties, this boost should be readily detectable by Planck. If reionization ended as late as z_ov<~7, as suggested by other observations, Planck will thereby see the signature of the first stars at high redshift, currently undetectable by other probes.