Abstract
ABSTRACT We present simulations of cosmic reionization and reheating from z = 18 to z = 5, investigating the role of stars (emitting soft UV-photons), nuclear black holes (BHs, with power-law spectra), X-ray binaries (XRBs, with hard X-ray dominated spectra), and the supernova-associated thermal bremsstrahlung of the diffuse interstellar medium (ISM, with soft X-ray spectra). We post-process the hydrodynamical simulation MassiveBlack-II (MBII) with multifrequency ionizing radiative transfer. The source properties are directly derived from the physical environment of MBII, and our only real free parameter is the ionizing escape fraction fesc. We find that, among the models explored here, the one with an escape fraction that decreases with decreasing redshift yields results most in line with observations, such as of the neutral hydrogen fraction and the Thomson scattering optical depth. Stars are the main driver of hydrogen reionization and consequently of the thermal history of the intergalactic medium (IGM). We obtain 〈xH ii〉 = 0.99998 at z = 6 for all source types, with volume-averaged temperatures $\langle \, T \rangle \sim 20\,000$ K. BHs are rare and negligible to hydrogen reionization, but conversely they are the only sources that can fully ionize helium, increasing local temperatures by ∼104 K. The thermal and ionization state of the neutral and lowly ionized hydrogen differs significantly with different source combinations, with ISM and (to a lesser extent) XRBs, playing a significant role and, as a consequence, determining the transition from absorption to emission of the 21-cm signal from neutral hydrogen.
Highlights
We present simulations of cosmic reionization and reheating from z = 18 to z = 5, investigating the role of stars, nuclear black holes (BHs, with power-law spectra), X-ray binaries (XRBs, with hard X-ray dominated spectra), and the supernova-associated thermal bremsstrahlung of the diffuse interstellar medium (ISM, with soft X-ray spectra)
The existence and characteristics of the last phase change of our Universe—the Epoch of Reionization (EoR, see e.g. Zaroubi 2013 for a review) has been a puzzle ever since the cosmological models of last century envisioned some sort of matter, likely hydrogen, to exist in between galaxies, which could appear as an absorption feature in the spectra of high redshift quasars (Davies & Fennison 1964; Gunn & Peterson 1965)
We first present some key qualitative findings that manifest themselves in all our results (§ 3.1), and turn to present detailed reionization histories, phase diagrams and thermal properties of the intergalactic medium (IGM) in our simulations with various combinations of different source types and escape fractions (§ 3.2)
Summary
The existence and characteristics of the last phase change of our Universe—the Epoch of Reionization (EoR, see e.g. Zaroubi 2013 for a review) has been a puzzle ever since the cosmological models of last century envisioned some sort of matter, likely hydrogen, to exist in between galaxies (an intergalactic medium, Hoyle 1948), which could appear as an absorption feature in the spectra of high redshift quasars (Davies & Fennison 1964; Gunn & Peterson 1965) Another half a century of search (e.g Penzias & Wilson 1969; Field 1972; Schneider et al 1991) has uncovered the IGM’s existence (e.g. Fan et al 2006), and coincidentally revealed the afterglow from the primordial cosmic fireball (CMB, Penzias & Wilson 1965). While XRBs dominate the X-ray output of gas-poor galaxies (Fabbiano 2006; Mineo et al 2012a), their hard spectra are not necessarily primarily accompanied by IGM ionization, but rather by heating (Fialkov et al 2014)
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