Reionization in Technicolor

TL;DR

The Technicolor Dawn simulations model early universe reionization with high resolution, matching multiple observational data sets through a single calibration of ionizing photon escape fraction, revealing tensions in UV background and metal ion predictions.

Contribution

This work introduces a comprehensive, high-resolution radiation-hydrodynamic simulation suite that unifies diverse observations of reionization and galaxy evolution with minimal empirical tuning.

Findings

Successfully reproduces reionization history and galaxy properties

Identifies discrepancies in UVB amplitude and metal ion predictions

Highlights need for harder ionizing spectra in models

Abstract

We present the Technicolor Dawn simulations, a suite of cosmological radiation-hydrodynamic simulations of the first 1.2 billion years. By modeling a spatially-inhomogeneous UVB on-the-fly with 24 frequencies and resolving dark matter halos down to $10^8 M_\odot$ within 12 $h^{-1}$ Mpc volumes, our simulations unify observations of the intergalactic and circumgalactic media, galaxies, and reionization into a common framework. The only empirically-tuned parameter, the fraction $f_{\mathrm{esc,gal}}(z)$ of ionizing photons that escape the interstellar medium, is adjusted to match observations of the Lyman-$\alpha$ forest and the cosmic microwave background. With this single calibration, our simulations reproduce the history of reionization; the stellar mass-star formation rate relation of galaxies; the number density and metallicity of damped Lyman-$\alpha$ absorbers (DLAs) at $z\sim5$; the abundance of weak metal absorbers; the ultraviolet background (UVB) amplitude; and the Lyman-$\alpha$ flux power spectrum at $z=5.4$. The galaxy stellar mass and UV luminosity functions are underproduced by $\leq2\times$, suggesting an overly vigorous feedback model. The mean transmission in the Lyman-$\alpha$ forest is underproduced at $z<6$, indicating tension between measurements of the UVB amplitude and Lyman-$\alpha$ transmission. The observed SiIV column density distribution is reasonably well-reproduced ($\sim 1\sigma$ low). By contrast, CIV remains significantly underproduced despite being boosted by an intense $>4$ Ryd UVB. Solving this problem by increasing metal yields would overproduce both weak absorbers and DLA metallicities. Instead, the observed strength of high-ionization emission from high-redshift galaxies and absorption from their environments suggest that the ionizing flux from conventional stellar population models is too soft.