Dusty galaxies in the Epoch of Reionization: simulations

TL;DR

This study uses advanced simulations to explore dusty galaxies during the Epoch of Reionization, revealing insights into their dust properties, star formation rates, and implications for early galaxy evolution.

Contribution

It combines hydrodynamic and dust radiative transfer simulations to accurately reproduce observed properties of high-redshift dusty galaxies, providing new estimates of their physical parameters.

Findings

Star formation rate is about four times higher than previous estimates.

Dust temperature is high, around 91 K, due to intense radiation fields.

Dust formation in early galaxies appears to be inefficient, with low dust-to-metal ratios.

Abstract

The recent discovery of dusty galaxies well into the Epoch of Reionization (redshift $z>6$) poses challenging questions about the properties of the interstellar medium in these pristine systems. By combining state-of-the-art hydrodynamic and dust radiative transfer simulations, we address these questions focusing on the recently discovered dusty galaxy A2744_YD4 ($z=8.38$, Laporte et al. 2017}). We show that we can reproduce the observed spectral energy distribution (SED) only using different physical values with respect to the inferred ones by Laporte et al(2017), i.e. a star formation rate of $\mathrm{SFR} = 78\;\rm M_\odot \rm yr^{-1}$, a factor $\approx 4$ higher than deduced from simple Spectral Energy Distribution fitting. In this case we find: (a) dust attenuation (corresponding to $\tau_V=1.4$) is consistent with a Milky Way extinction curve; (b) the dust-to-metal ratio is low, $f_\mathrm{d} \sim 0.08$, implying that early dust formation is rather inefficient; (c) the luminosity-weighted dust temperature is high, $T_d=91\pm 23\, \rm K$, as a result of the intense ($\approx 100\times$ MW) interstellar radiation field; (d) due to the high $T_d$, the ALMA Band 7 detection can be explained by a limited dust mass, $M_d=1.6\times 10^6 $M$_\odot$. Finally, the high dust temperatures might solve the puzzling low infrared excess recently deduced for high-$z$ galaxies from the IRX-$\beta$ relation.