Abstract
Abstract We present a suite of 34 high-resolution cosmological zoom-in simulations consisting of thousands of haloes up to $M_{\rm halo}\sim 10^{12}\, \mathrm{M}_{\odot }$ ($M_{\ast }\sim 10^{10.5}\, \mathrm{M}_{\odot }$) at z ≥ 5 from the Feedback in Realistic Environments project. We post-process our simulations with a three-dimensional Monte Carlo dust radiative transfer code to study dust attenuation, dust emission, and dust temperature within these simulated z ≥ 5 galaxies. Our sample forms a tight correlation between infrared excess (IRX ≡ FIR/FUV) and ultraviolet (UV)-continuum slope (βUV), despite the patchy, clumpy dust geometry shown in our simulations. We find that the IRX–βUV relation is mainly determined by the shape of the attenuation law and is independent of its normalization (set by the dust-to-gas ratio). The bolometric IR luminosity (LIR) correlates with the intrinsic UV luminosity and the star formation rate (SFR) averaged over the past 10 Myr. We predict that at a given LIR, the peak wavelength of the dust spectral energy distributions for z ≥ 5 galaxies is smaller by a factor of 2 (due to higher dust temperatures on average) than at z = 0. The higher dust temperatures are driven by higher specific SFRs and SFR surface densities with increasing redshift. We derive the galaxy UV luminosity functions (UVLFs) at z = 5–10 from our simulations and confirm that a heavy attenuation is required to reproduce the observed bright-end UVLFs. We also predict the IR luminosity functions (IRLFs) and UV luminosity densities at z = 5–10. We discuss the implications of our results on current and future observations probing dust attenuation and emission in z ≥ 5 galaxies.
Highlights
Improving the constraints on the star formation rate density (SFRD) across cosmic time is important for understanding the assembly history of galaxies
Columns (a) and (b) show the rest-frame UV (1500 Å) images detected by a ‘smart camera’, decomposed into (a) light transmitted directly from stars and (b) light scattered by dust at least once [i.e. adding (a) and (b) together gives the total UV flux as viewed by a regular camera]
We compare our results with the observational data set compiled in Casey et al (2018b), which consists of the ASPECSPilot sample from Aravena et al (2016) and z ∼ 5.5 sample from Capak et al (2015) with updated measurements by Barisic et al and Casey et al We show the empirical IR excess (IRX)–βUV relation developed from local starburst galaxies in Meurer et al (1999, dashed) and the aperture-corrected relation in Takeuchi et al (2012, dotted)
Summary
Improving the constraints on the star formation rate density (SFRD) across cosmic time is important for understanding the assembly history of galaxies (see Madau & Dickinson 2014 for a recent review). C 2019 The Author(s) Published by Oxford University Press on behalf of the Royal Astronomical Society obscuration in UV-selected galaxies at z ≥ 5 is to use the empirical relationship between infrared (IR) excess, IRX ≡ FIR/FUV, and the UV-continuum slope, βUV (e.g. Bouwens et al 2015; Finkelstein et al 2015). This so-called IRX–βUV relation was first established in local compact starburst galaxies This so-called IRX–βUV relation was first established in local compact starburst galaxies (e.g. Meurer, Heckman & Calzetti 1999) and has been confirmed to hold up to z ∼ 2–3 (e.g. Reddy et al 2006, 2018; Alvarez-Marquez et al 2016; Bourne et al 2017; Fudamoto et al 2017; McLure et al 2018)
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