Lyman Break Galaxies at z~1 and the evolution of the dust attenuation in star-forming galaxies with the redshift

TL;DR

This study analyzes Lyman Break Galaxies at z~1, examining their dust attenuation, star formation rates, and spectral energy distributions, revealing differences between red and blue sub-classes and their contribution to cosmic star formation.

Contribution

It provides a detailed comparison of UV-selected LBGs at z~1, including their dust properties, luminosity functions, and star formation rates, highlighting differences between sub-classes and evolution with redshift.

Findings

RLBGs are UV bright dusty LIRGs with significant dust but visible stellar populations.

BLBGs have lower dust content and similar stellar populations as RLBGs.

Star formation rate estimates from UV and IR data are generally consistent, with IRX-beta method showing large dispersion.

Abstract

Ultraviolet (UV) galaxies have been selected from GALEX. The presence of a FUV-dropout in their spectral energy distributions proved to be a very complete (83.3%) but not very efficient (21.4%) tool for identifying Lyman Break Galaxies (LBGs) at z~1. We divide the LBG sample into two sub-classes: red LBGs (RLBGs) detected at 24 micron which are mainly Luminous IR Galaxies (LIRGs) and blue LBGs (BLBGs) undetected at 24 microns down to 83 microJy. Two of the RLBGs are also detected at 70 micron. The median SED of the RLBGs is similar (above lambda~1 micron) to the dusty starburst HR10. However, unlike local (U)LIRGs, RLBGs are UV bright objects. We suggest that these objects contain a large amount of dust but that some bare stellar populations are also directly visible. The median SED of the BLBGs is consistent with their containing the same stellar population as the RLBGs but with a lower dust content. The luminosity function of our LBG sample at z~1 is similar to the luminosity function of NUV-selected galaxies at the same redshift. The integrated luminosity densities of z~1 LBGs and NUV-selected galaxies are very consistent. We show that star formation rates (SFRs) estimated from UV measurements and corrected using the IRX-beta method provide average total SFR_TOT in agreement with SFR_UV + SFR_dust. However, IRX-beta-based SFR_TOT shows a large dispersion. Summing up the detected UV (1150A rest-frame) and IR-based star formation rates of the detected objects, we find that only one third of the total (i.e. UV + dust) LBG SFR resides in BLBGs and two thirds in RLBGs, even though most LBGs at z~1 are BLBGs. On the other hand, the total SFR of LBGs accounts for only 11% of the total SFR at z~1. Finally, we observe a regular decrease of L_TIR / L_FUV from z=0 to z~2 for UV-selected samples.