An Evolving and Mass-dependent σsSFR–M ⋆ Relation for Galaxies.

The scatter (σ_sSFR) of the specific star formation rates of galaxies is a measure of the diversity in their star formation histories (SFHs) at a given mass. In this paper, we employ the Evolution and Assembly of GaLaxies and their Environments (EAGLE) simulations to study the dependence of the σ_sSFR of galaxies on stellar mass (M_⋆) through the σ_sSFR–M_⋆ relation in z ∼ 0–4. We find that the relation evolves with time, with the dispersion depending on both stellar mass and redshift. The models point to an evolving U-shaped form for the σ_sSFR–M_⋆ relation, with the scatter being minimal at a characteristic mass M^⋆ of 10^9.5M_⊙ and increasing both at lower and higher masses. This implies that the diversity of SFHs increases toward both the low- and high-mass ends. We find that feedback from active galactic nuclei is important for increasing the σ_sSFR for high-mass objects. On the other hand, we suggest that feedback from supernovae increases the σ_sSFR of galaxies at the low-mass end. We also find that excluding galaxies that have experienced recent mergers does not significantly affect the σ_sSFR–M_⋆ relation. Furthermore, we employ the EAGLE simulations in combination with the radiative transfer code SKIRT to evaluate the effect of SFR/stellar mass diagnostics in the σ_sSFR–M_⋆ relation, and find that the SFR/M_⋆ methodologies (e.g., SED fitting, UV+IR, UV+IRX–β) widely used in the literature to obtain intrinsic properties of galaxies have a large effect on the derived shape and normalization of the σ_sSFR–M_⋆ relation. [ABSTRACT FROM AUTHOR]