The dust-star interplay in late-type galaxies at z < 0.5: forecasts for the JWST (2110.00022v2)

Abstract: In recent years, significant growth in the amount of data available to astronomers has opened up the possibility to uncover fundamental correlations, linking the dust component of a galaxy to its star formation rate (SFR). In this paper, we re-examine these correlations, investigating the origin of the observed scatter, and the ability of the James Webb Space Telescope (JWST) to explore such relations in the early Universe. We defined a sample of about 800 normal star-forming galaxies with photometries in the range of 0.15 < $\lambda$ < 500 microns and analysed them with different spectral energy distribution (SED) fitting methods. With the SEDs extracted, we investigated the detection rate at different redshifts with the MId-Infrared instruments (MIRI) onboard the JWST. Dust luminosity (L$d$) and SFR show a strong correlation, but for SFR < 2 M$\odot$ yr$^{-1}$, the correlation scatter increases dramatically. We show that selection based on the fraction of ultraviolet (UV) emission absorbed by dust, that is, the UV extinction, greatly reduces the data dispersion. Reproducing the sensitivity of the Cosmic Evolution Early Release Science Survey (CEERS) and classifying galaxies according to their SFR and stellar mass (M$\ast$), we investigated the MIRI detection rate as a function of the physical properties of the galaxies. Fifty percent of the objects with SFR $\sim$ 1 M$\odot$yr$^{-1}$ at $z$ = 6 are detected with F770, which decreases to 20% at $z$ = 8. For such galaxies, only 5% of the subsample will be detected at 5$\sigma$ with F770 and F1000 at $z$ = 8, and only 10% with F770, F1000, and F1280 at $z$ = 6. The link between dust and star formation is complex, and many aspects remain to be fully understood. In this context, the JWST will revolutionise the field, allowing investigation of the dust--star interplay well within the epoch of reionisation.