Unveiling the trends between dust attenuation and galaxy properties at $z \sim 2$-12 with JWST (2504.12378v1)

Abstract: A variety of dust attenuation/extinction curves have been observed in high-redshift galaxies, with mixed results regarding their correlations with global galaxy properties. These variations are likely driven by factors such as intrinsic dust properties, total dust content, and the dust-star geometry. In this work, we explore how the shape of dust attenuation curves-quantified by the UV-optical slope (S) and UV bump strength (B)-correlates with galaxy properties. Our goal is to identify the key physical mechanisms shaping attenuation curves through cosmic time. We build on arXiv:2402.05996, analyzing 173 dusty galaxies at z ~ 2-11.5, with attenuation curves inferred via SED fitting of JWST data using a modified version of BAGPIPES (arXiv:2304.11178). We investigate trends between S, B, and properties inferred from SED fitting: AV, SFR, stellar mass (M*), specific SFR (sSFR), mass-weighted stellar age (a*), ionization parameter (U), and metallicity (Z). For a subset, we also consider oxygen abundance (12 + log(O/H)), derived via Te-based methods. We find that lower AV galaxies tend to have steeper slopes and stronger UV bumps, consistent with radiative transfer predictions involving dust geometry and content. S also correlates with a* and sSFR, suggesting that strong radiation fields in young, bursty galaxies may destroy small grains, flattening the slope. B correlates with 12 + log(O/H), possibly due to metallicity-driven dust composition changes. Overall, attenuation curve shapes appear most strongly linked to: (1) redshift (dust evolution), (2) AV (RT effects), (3) a* or sSFR (radiation field), and (4) oxygen abundance (dust composition). Disentangling these effects requires spatially resolved data and theoretical models including dust evolution.