A Variant Stellar-to-nebular Dust Attenuation Ratio on Subgalactic and Galactic Scales

Abstract

The state-of-the-art geometry models of stars/dust suggest that dust attenuation toward nebular regions (AV,gas) is always larger than that of stellar regions (AV,star). Utilizing the newly released integral field spectroscopic data from the MaNGA survey, we investigate whether and how the AV,star/AV,gas ratio varies from subgalactic to galactic scales. On a subgalactic scale, we report a stronger correlation between AV,star and AV,gas for more active HII regions. The local AV,star/AV,gas is found to have moderate nonlinear correlations with three tracers of diffuse ionized gas (DIG), as well as indicators of gas-phase metallicity and ionization. The DIG regions tend to have larger AV,star/AV,gas compared to classic HII regions excited by young OB stars. Metal-poor regions with a higher ionized level suffer much less nebular attenuation and thus have larger AV,star/AV,gas ratios. A low-AV,gas and high-AV,star/AV,gas sequence, which can be resolved into DIG-dominated and metal-poor regions, on the three BPT diagrams is found. Based on these observations, we suggest that besides the geometry of stars/dust, local physical conditions such as metallicity and ionized level also play an important role in determining the AV,star/AV,gas. On a galactic scale, the global AV,star/AV,gas ratio has strong correlations with stellar mass (M*), moderate correlations with SFR and metallicity, and weak correlations with inclination and specific SFR. Galaxies with larger M* and higher SFR that are more metal-rich tend to have smaller AV,star/AV,gas ratios. Such correlations form a decreasing trend of AV,star/AV,gas along the star-forming main sequence and mass-metallicity relation. The dust growth process accompanied by galaxy growth might be one plausible explanation for our observations.