Estimating dust attenuation from galactic spectra. II. Stellar and gas attenuation in star-forming and diffuse ionized gas regions in MaNGA

Abstract

We investigate the dust attenuation in both stellar populations and ionized gas in kpc-scale regions in nearby galaxies, using integral field spectroscopy data from MaNGA MPL-9. We identify star-forming (HII) and diffuse ionized gas (DIG) regions from MaNGA datacubes. From the stacked spectrum of each region, we measure the stellar attenuation, E(B-V) star, using the technique developed by Li et al.(2020), as well as the gas attenuation, E(B-V) gas, from the Balmer decrement. We then examine the correlation of E(B-V) star, E(B-V) gas, E(B-V) gas-E(B-V) star and E(B-V) star/E(B-V) gas with 16 regional/global properties, and for regions with different Hα surface brightnesses ( Hα). We find a stronger correlation between E(B-V) star and E(B-V) gas in regions of higher Hα. Luminosity-weighted age (tL) is found to be the property that is the most strongly correlated with E(B-V) star, and consequently with E(B-V) gas-E(B-V) star and E(B-V) star/E(B-V) gas. At fixed Hα, 10tL is linearly and negatively correlated with E(B-V) star/E(B-V) gas at all ages. Gas-phase metallicity and ionization level are important for the attenuation in the gas. Our results indicate that the ionizing source for DIG regions is likely distributed in the outer-skirt of galaxies, while for HII regions our results can be well explained by the two-component dust model of Charlot & Fall (2000).