Assessing differences between local galaxy dust attenuation and point source extinction within the same environments
Abstract
Dust attenuation in galaxies has often been used as a proxy for the extinction of point sources, such as supernovae, even though this approach ignores fundamental differences between the two cases. We present an analysis of the impact of geometric effects and scattering within dusty media on recovered galaxy dust properties. We use SKIRT, a radiative transfer code, to simulate observations of point sources embedded in dust clouds, as well as spiral and elliptical galaxies. We examine various galaxy morphologies, inclinations, and instrument apertures. We find that in galaxies the scattering of light into the line of sight and the presence of sources at different depths within the galaxy make attenuation fundamentally different from extinction. For a medium with intrinsic extinction slope Rv=3.068, we recover effective attenuation slopes Rve ranging from 0.5 to 7, showing that the two quantities are not analogous, even for local resolved observations. We find that Rve greatly depends on dust density, galaxy morphology, and inclination, the latter being the most significant. A single simulated galaxy, viewed from different angles, can reproduce the well-known relation between attenuation strength Ave and Rve observed for star-forming galaxy samples. An increase in dust density leads to higher Rve across all inclinations, which, assuming a correlation between stellar mass and dust density, explains the increase in Rve with mass observed in star-forming galaxies. However, we are unable to explain the differences in Rve between star-forming and quiescent high-mass galaxies. We conclude that highly attenuated regions of simulated face-on galaxies yield Rve within 10% of the intrinsic extinction slope of the medium, allowing for the distinction of different dust types. For edge-on spirals, however, the median Rve for low Ave regions appears to better approximate the extinction slope.
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