http://arxiv.org/abs/1710.05034
We study radial profiles in H$\alpha$ equivalent width and specific star formation rate (sSFR) derived from spatially-resolved SDSS-IV MaNGA spectroscopy to gain insight on the physical mechanisms that suppress star formation and determine a galaxy’s location in the SFR-$\rm M_\star$ diagram. Even within the star-forming blue cloud, the typical sSFR profile depends on stellar mass. Flat radial profiles are observed for $\rm log(M_\star/M_\odot ) < 10.5$, while star-forming galaxies of higher mass show a significant decrease in sSFR in the central regions, a likely consequence of both larger bulges and an inside-out growth history. Our primary focus is the green valley where, at all masses, we find sSFR profiles that are suppressed with respect to normal star-forming galaxies at all galactocentric distances out to 2 effective radii. The responsible quenching mechanism therefore appears to affect the entire galaxy, not simply an expanding central region. However, those galaxies in which central star formation has shut down (classified spectroscopically as central low-ionisation emission-line regions, or cLIERs) show an even stronger suppression in sSFR across the whole disc. These systems are also more suppressed than green valley galaxies with residual, central star-formation. In fact, compared to structural parameters like $\Sigma_1$ (the mass surface density within 1 kpc), central quiescence is a stronger predictor of ongoing sSFR suppression at fixed $\rm M_\star$. The green valley hosts both quiescent bulges and strongly suppressed star forming discs, supporting a scenario in which a slow quenching process affects the entire galaxy, and not just the central regions.
F. Belfiore, R. Maiolino, K. Bundy, et. al.
Tue, 17 Oct 17
58/163
Comments: 12 pages, 9 figures, submitted to MNRAS