The physical connection between central stellar surface density and stellar spin in SAMI and MaNGA nearby galaxies

Abstract

The stellar surface density within the inner 1 kpc (1) has become a popular tool for understanding the growth of galaxies and its connection with the quenching of star formation. The emerging picture suggests that building a central dense core is a necessary condition for quenching. However, it is not clear whether changes in 1 trace changes in stellar kinematics and the growth of dispersion-dominated bulges. In this paper, we combine imaging from the Sloan Digital Sky Survey with stellar kinematics from the Sydney-AAO Multi-object Integral-field unit (SAMI) and Mapping Nearby Galaxies at Apache Point Observatory (MaNGA) surveys to quantify the correlation between 1 and the proxy for stellar spin parameter within one effective radius (λre) for 1599 nearby galaxies. We show that, on the star-forming main sequence and at fixed stellar mass, changes in 1 are mirrored by changes in λre. While forming stars, main sequence galaxies remain rotationally-dominated systems, with their 1 increasing but their stellar spin staying either constant or slightly increasing. The picture changes below the main sequence, where 1 and λre are no longer correlated. Passive systems show a narrower range of 1, but a wider range of λre compared to star-forming galaxies. Our results indicate that, from a structural point of view, passive galaxies are a more heterogeneous population than star-forming systems, and may have followed a variety of evolutionary paths. This also suggests that, if dispersion-dominated bulges still grow significantly at z0, this generally takes place during, or after, the quenching phase.