New Constraints on the Origin of Surface Brightness Profile Breaks of Disk Galaxies from MaNGA

TL;DR

This study investigates the origins of surface brightness profile breaks in disk galaxies using MaNGA data, finding that star formation rate changes and stellar migration influence different break types, with galaxy spin and environment playing minimal roles.

Contribution

It provides a comparative analysis of stellar populations in various SBP types, highlighting the roles of star formation and stellar migration in break formation, and challenges the idea that spin or environment are key factors.

Findings

TII and TIII breaks are linked to radial SFR changes.

Stellar migration weakens TII profile breaks but not TIII.

Galaxy spin and environment have little impact on SBP types.

Abstract

In an effort to probe the origin of surface brightness profile (SBP) breaks widely observed in nearby disk galaxies, we carry out a comparative study of stellar population profiles of 635 disk galaxies selected from the MaNGA spectroscopic survey. We classify our galaxies into single exponential (TI), down-bending (TII) and up-bending (TIII) SBP types, and derive their spin parameters and radial profiles of age/metallicity-sensitive spectral features. Most TII (TIII) galaxies have down-bending (up-bending) star formation rate (SFR) radial profiles, implying that abrupt radial changes of SFR intensities contribute to the formation of both TII and TIII breaks. Nevertheless, a comparison between our galaxies and simulations suggests that stellar migration plays a significant role in weakening down-bending $\Sigma_{\star}$ profile breaks. While there is a correlation between the break strengths of SBPs and age/metallicity-sensitive spectral features for TII galaxies, no such correlation is found for TIII galaxies, indicating that stellar migration may not play a major role in shaping TIII breaks, as is evidenced by a good correspondence between break strengths of $\Sigma_{\star}$ and surface brightness profiles of TIII galaxies. We do not find evidence for galaxy spin being a relevant parameter for forming different SBP types, nor do we find significant differences between the asymmetries of galaxies with different SBP types, suggesting that environmental disturbances or satellite accretion in the recent past do not significantly influence the break formation. By dividing our sample into early and late morphological types, we find that galaxies with different SBP types follow nearly the same tight stellar mass-$R_{25}$ relation, which makes the hypothesis that stellar migration alone can transform SBP types from TII to TI and then to TIII highly unlikely.