The Most Predictive Physical Properties for the Stellar Population Radial Profiles of Nearby Galaxies

Abstract

We present a study on the radial profiles of D4000,luminosity-weighted stellar ages τL,and luminosity-weighted stellar metallicities [Z/H]L of 3654 nearby galaxies(0.01<z<0.15)using the IFU spectroscopic data from the MaNGA survey available in the SDSS DR15,in an effort to explore the connection between median stellar population radial gradients(∇D4000,∇τL,∇[Z/H]L)out to~1.5Re and various galaxy properties,including stellar mass(M),specific star formation rate(sSFR),morphologies,and local environment. We find that M is the single most predictive physical property for∇D4000 and∇[Z/H]L. The most predictive properties for ∇τL are sSFR,and to a lesser degree,M. The environmental parameters,including local galaxy overdensities and central-satellite division,have virtually no correlation with stellar population radial profiles for the whole sample,but the ∇D4000 of star-forming satellite galaxies withM 1010M a significant positive correlation with galaxy overdensities. Galaxies with lower sSFR have on average steeper negative stellar population gradients,and this sSFR dependence is stronger for more massive star-forming galaxies. The negative correlation between the median stellar population gradients andM are best described largely as segmented relationships, whereby median gradients of galaxies with M 10(with the exact value depending on sSFR)have much weaker mass dependence than galaxies with higherM. While the dependence of the radial gradients of ages and metallicities on T-Types and central stellar mass surface densities are generally not significant,galaxies with later T-Types or lower central mass densities tend to have significantly lower D4000,youngerτL and lower[Z/H]L across the radial ranges probed in this study.