MaNGA DynPop -- V. The dark-matter fraction versus stellar velocity dispersion relation and stellar initial mass function variations in galaxies: dynamical models and full spectrum fitting of integral-field spectroscopy

Abstract

Using the final MaNGA sample of 10K galaxies, we investigate the dark matter fraction f DM within one half-light radius R e for about 6K galaxies with good kinematics spanning a wide range of morphologies and stellar velocity dispersion. We employ two techniques to estimate f DM: (i) Jeans Anisotropic Modelling (JAM), which performs dark matter decomposition based on stellar kinematics and (ii) comparing the total dynamical mass-to-light ratios (M/L) JAM and (M/L) SPS from Stellar Population Synthesis (SPS). We find that both methods consistently show a significant trend of increasing f DM with decreasing σ e and low f DM at larger σ e. For 235 early-type galaxies with the best models, we explore the variation of stellar initial mass function (IMF) by comparing the stellar mass-to-light ratios from JAM and SPS. We confirm that the stellar mass excess factor α IMF increases with σ e, consistent with previous studies that reported a transition from Chabrier-like to Salpeter IMF among galaxies. We show that the α IMF trend cannot be driven by M/L or IMF gradients as it persists when allowing for radial gradients in our model. We find no evidence for the total M/L increasing toward the centre. We detect weak positive correlations between α IMF and age, but no correlations with metallicity. We stack galaxy spectra according to their α IMF to search for differences in IMF-sensitive spectral features (e.g. the Na I doublet). We only find marginal evidence for such differences, which casts doubt on the validity of one or both methods to measure the IMF.