Quantifying the stellar ages of dynamically separated bulges and disks of CALIFA spiral galaxies

We employ a recently developed population-orbit superposition technique to simultaneously fit the stellar kinematic and age maps of 82 CALIFA spiral galaxies and obtain the ages of stars in different dynamical structures. We first evaluated the capabilities of this method on CALIFA-like mock data created from the Auriga simulations. The recovered mean ages of dynamically cold, warm, and hot components match the true values well, with an observational error of up to 20% in the mock age maps. For CALIFA spiral galaxies, we find that the stellar ages of the cold, warm, and hot components all increase with the stellar mass of the galaxies, from (t(cold)) over bar similar to 2.2 Gyr, (t(warm)) over bar similar to 2.3 Gyr, and (t(hot)) over bar similar to 2.6 Gyr for galaxies with stellar mass M-* < 10(10) M-circle dot, to <(t(cold))over bar> similar to 4.0 Gyr, (t(warm)) over bar similar to 5.1 Gyr, and (t(hot)) over bar similar to 5.9 Gyr for galaxies with M-* > 10(11) M-circle dot. About 80% of the galaxies in our sample have t(hot) > t(cold), and the mean values of t(hot) - t(cold) also increase with stellar mass, from 0.7(-0.2)(+0.6) Gyr in low-mass galaxies (10(8.9) M-circle dot < M-* <= 10(10.5) M-circle dot) to 1.7(-0.2)(+0.7) Gyr in high-mass galaxies (10(10.5) M-circle dot < M-* < 10(11.3) M-circle dot). The stellar age is younger in disks than in bulges, on average. This suggests that either the disks formed later and/or that they experienced a more prolonged and extensive period of star formation. Lower-mass spiral galaxies have younger bulges and younger disks, while higher-mass spiral galaxies generally have older bulges, and their disks span a wide range of ages. This is consistent with the scenario in which the bulges in more massive spirals formed earlier than those in less massive spirals.