Morphology and kinematics of orbital components in CALIFA galaxies across the Hubble sequence

Abstract

Based on the stellar orbit distribution derived from orbit-superposition Schwarzschild models, we decompose each of 250 representative present-day galaxies into four orbital components: cold with strong rotation, warm with weak rotation, hot with dominant random motion and counter-rotating (CR). We rebuild the surface brightness () of each orbital component and we present in figures and tables a quantification of their morphologies using the Sersic index n, concentration C = (0.1Re/Re) and intrinsic flattening qRe and qRmax, with Re the half-light-radius and Rmax the CALIFA data coverage. We find that: (1) kinematic hotter components are generally more concentrated and rounder than colder components, and (2) all components become more concentrated and thicker/rounder in more massive galaxies; they change from disk-like in low mass late-type galaxies to bulge-like in high-mass early type galaxies. Our findings suggest that Sersic n is not a good discriminator between rotating bulges and non-rotating bulges. The luminosity fraction of cold orbits f cold is well correlated with the photometrically-decomposed disk fraction f disk as fcold = 0.14 + 0.23fdisk. Similarly, the hot orbit fraction f hot is correlated with the bulge fraction f bulge as fhot = 0.19 + 0.31fbulge. The warm orbits mainly contribute to disks in low-mass late-type galaxies, and to bulges in high-mass early-type galaxies. The cold, warm, and hot components generally follow the same morphology (ε = 1-q Rmax) versus kinematics (σz2/Vtot2) relation as the thin disk, thick disk/pseudo bulge, and classical bulge identified from cosmological simulations.