Unifying the dynamical classification of early-type galaxies: kinematic deficits in IllustrisTNG versus observations

Abstract

We conduct a comparative analysis of galaxy kinematics using IllustrisTNG simulations and integral-field spectroscopy (IFS) observations. We identify 2,342 early-type galaxies (ETGs) from the TNG100 simulation and 236 ETGs from the TNG50 simulation, comparing them with observations from MaNGA and ATLAS3D. For these systems, we measure key kinematic parameters: the intrinsic spin parameter λR,intr (measured edge-on), the cylindrical rotational energy fraction rot, and structural mass ratios including the spheroid mass fraction fspheroid and stellar halo mass fraction fhalo. Our study reveals that standard classifiers--the λR(Re)=0.31 relation and k5 coefficient (higher-order Fourier term of velocity fields)--fail to align with observed kinematic bimodality. We propose revised thresholds: λR,intr 0.4, rot 0.5, and fspheroid 0.6, which classify galaxies into rotation-dominated (fast rotators) and random motion-dominated (slow rotators). Scaling relations from TNG enable observational estimates of rot and fspheroid. The simulations exhibit a bimodality deficit, characterized by a lack of fast rotators and suppressed λR,intr, attributed to excess galaxies with intermediate rotation and high spheroid/stellar halo mass. We introduce a novel method to estimate fhalo from IFS kinematics, though uncertainties remain.