MAGNUS III: Mild evolution of the total density slope in massive early-type galaxies since z1 from dynamical modeling of MUSE integral-field stellar kinematics

Abstract

We investigate the total mass density slope evolution in massive early-type galaxies (ETGs) over the last 6.5 billion years (0 < z < 0.75). We perform a detailed dynamical analysis of approximately 200 ETGs spanning the redshift range 0.24 < z < 0.75, utilizing spatially resolved stellar kinematics derived from high signal-to-noise ratio (S/N) MUSE-DEEP spectroscopy and surface brightness models from high-resolution HST imaging. We constrain mass distributions using the Jeans Anisotropic Modeling (JAM) technique coupled with Multi-Gaussian Expansion (MGE) method. To rigorously constrain evolutionary trends, we combine this intermediate-redshift dataset with a local ETG sample (z 0.05) from the MaNGA survey. We adopt dynamical constraints for the local sample derived using an identical homogeneous methodology, ensuring a strictly consistent comparison. We found that the total density profiles of the intermediate-redshift ETG sample are approximately isothermal and exhibit a median mass-weighted total density slope, <γ T>=2.19 0.01 at <z>=0.44, which is shallower than the local baseline of <γ T> = 2.26 0.01 at <z>=0.04. This structural shift corresponds to a redshift gradient of d γ T/d z ≈ -0.20 0.03, detected at 5-σ significance. We demonstrate that this trend is robust against model assumptions and persists even when restricting the analysis to high-velocity dispersion systems (σe > 150 km/s). Our findings are consistent with previous lensing-based studies and in tension with cosmological simulations. The observed steepening suggests that dissipative processes, such as gas-rich accretion and mergers, must play a non-negligible role in the late-stage assembly of massive ETGs.