A Universal Power-law Profile of Pseudo-Phase-Space Density-like Quantities in Elliptical Galaxies

Abstract

We study profiles of mass density, velocity dispersion (VD), and their combination using 2000 nearly spherical and rotation-free SDSS galaxies. For observational stellar mass density (r) we consider a range of dark matter (DM) distribution DM(r) and VD anisotropy β(r) to investigate radial stellar VD σ r(r) using the spherical Jeans equation. While mass and VD profiles vary appreciably depending on DM distribution and anisotropy, the pseudo-phase-space density-like combination (r)/σ r3(r) with total density (r)= (r)+DM(r) is nearly universal. In the optical region the minus of its logarithmic slope has a mean value of ≈ 1.86--1.90 with a galaxy-to-galaxy rms scatter of ≈ 0.04--0.06, which is a few times smaller than that of (r) profiles. The scatter of can be increased by invoking wildly varying anisotropies that are, however, less likely because they would produce too large a scatter of line-of-sight VD profiles. As an independent check of this universality we analyze stellar orbit-based dynamical models of 15 ETGs of Coma cluster provided by J. Thomas. Coma ETGs, with σr(r) replaced by the rms velocity of stars vrms(r) including net rotation, exhibit a similar universality with a slope of = 1.93 0.06. Remarkably, the inferred values of for ETGs match well the slope ≈ 1.9 predicted by N-body simulations of DM halos. We argue that the inferred universal nature of (r)/σ r3(r) cannot be fully explained by equilibrium alone, implying that some astrophysical factors conspire and/or it reflects a fundamental principle in collisionless formation processes.