# Modeling Nearly Spherical Pure-Bulge Galaxies with a Stellar   Mass-to-Light Ratio Gradient under the $\Lambda$CDM and MOND Paradigms: II.   The Orbital Anisotropy of Slow Rotators within the Effective Radius

**Authors:** Kyu-Hyun Chae, Mariangela Bernardi, Ravi K. Sheth

arXiv: 1902.09350 · 2019-04-03

## TL;DR

This study analyzes the orbital anisotropy of slow rotator galaxies within the effective radius, considering stellar mass-to-light ratio gradients under both $m f 	extLambda$CDM and MOND paradigms, revealing a preference for isotropy when marginalizing over gradients.

## Contribution

It introduces a model allowing for radial variations in stellar mass-to-light ratio and anisotropy, and compares the implications under $m f 	extLambda$CDM and MOND for galaxy dynamics.

## Key findings

- Isotropy is preferred when marginalizing over $K$.
- Radial bias correlates with low-level velocities.
- Tangential bias correlates with counter rotating cores.

## Abstract

We investigate the anisotropy of the stellar velocity dispersions within the effective radius, $R_{\rm e}$, in 24 ATLAS$^{\rm 3D}$ pure-bulge galaxies, 16 of which are kinematic slow rotators (SRs). We allow the spherical anisotropy parameter $\beta$ to be radially varying and allow a radial gradient in the stellar mass-to-light ratio ($M_\star/L$) through the parameter $K$ introduced earlier. The median anisotropy for SRs depends on $K$ as follows: $\langle\beta_{\rm m}\rangle = a + b K$ with $a=0.19\pm 0.05$, $b=-0.13\pm 0.07$ ($\Lambda$CDM) or $a=0.21\pm 0.05$, $b=-0.26\pm 0.08$ (MOND), where $\beta_{\rm m}$ refers to the radially averaged quantity. Under the $\Lambda$CDM paradigm this scaling is tied to a scaling of $\langle f_{\rm DM}\rangle = (0.16\pm 0.03) +(0.31\pm 0.06) K$, where $f_{\rm DM}$ refers to the DM fraction within a sphere of $r=R_{\rm e}$. For $K=0$ (constant $M_\star/L$), we obtain radially biased results with $\langle\beta_{\rm m}\rangle \approx 0.2$ consistent with previous results. However, marginalizing over $0 < K < 1.5$ yields $\langle\beta_{\rm m}\rangle = 0.06 ^{+0.11}_{-0.14}$ with $\langle f_{\rm DM}\rangle = 0.35 \pm 0.08$: isotropy is preferred. This isotropy hides the fact that $\beta_{\rm m}$ is correlated with kinematic features such as counter rotating cores (CRCs), kinematically distinct cores (KDCs), and low-level velocities (LVs): SRs with LVs are likely to be radially biased while SRs with CRCs are likely to be tangentially biased, and SRs with KDCs are intermediate. Existing cosmological simulations allow us to understand these results qualitatively in terms of their dynamical structures and formation histories although there exist quantitative tensions. More realistic cosmological simulations, particularly allowing for $M_\star/L$ gradients, may be required to better understand SRs.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1902.09350/full.md

## Figures

33 figures with captions in the complete paper: https://tomesphere.com/paper/1902.09350/full.md

## References

68 references — full list in the complete paper: https://tomesphere.com/paper/1902.09350/full.md

---
Source: https://tomesphere.com/paper/1902.09350