The Cen A galaxy group: dynamical mass and missing baryons

TL;DR

This study measures the dynamical mass and baryon content of the Cen A galaxy group, revealing significant missing baryons and supporting MOND predictions without requiring additional unseen matter.

Contribution

It introduces a novel Bayesian method to analyze satellite galaxy motions and provides new estimates of the group's mass and baryon fraction within a cosmological context.

Findings

Cen A's satellite system shows significant rotational support.

The group has a baryon fraction of about 3.5%.

Cen A's baryon content aligns with MOND predictions.

Abstract

The nearby elliptical galaxy Cen A is surrounded by a flattened system of dwarf satellite galaxies with coherent motions. Using a novel Bayesian approach, we measure the mean rotation velocity $v_{\rm rot}$ and velocity dispersion $\sigma_{\rm int}$ of the satellite system. We find $v_{\rm rot}/\sigma_{\rm int} \simeq 0.7$ indicating that the satellite system has non-negligible rotational support. Using Jeans' equations, we measure a circular velocity of 258 km s$^{-1}$ and a dynamical mass of $1.2\times 10^{13}$ M$_\odot$ within 800 kpc. In a $\Lambda$CDM cosmological context, we find that the Cen A group has a baryon fraction $M_{\rm b}/M_{200}\simeq0.035$ and is missing $\sim$77$\%$ of the cosmologically available baryons. Consequently, Cen A should have a hot intergalactic medium with a mass of $\sim$8$\times$10$^{11}$ M$_\odot$, which is more than $\sim$20 times larger than current X-ray estimates. Intriguingly, The whole Cen A group lies on the baryonic Tully-Fisher relation defined by individual rotationally supported galaxies, as expected in Milgromian dynamics (MOND) with no need of missing baryons.