Dynamical mass distribution and velocity structure of the Galactic centre

TL;DR

This study uses chemo-dynamical modeling of stellar kinematics and metallicity to analyze the mass distribution and velocity structure of the Galactic centre, providing new insights into the supermassive black hole and stellar populations.

Contribution

It introduces a chemo-dynamical modeling approach to disentangle stellar populations and refine the mass profile of the Galactic centre, including the black hole mass estimate.

Findings

Black hole mass of (4.35±0.24)×10^6 solar masses.

Dark matter and variable mass-to-light ratio are negligible.

High-[M/H] population dominates over 90% of stellar density.

Abstract

The inner ~200 pc region of the Milky Way contains a nuclear stellar disc and a nuclear star cluster that are embedded in the larger Galactic bar. These stellar systems overlap spatially, which makes it challenging to separate stars that belong to the nuclear stellar systems, to deduce their internal dynamics, and to derive the central Galactic potential. Discrete stellar kinematics probe the mass distribution of a stellar system, and chemical tracers such as stellar metallicity can further separate multiple stellar populations that can have distinct kinematic properties. We took advantage of the information provided by discrete stellar kinematics and the metallicity in the Galactic centre using discrete chemo-dynamical modelling. We fitted axisymmetric Jeans models to discrete data of 4,600 stars. We fitted the stars as either one population plus a background component or as two populations plus a background that represents the bar. We tested the robustness of the inferred gravitational potential against a varying mass of the supermassive black hole, including dark matter, or a radially varying mass-to-light ratio. We obtained robust results on the fit with a single population and a background component. We obtained a supermassive black hole mass of (4.35$\pm 0.24) \times 10^6$ M$_\odot$, and we find that a dark matter component and radial variation in the mass-to-light ratio are negligible. We derived the enclosed mass profile of the inner ~60 pc and found a lower mass than reported in the literature in the region of ~5-30 pc. In our two-population fit, we found a high-[M/H] population that contributes more than 90% to the total stellar density. The properties of the high-[M/H] population are consistent with in situ formation after gas inflow from the Galactic disc via the bar. The distinct kinematic properties of the low-[M/H] population indicate a different origin. [abridged]