Investigating the Relativistic Motion of the Stars Near the Supermassive Black Hole in the Galactic Center

TL;DR

This study investigates the relativistic motion of stars near the supermassive black hole in the Galactic Center, introducing a new method to measure relativistic effects in stellar orbits using observational data.

Contribution

The paper presents a novel observational method employing orbital element changes to detect relativistic effects in stars near Sgr A* using a first-order post-Newtonian approximation.

Findings

Estimated black hole mass: 4.15 million solar masses.

Measured relativistic parameter {5}: 0.00088 b1 0.00080.

Method is robust against observational perturbations.

Abstract

The S-star cluster in the Galactic center allows us to study the physics close to a supermassive black hole, including distinctive dynamical tests of general relativity. Our best estimates for the mass of and the distance to Sgr A* using the three stars with the shortest period (S2, S38, and S55/S0-102) and Newtonian models are M_BH = (4.15+- 0.13 +- 0.57) x 10^6 M_sun and R_0 = 8.19 +- 0.11 +- 0.34 kpc. Additionally, we aim at a new and practical method to investigate the relativistic orbits of stars in the gravitational field near Sgr A*. We use a first-order post- Newtonian approximation to calculate the stellar orbits with a broad range of periapse distance r_p. We present a method that employs the changes in orbital elements derived from elliptical fits to different sections of the orbit. These changes are correlated with the relativistic parameter defined as {\Upsilon} = r_s/r_p (with r_s being the Schwarzschild radius) and can be used to derive {\Upsilon} from observational data. For S2 we find a value of {\Upsilon} = 0.00088 +- 0.00080, which is consistent, within the uncertainty, with the expected value of {\Upsilon} = 0.00065 derived from MBH and the orbit of S2. We argue that the derived quantity is unlikely to be dominated by perturbing influences such as noise on the derived stellar positions, field rotation, and drifts in black hole mass.