Probing the Galactic Potential with Next-Generation Observations of Disk Stars

TL;DR

Upcoming high-precision stellar surveys will enable detailed mapping of the Milky Way's gravitational potential, significantly improving our understanding of its mass distribution through advanced statistical analysis.

Contribution

This study demonstrates that next-generation surveys can accurately recover the Galactic potential using MCMC methods, even with realistic measurement errors and non-random star sampling.

Findings

Force field can be constrained to better than 1% accuracy between 4-20 kpc.

Global, non-random star sampling does not bias potential recovery.

High-precision measurements enable detailed Galactic mass modeling.

Abstract

Near-future surveys promise a dramatic improvement in the number and precision of astrometric, photometric and spectroscopic measurements of stars in the Milky Way's disk. We examine the impact of such surveys on our understanding of the Galaxy by "observing" particle realizations of non-axisymmetric disk distributions orbiting in an axisymmetric halo with appropriate errors and then attempting to recover the underlying potential using a Markov Chain Monte Carlo (MCMC) approach. We demonstrate that the azimuthally averaged gravitational force field in the Galactic plane--and hence, to a lesser extent, the Galactic mass distribution--can be tightly constrained over a large range of radii using a variety of types of surveys so long as the error distribution of the measurements of the parallax, proper motion and radial velocity are well-understood and the disk is surveyed globally. One advantage of our method is that the target stars can be selected non-randomly in real or apparent-magnitude space to ensure just such a global sample without biasing the results. Assuming we can always measure the line-of-sight velocity of a star with at least 1 km/s precision, we demonstrate that the force field can be determined to better than ~1% for Galactocentric radii in the range R=4-20 kpc We conclude that near-future surveys, like SIM Lite, Gaia, and VERA, will provide the first precise mapping of the gravitational force field in the region of the Galactic disk.