Optical Astrometry of Accreting Black Holes and Neutron Stars: Scientific Opportunities

TL;DR

High-precision optical astrometry can significantly advance our understanding of black holes and neutron stars by enabling accurate measurements of their distances, orbits, and masses, thus testing fundamental physics.

Contribution

This paper highlights the potential of microarcsecond optical astrometry, enabled by the Space Interferometry Mission, to improve measurements of compact objects and test theories of gravity and dense matter.

Findings

Astrometry can determine distances and proper motions with a few percent accuracy.

Mapping X-ray binary orbits allows for precise measurements of orbital inclination and compact object masses.

Astrometry at this level can lead to breakthroughs in understanding black hole and neutron star physics.

Abstract

The extreme conditions found near black holes and neutron stars provide a unique opportunity for testing physical theories. Observations of both types of compact objects can be used to probe regions of strong gravity, allowing for tests of General Relativity. Furthermore, a determination of the properties of matter at the remarkably high densities that exist within neutron stars would have important implications for nuclear and particle physics. While many of these objects are in binary systems ("X-ray binaries"), where accreting matter from the stellar companion provides a probe of the compact object, a main difficulty in making measurements that lead to definitive tests has been uncertainty about basic information such as distances to sources, orientation of their binary orbits, and masses of the compact objects. Optical astrometry at the microarcsecond level will allow for accurate determinations of distances and proper motions with precisions of a few percent and will provide an opportunity to directly map X-ray binary orbits, leading to measurements of orbital inclination and compact object masses accurate to better than 4%. Using astrometry at this unprecedented accuracy, which would be enabled by the Space Interferometry Mission ("SIM Lite"), will lead to breakthroughs in the investigations of the physics of black holes and neutron stars