A Search for Stellar-Mass Black Holes via Astrometric Microlensing

TL;DR

This study searches for isolated stellar-mass black holes through astrometric microlensing signals, using long-term adaptive optics observations, but finds no significant signals, providing constraints on lens masses and demonstrating the potential for future detections.

Contribution

The paper presents the first attempt to detect isolated black holes via astrometric microlensing with adaptive optics, constraining lens masses and proposing optimized observation strategies.

Findings

No significant astrometric signals detected.

Constraints placed on lens mass of OB110022, disfavoring a black hole.

Simulations show future detection feasibility with improved strategies.

Abstract

While dozens of stellar mass black holes have been discovered in binary systems, isolated black holes have eluded detection. Their presence can be inferred when they lens light from a background star. We attempt to detect the astrometric lensing signatures of three photometrically identified microlensing events, OGLE-2011-BLG-0022, OGLE-2011-BLG-0125, and OGLE-2012-BLG-0169 (OB110022, OB110125, and OB120169), located toward the Galactic Bulge. These events were selected because of their long durations, which statistically favors more massive lenses. Astrometric measurements were made over 1-2 years using laser-guided adaptive optics observations from the W. M. Keck Observatory. Lens model parameters were first constrained by the photometric light curves. The OB120169 light curve is well-fit by a single-lens model, while both OB110022 and OB110125 light curves favor binary-lens models. Using the photometric fits as prior information, no significant astrometric lensing signal was detected and all targets were consistent with linear motion. The significant lack of astrometric signal constrains the lens mass of OB110022 to 0.05-1.79 Msun in a 99.7% confidence interval, which disfavors a black hole lens. Fits to OB110125 yielded a reduced Einstein crossing time and insufficient observations during the peak, so no mass limits were obtained. Two degenerate solutions exist for OB120169, which have a lens mass between 0.2-38.8 Msun and 0.4-39.8 Msun for a 99.7% confidence interval. Follow-up observations of OB120169 will further constrain the lens mass. Based on our experience, we use simulations to design optimal astrometric observing strategies and show that, with more typical observing conditions, detection of black holes is feasible.