SIMBAD references

Gravitational microlensing¹ is a powerful technique for measuring the mass of isolated and faint or non-luminous objects in the Milky Way^2,3. In most cases, however, additional observations to the photometric light curve are required to measure accurately the mass of the microlens. Long-baseline optical/infrared interferometry provides a new and efficient way to deliver such independent constraints^4–7, as demonstrated recently by first interferometric observations in microlensing event TCP J05074264+2447555 (`Kojima-1')⁸. Here we report real-time observations of gravitationally lensed arcs in rotation around a microlens, Gaia19bld⁹, made with the PIONIER instrument¹⁰ at the Very Large Telescope Interferometer. Our data allowed us to determine the angular separation and length of the arcs, as well as their rotation rate. Combining these measurements with ground-based photometric data enabled the determination of the microlens mass, M = 1.147 ± 0.029 M☉, to a very high accuracy. We anticipate interferometric microlensing to play an important future role in the mass and distance determination of isolated stellar-mass black holes^11–13 in the Galaxy, which cannot be addressed by any other technique.