Lens parameters for Gaia18cbf -- a long gravitational microlensing event in the Galactic Plane

Context: The size of the Einstein Radius in a microlensing event scales as a square root of the mass of the lens. Therefore, long-lasting microlensing events are the best candidates for massive lenses, including black holes. Aims: Here we present the analysis of the Gaia18cbf microlensing event reported by the Gaia Science Alerts system. It has exhibited a long timescale and features characteristic to the annual microlensing parallax effect. We deduce the parameters of the lens based on the derived best fitting model. Methods: We used photometric data collected by the Gaia satellite as well as the follow-up data gathered by the ground-based observatories. We investigate the range of microlensing models and use them to derive the most probable mass and distance to the lens using a Galactic model as a prior. Using known mass-brightness relation we determined how likely it is that the lens is a main sequence star. Results: This event is one of the longest ever detected, with the Einstein timescale of $t_\mathrm{E}=491.41^{+128.31}_{-84.94}$~days for the best solution and $t_\mathrm{E}=453.74^{+178.69}_{-105.74}$~days for the second-best. This translates to a lens mass of $M_\mathrm{L} = 2.91^{+6.02}_{-1.70} M_\odot$ and $M_\mathrm{L} = 1.88^{+4.40}_{-1.19} M_\odot$ respectively. The limits on the blended light suggest that this event was most likely not caused by a main sequence star, but rather by a dark remnant of stellar evolution.