The first radial velocity measurements of a microlensing event: no evidence for the predicted binary

TL;DR

This study used high-precision radial velocity measurements to test a microlensing-predicted binary system, but found no evidence supporting the initial prediction, suggesting the lens may be a blend rather than the primary target.

Contribution

First radial velocity measurements of a microlensing event were conducted, challenging previous binary system predictions based on microlensing data.

Findings

No confirmation of the predicted binary system from radial velocities.

The lens may be a blend rather than the primary lens.

Further observations are required for definitive conclusions.

Abstract

The gravitational microlensing technique allows the discovery of exoplanets around stars distributed in the disk of the galaxy towards the bulge. However, the alignment of two stars that led to the discovery is unique over the timescale of a human life and cannot be re-observed. Moreover, the target host is often very faint and located in a crowded region. These difficulties hamper and often make impossible the follow-up of the target and study of its possible companions. Gould et al. (2013) predicted the radial-velocity curve of a binary system, OGLE-2011-BLG-0417, discovered and characterised from a microlensing event by Shin et al. (2012). We used the UVES spectrograph mounted at the VLT, ESO to derive precise radial-velocity measurements of OGLE-2011-BLG-0417. To gather high-precision on faint targets of microlensing events, we proposed to use the source star as a reference to measure the lens radial velocities. We obtained ten radial velocities on the putative V=18 lens with a dispersion of ~100 m/s, spread over one year. Our measurements do not confirm the microlensing prediction for this binary system. The most likely scenario is that the assumed V=18 mag lens is actually a blend and not the primary lens that is 2 magnitude fainter. Further observations and analyses are needed to understand the microlensing observation and infer on the nature and characteristics of the lens itself.