On the nature and Galactic origin of the Be binary MWC 656. New insights from VLA, Gaia, and Fermi-LAT

TL;DR

This study reexamines the binary star MWC 656 using multi-wavelength data, providing new insights into its nature and challenging the previous black hole companion hypothesis by analyzing radio, optical, and gamma-ray observations.

Contribution

The paper presents the deepest radio map of MWC 656, analyzes its astrometric motion, and assesses gamma-ray data, offering evidence against a black hole companion and supporting alternative compact objects.

Findings

Radio detection with ambiguous emission mechanism

Optical astrometry indicates in situ formation at high Galactic latitude

No significant gamma-ray emission detected from MWC 656

Abstract

The binary star MWC 656 was initially proposed as the first confirmed system composed of a Be star and a black hole. However, recent studies have challenged this interpretation, suggesting that the compact companion is unlikely to be a black hole. In this study, we revisit the nature of MWC 656 by analyzing archival data across multiple wavelengths, including radio observations from the VLA, optical astrometry from the Gaia satellite, and high-energy $\gamma$-ray data from the Fermi-LAT. Using all available VLA observations at X-band (8.0-12.0 GHz), we produce the deepest radio map toward this system to date, with a noise level of 780 nJy beam$^{-1}$. The source MWC 656 is detected with $S_\nu=4.6\pm0.8\mu$Jy and a spectral index of $\alpha=1.2\pm1.8$, derived by sub-band imaging. The radio and X-ray luminosity ratio of MWC 656 is consistent with both the fundamental plane of accreting black holes and with the G\"udel-Benz relation for magnetically active stars, leaving the emission mechanism ambiguous. The optical astrometric results of MWC 656 indicate a peculiar velocity of $11.2\pm2.3$ km s$^{-1}$, discarding it as a runaway star. Its current location, 442 pc below the Galactic plane, implies a vertical travel time incompatible with the lifetime of a B1.5-type star. Moreover, the agreement between observed and expected motion in all three velocity components argues against a deceleration scenario, suggesting that MWC 656 likely formed in situ at high Galactic latitude. We carried out maximum likelihood analysis of Fermi-LAT data, but cannot report a significant detection of $\gamma$-ray emission from this source. These results reinforce recent evidence that challenge the black hole companion interpretation, and favor a non-BH compact object such as a white dwarf or neutron star.