Is Betelgeuse really rotating? Synthetic ALMA observations of large-scale convection in 3D simulations of Red Supergiants

Jing-Ze Ma, Andrea Chiavassa, Selma E. de Mink, Ruggero Valli, Stephen Justham, Bernd Freytag

Published 2023-11-28Version 1

The evolved stages of massive stars are poorly understood, but invaluable constraints can be derived from spatially resolved observations of nearby red supergiants, such as Betelgeuse. ALMA observations of Betelgeuse showing a dipolar velocity field have been interpreted as evidence for a rotation rate of $v\sin i \sim 5\, \mathrm{km\, s^{-1}}$. This is two orders of magnitude larger than predicted by single-star evolution, leading to the suggestion that Betelgeuse is a binary merger product. We propose instead that the velocity field could be due to large-scale convective motions. The resulting surface velocity maps can sometimes be mistaken for rotation, especially when the turbulent motions are only partially resolved, as is the case for the current ALMA beam. We support this claim with 3D CO5BOLD simulations of non-rotating red supergiants post-processed to predict synthetic ALMA images and SiO spectra to compare with observed radial velocity maps. Our simulations show a $\sim 50\%$ chance to be interpreted as evidence for a rotation rate as high as claimed for Betelgeuse. We conclude that we need at least another ALMA observation to firmly establish whether Betelgeuse is indeed rapidly rotating. Such observations would also provide insight into the role of angular momentum and binary interaction in the late evolutionary stages. The data will further probe the structure and complex physical processes in the atmospheres of red supergiants, which are immediate progenitors of supernovae and are believed to be essential in the formation of gravitational wave sources.