Betelgeuse is one of the largest stars known. At a distance of 700 light-years, this is an evolved massive star. Its present radius reaches 1000 times that of the Sun, for a mass of about 15 times our star’s. Betelgeuse will end its existence with a supernova explosion, when its core will collapse. This spectacular event could happen within the next 10 000 to 100 000 years.
Thanks to observations obtained with the ALMA interferometer at sub-millimeter wavelengths, an international team lead by Pierre Kervella (Paris Observatory) observed the radio emission of two molecules present in the atmosphere of Betelgeuse: silicon monoxyde (SiO) and carbon monoxyde (CO). These two molecules are very abundant in the universe (including on Earth) and are also present in large quantities around the supergiant.
By measuring precisely the Doppler shift of the spectral lines emitted by the two molecules, the astronomers have observed that the north-west part of the star is coming toward us (blue shifted emission) at a velocity of 5 km/s and its south-east part is going away from us (red shifted emission) at the same speed.

This is a characteristic consequence of the rotation of the star.

Due to its very large size, and in spite of a minimum velocity of 5 km/s at its equator (five times the velocity of a rifle bullet), one rotation of Betelgeuse takes approximately 30 years. This long period is due to the considerable increase of the size of the star when it became a supergiant, that led to a slow down of its rotation.
The rotation of a star influences the way it expels its material to the surrounding space. It also increases its lifetime by mixing its interior, thus bringing more material to its core. With more fuel available to maintain nuclear fusion, a rotating star therefore lasts longer. A large and bright hot spot and a dust plume are precisely aligned with the direction of the rotation axis of Betelgeuse as measured with ALMA. This remarkable coincidence suggests that the polar cap of the star is a particularly intense mass-loss region. Further observations in the coming years will make it possible to test this hypothesis and understand the underlying mechanisms.

Composition of the team :
Pierre Kervella (Paris Observatory, France), Leen Decin (KU Leuven, Belgium), Anita M. S. Richards (University of Manchester, UK), Graham M. Harper (University of Colorado, USA), Iain McDonald (University of Manchester, UK), Eamon O’Gorman (Dublin Institute for Advanced Studies, Irlande), Miguel Montargès (KU Leuven, Belgium), Ward Homan (KU Leuven, Belgium), Keiichi Ohnaka (UCN, Chile)