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ESO telescope sees surface of dim Betelgeuse

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This comparison image shows the star Betelgeuse before and after its unprecedented dimming. The observations, taken with the SPHERE instrument on ESO’s Very Large Telescope in January and December 2019, show how much the star has faded and how its apparent shape has changed.
Credit: © ESO/M. Montargès et al. / Adobe Stock

Using ESO’s Very Large Telescope (VLT), astronomers have captured the unprecedented dimming of Betelgeuse, a red supergiant star in the constellation of Orion. The stunning new images of the star’s surface show not only the fading red supergiant but also how its apparent shape is changing.

Betelgeuse has been a beacon in the night sky for stellar observers but it began to dim late last year. At the time of writing Betelgeuse is at about 36% of its normal brightness, a change noticeable even to the naked eye. Astronomy enthusiasts and scientists alike were excitedly hoping to find out more about this unprecedented dimming.

A team led by Miguel Montargès, an astronomer at KU Leuven in Belgium, has been observing the star with ESO’s Very Large Telescope since December, aiming to understand why it’s becoming fainter. Among the first observations to come out of their campaign is a stunning new image of Betelgeuse’s surface, taken late last year with the SPHERE instrument.

The team also happened to observe the star with SPHERE in January 2019, before it began to dim, giving us a before-and-after picture of Betelgeuse. Taken in visible light, the images highlight the changes occurring to the star both in brightness and in apparent shape.

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Many astronomy enthusiasts wondered if Betelgeuse’s dimming meant it was about to explode. Like all red supergiants, Betelgeuse will one day go supernova, but astronomers don’t think this is happening now. They have other hypotheses to explain what exactly is causing the shift in shape and brightness seen in the SPHERE images. “The two scenarios we are working on are a cooling of the surface due to exceptional stellar activity or dust ejection towards us,” says Montargès [1]. “Of course, our knowledge of red supergiants remains incomplete, and this is still a work in progress, so a surprise can still happen.”

Montargès and his team needed the VLT at Cerro Paranal in Chile to study the star, which is over 700 light-years away, and gather clues on its dimming. “ESO’s Paranal Observatory is one of few facilities capable of imaging the surface of Betelgeuse,” he says. Instruments on ESO’s VLT allow observations from the visible to the mid-infrared, meaning astronomers can see both the surface of Betelgeuse and the material around it. “This is the only way we can understand what is happening to the star.”

Another new image, obtained with the VISIR instrument on the VLT, shows the infrared light being emitted by the dust surrounding Betelgeuse in December 2019. These observations were made by a team led by Pierre Kervella from the Observatory of Paris in France who explained that the wavelength of the image is similar to that detected by heat cameras. The clouds of dust, which resemble flames in the VISIR image, are formed when the star sheds its material back into space.

“The phrase ‘we are all made of stardust’ is one we hear a lot in popular astronomy, but where exactly does this dust come from?” says Emily Cannon, a PhD student at KU Leuven working with SPHERE images of red supergiants. “Over their lifetimes, red supergiants like Betelgeuse create and eject vast amounts of material even before they explode as supernovae. Modern technology has enabled us to study these objects, hundreds of light-years away, in unprecedented detail giving us the opportunity to unravel the mystery of what triggers their mass loss.”

Note

[1] Betelgeuse’s irregular surface is made up of giant convective cells that move, shrink and swell. The star also pulsates, like a beating heart, periodically changing in brightness. These convection and pulsation changes in Betelgeuse are referred to as stellar activity.

More information

The team is composed of Miguel Montargès (Institute of Astronomy, KU Leuven, Belgium), Emily Cannon (Institute of Astronomy, KU Leuven, Belgium), Pierre Kervella (LESIA, Observatoire de Paris — PSL, France), Eric Lagadec (Laboratoire Lagrange, Observatoire de la Côte d’Azur, France), Faustine Cantalloube (Max-Planck-Institut für Astronomie, Heidelberg, Germany), Joel Sánchez Bermúdez (Instituto de Astronomía, Universidad Nacional Autónoma de México, Mexico City, Mexico and Max-Planck-Institut für Astronomie, Heidelberg, Germany), Andrea Dupree (Center for Astrophysics | Harvard & Smithsonian, USA), Elsa Huby (LESIA, Observatoire de Paris — PSL, France), Ryan Norris (Georgia State University, USA), Benjamin Tessore (IPAG, France), Andrea Chiavassa (Laboratoire Lagrange, Observatoire de la Côte d’Azur, France), Claudia Paladini (ESO, Chile), Agnès Lèbre (Université de Montpellier, France), Leen Decin (Institute of Astronomy, KU Leuven, Belgium), Markus Wittkowski (ESO, Germany), Gioia Rau (NASA/GSFC, USA), Arturo López Ariste (IRAP, France), Stephen Ridgway (NSF’s National Optical-Infrared Astronomy Research Laboratory, USA), Guy Perrin (LESIA, Observatoire de Paris — PSL, France), Alex de Koter (Astronomical Institute Anton Pannekoek, Amsterdam University, The Netherlands & Institute of Astronomy, KU Leuven, Belgium), Xavier Haubois (ESO, Chile).

The VISIR image was obtained as part of the NEAR science demonstration observations. NEAR (Near Earths in the AlphaCen Region) is an upgrade of VISIR, which was implemented as a time-limited experiment.

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