JADLOVSKÝ, Daniel, Thomas GRANZER, Michael WEBER, Kateryna KRAVCHENKO, Jiří KRTIČKA, Andrea K DUPREE, Andrea CHIAVASSA, Klaus G STRASSMEIER and Katja POPPENHÄGER. The Great Dimming of Betelgeuse: The photosphere as revealed by tomography over the past 15 years. Astronomy and Astrophysics. EDP Sciences, 2024, vol. 685, May 2024, p. 1-14. ISSN 0004-6361. Available from: https://dx.doi.org/10.1051/0004-6361/202348846.
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Basic information
Original name The Great Dimming of Betelgeuse: The photosphere as revealed by tomography over the past 15 years
Authors JADLOVSKÝ, Daniel (203 Czech Republic, guarantor, belonging to the institution), Thomas GRANZER, Michael WEBER, Kateryna KRAVCHENKO, Jiří KRTIČKA (203 Czech Republic, belonging to the institution), Andrea K DUPREE, Andrea CHIAVASSA, Klaus G STRASSMEIER and Katja POPPENHÄGER.
Edition Astronomy and Astrophysics, EDP Sciences, 2024, 0004-6361.
Other information
Original language English
Type of outcome Article in a journal
Field of Study 10308 Astronomy
Country of publisher France
Confidentiality degree is not subject to a state or trade secret
WWW URL URL
Impact factor Impact factor: 6.500 in 2022
Organization unit Faculty of Science
Doi http://dx.doi.org/10.1051/0004-6361/202348846
UT WoS 001226200200008
Keywords in English stars: supergiants; stars: atmospheres; stars: mass-loss; shock waves; techniques: spectroscopic
Tags rivok
Tags International impact, Reviewed
Changed by Changed by: Mgr. Marie Šípková, DiS., učo 437722. Changed: 7/8/2024 12:15.
Abstract
Context. Betelgeuse, a red supergiant star of semi-regular variability, reached a historical minimum brightness in February 2020, known as the Great Dimming. Even though the brightness has returned to the values prior to the Great Dimming now, it continues to exhibit highly unusual behavior. Aims. Understanding the long-term atmospheric motions of Betelgeuse and its variability could be a clue to the nature of the Great Dimming and the mass-loss process in red supergiants. Our goal is to study long-term dynamics of the photosphere, including during the Great Dimming. Methods. We applied the tomographic method, which allows different layers in the stellar atmosphere to be probed in order to reconstruct depth-dependent velocity fields. The method is based on the construction of spectral masks by grouping spectral lines from specific optical depths. These masks are cross-correlated with the observed spectra to recover the velocity field inside each atmospheric layer. Results. We obtained about 2800 spectra over the past 15 yr that were observed with the STELLA robotic telescope in Tenerife. We analyzed the variability of five different layers of Betelgeuse’s photosphere. We found phase shift between the layers, as well as between the variability of velocity and photometry. The time variations of the widths of the cross-correlation function reveal propagation of two shockwaves during the Great Dimming. For about 2 yr after the dimming, the timescale of variability was different between the inner and outer photospheric layers. By 2022, all the layers seemingly started to follow a similar behavior as before the dimming, but pulsating with higher frequency corresponding with the first overtone. Conclusions. The combination of the extensive high-resolution spectroscopic data set with the tomographic method revealed the variable velocity fields in the photosphere of Betelgeuse, for the first time in such detail. We were also able to find new insights related to the Great Dimming event and its aftermath, namely the discovery of another shockwave and the subsequent rearrangement of the photosphere. Our results demonstrate that powerful shocks are the triggering mechanism for episodic mass-loss events, which may be the missing component to explain the mass-loss process in red supergiants.
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