Authors
Claudia Paladini, Fabien Baron, Alain Jorissen, J-B Le Bouquin, Bernd Freytag, Sophie Van Eck, Markus Wittkowski, Josef Hron, Andréa Chiavassa, J-P Berger, Christos Siopis, A Mayer, Gilles Sadowski, Kateryna Kravchenko, Shreeya Shetye, Franz Kerschbaum, Jacques Kluska, Sofia Ramstedt
Publication date
2018/1/18
Journal
Nature
Volume
553
Issue
7688
Pages
310-312
Publisher
Nature Publishing Group UK
Description
Convection plays a major part in many astrophysical processes, including energy transport, pulsation, dynamos and winds on evolved stars, in dust clouds and on brown dwarfs,. Most of our knowledge about stellar convection has come from studying the Sun: about two million convective cells with typical sizes of around 2,000 kilometres across are present on the surface of the Sun—a phenomenon known as granulation. But on the surfaces of giant and supergiant stars there should be only a few large (several tens of thousands of times larger than those on the Sun) convective cells, owing to low surface gravity. Deriving the characteristic properties of convection (such as granule size and contrast) for the most evolved giant and supergiant stars is challenging because their photospheres are obscured by dust, which partially masks the convective patterns. These properties can be inferred from geometric model fitting …
Scholar articles
C Paladini, F Baron, A Jorissen, JB Le Bouquin… - Nature, 2018