Realistic 3D hydrodynamics simulations find significant turbulent entrainment in massive stars

F. Rizzuti*, R. Hirschi, C. Georgy, W. D. Arnett, C. Meakin, A. StJ Murphy

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

Our understanding of stellar structure and evolution coming from one-dimensional (1D) stellar models is limited by uncertainties related to multi-dimensional processes taking place in stellar interiors. 1D models, however, can now be tested and improved with the help of detailed three-dimensional (3D) hydrodynamics models, which can reproduce complex multi-dimensional processes over short timescales, thanks to the recent advances in computing resources. Among these processes, turbulent entrainment leading to mixing across convective boundaries is one of the least understood and most impactful. Here we present the results from a set of hydrodynamics simulations of the neon-burning shell in a massive star, and interpret them in the framework of the turbulent entrainment law from geophysics. Our simulations differ from previous studies in their unprecedented degree of realism in reproducing the stellar environment. Importantly, the strong entrainment found in the simulations highlights the major flaws of the current implementation of convective boundary mixing in 1D stellar models. This study therefore calls for major revisions of how convective boundaries are modelled in 1D, and in particular the implementation of entrainment in these models. This will have important implications for supernova theory, nucleosynthesis, neutron stars and black holes physics.
Original languageEnglish
Pages (from-to)4013-4019
Number of pages7
JournalMonthly Notices of the Royal Astronomical Society
Volume515
Issue number3
Early online date23 Jul 2022
DOIs
Publication statusPublished - 1 Sept 2022

Keywords / Materials (for Non-textual outputs)

  • convection
  • hydrodynamics
  • stars: evolution
  • stars: interiors
  • stars: massive
  • turbulence

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