| Title: |
Enhanced extra mixing in low-mass stars approaching the RGB tip and the problem of Li-rich red-clump stars. |
| Authors: |
Denissenkov, Pavel A1,2,3 (AUTHOR) pavelden@uvic.ca, Blouin, Simon1,2 (AUTHOR), Herwig, Falk1,2,3 (AUTHOR), Stott, Jacob1 (AUTHOR), Woodward, Paul R2,4 (AUTHOR) |
| Source: |
Monthly Notices of the Royal Astronomical Society. Dec2024, Vol. 535 Issue 2, p1243-1257. 15p. |
| Subject Terms: |
*CONVECTION (Astrophysics), *LOW mass stars, *STELLAR evolution, *INTERNAL waves, *RED giants |
| Abstract: |
A few per cent of red giants are enriched in lithium with |$A(\mathrm{Li}) \gt 1.5$|. Their evolutionary status has remained uncertain because these Li-rich giants can be placed both on the red giant branch (RGB) near the bump luminosity and in the red clump (RC) region. However, thanks to asteroseismology, it has been found that most of them are actually RC stars. Starting at the bump luminosity, RGB progenitors of the RC stars experience extra mixing in the radiative zone separating the H-burning shell from the convective envelope followed by a series of convective He-shell flashes at the RGB tip, known as the He-core flash. The He-core flash was proposed to cause fast extra mixing in the stars at the RGB tip that is needed for the Cameron–Fowler mechanism to produce Li. We propose that the RGB stars are getting enriched in Li by the RGB extra mixing that is getting enhanced and begins to produce Li, instead of destroying it, when the stars are approaching the RGB tip. After a discussion of several mechanisms of the RGB extra mixing, including the joint operation of rotation-driven meridional circulation and turbulent diffusion, the azimuthal magnetorotational instability (AMRI), thermohaline convection, buoyancy of magnetic flux tubes, and internal gravity waves, and based on results of (magneto-) hydrodynamics simulations and asteroseismology observations, we are inclined to conclude that it is the mechanism of the AMRI or magnetically enhanced thermohaline convection, that is most likely to support our hypothesis. [ABSTRACT FROM AUTHOR] |
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