Leonid Kitchatinov, Alexander Nepomnyashchikh
Published 2019-09-26Version 1
Asteroseismology has revealed that cores of red giants rotate about one order of magnitude faster than their convective envelopes. This paper attempts an explanation for this rotational state in terms of the theory of angular momentum transport in stellar convection zones. A differential rotation model based on the theory is applied to a sequence of evolutionary states of a red giant of one solar mass. The model computations show a rotation of about ten times faster in the cores compared to the stellar surface. This rotational state is caused by the non-diffusive downward convective transport of angular momentum. The contrast in rotational rates between core and envelope increases with the radius (age) of the star. Seismologically detected scaling for the spindown of the giants' cores is also reproduced.
Comments: Submitted to MNRAS, 5 pages, 8 figures
Post-dynamical inspiral phase of common envelope evolution: Binary orbit evolution and angular momentum transport
Probing the mid-layer structure of red giants I. Mixed-mode coupling factor as a seismic diagnosis
Angular Momentum Transport by Acoustic Modes Generated in the Boundary Layer II: MHD Simulations
![QR code for arXiv:1909.11928 [astro-ph.SR]](http://oss.arxitics.com/images/favicon.svg)