Magnetically controlled stellar differential rotation near the transition from solar to anti-solar profiles

TL;DR

This study investigates how magnetic fields influence stellar differential rotation, revealing that magnetic effects favor solar-like rotation profiles and significantly impact flow patterns and magnetic cycles in stars.

Contribution

The paper demonstrates that dynamo-generated magnetic fields promote solar-like differential rotation and alter flow structures, providing new insights into stellar rotation behavior near the SL-AS transition.

Findings

Magnetic fields help produce solar-like differential rotation.

No bistable states of differential rotation observed.

Magnetic cycles influence flow patterns similarly to the Sun.

Abstract

Late-type stars rotate differentially owing to anisotropic turbulence in their outer convection zones. The rotation is called solar-like (SL) when the equator rotates fastest and anti-solar (AS) otherwise. Hydrodynamic simulations show a transition from SL to AS rotation as the influence of rotation on convection is reduced, but the opposite transition occurs at a different point in the parameter space. The system is bistable, i.e., SL and AS rotation profiles can both be stable. We study the effect of a dynamo-generated magnetic field on the large-scale flows, particularly on the possibility of bistable behavior of differential rotation. We solve the hydromagnetic equations numerically in a rotating spherical shell for a set of different radiative conductivities controlling the relative importance of convection. In agreement with earlier findings, our models display SL rotation profiles when the rotational influence on convection is strong and a transition to AS when the rotational influence decreases. We find that dynamo-generated magnetic fields help to produce SL differential rotation compared to the hydrodynamic simulations. We do not observe any bistable states of differential rotation. In the AS cases we get coherent single-cell meridional circulation, whereas in SL cases we get multi-cellular patterns. In both cases, we obtain poleward circulation near the surface with a magnitude close to that observed in the Sun. Moreover, both differential rotation and meridional circulation have significant magnetic cycle-related variations that are similar in strength to those of the Sun. Purely hydrodynamic simulations of differential rotation and meridional circulation are shown to be of limited relevance as magnetic fields, self-consistently generated by dynamo action, significantly affect the flows.