A new simple dynamo model for stellar activity cycle

Abstract: A new simple dynamo model for stellar activity cycle is proposed. By considering an inhomogeneous mean flow effect on turbulence, it is shown that turbulent cross helicity (velocity--magnetic-field correlation) should enter the expression of turbulent electromotive force as the coupling coefficient for the mean absolute vorticity. The inclusion of the cross-helicity effect makes the present model different from the current $\alpha$--$\Omega$-type models mainly in two points. First, in addition to the usual $\alpha$ (helicity effect) and $\beta$ (turbulent magnetic diffusivity), we consider the $\gamma$ coefficient (cross-helicity effect) as a key ingredient of the dynamo process. Second, unlike the $\alpha$ and $\beta$ coefficients, which are often treated as an adjustable parameter in the current studies, the spatiotemporal evolution of $\gamma$ coefficient is solved simultaneously with the mean magnetic-field equations. The basic scenario is as follows: In the presence of turbulent cross helicity, the toroidal field is induced by the toroidal rotation in mediation by the turbulent cross helicity. The $\alpha$ effect generates the poloidal field from the toroidal one. This poloidal field produces a turbulent cross helicity whose sign is opposite to the original one. Then a cycle of reversal completes. Eigenvalue analyses of the simplest possible present model give a butterfly diagram, which confirms the above scenario as well as the equator-ward migrations, the phase relationship between the cross helicity and magnetic fields, etc. These results suggest that the oscillation of the turbulent cross helicity is a key for the activity cycle. The reversal of the turbulent cross helicity is not the result of the magnetic-field reversal, but the cause of the latter. This new model is expected to open up the possibility of the mean-field or turbulence closure dynamo approaches.