Small-scale magnetic fields on late-type M-dwarfs

Abstract

We performed kinematic studies of the evolution of small-scale magnetic fields in the surface laters of M-dwarfs. We solved the induction equation for a prescribed velocity field, magnetic Reynolds number, and boundary conditions in a Cartesian box, representing a volume comprising the optically thin stellar atmosphere and the uppermost part of the optically thick convective envelope. The velocity field is spatially and temporally variable, and stems from detailed radiation-hydrodynamics simulations of convectione flows in a proto-typical late-type M-dwarf. We find dynamo action for large magnetic Reynolds numbers. Growth time scales of the magnetic field is comparable to the convective turn-over time scale (approximately 150 seconds). The convective velocity field concentrates the magnetic field in sheets and tubular structures in the inter-granular down-flows. Scaling from solar conditions suggests that field strengths as high as 20 kG might be reached locally. Perhps surprisingly, the magnetic Reynolds number is of the order unity in the surface layers of cooler M-dwarfs, rendering the dynamo inoperative. In all studied cases we find a rather low spatial filling factor of the magnetic field.

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