Transport of magnetic flux and the vertical structure of accretion discs: II. Vertical profile of the diffusion coefficients

TL;DR

This study examines how vertical variations in diffusion coefficients within accretion discs influence magnetic flux transport, revealing that weak magnetic fields can be advected faster than mass, especially with dead zones or non-turbulent surface layers.

Contribution

It demonstrates the impact of vertical profiles of diffusion coefficients on magnetic flux transport, confirming previous results and exploring effects of dead zones and non-turbulent layers.

Findings

Weak magnetic fields can be advected faster than mass.

Dead zones amplify magnetic flux advection.

Non-turbulent surface layers are ineffective at reducing diffusion.

Abstract

We investigate the radial transport of magnetic flux in a thin accretion disc, the turbulence being modelled by effective diffusion coefficients (viscosity and resistivity). Both turbulent diffusion and advection by the accretion flow contribute to flux transport, and they are likely to act in opposition. We study the consequences of the vertical variation of the diffusion coefficients, due to a varying strength of the turbulence. For this purpose, we consider three different vertical profiles of these coefficients. The first one is aimed at mimicking the turbulent stress profile observed in numerical simulations of MHD turbulence in stratified discs. This enables us to confirm the robustness of the main result of Paper I obtained for uniform diffusion coefficients that, for weak magnetic fields, the contribution of the accretion flow to the transport velocity of magnetic flux is much larger than the transport velocity of mass. We then consider the presence of a dead zone around the equatorial plane, where the physical resistivity is high while the turbulent viscosity is low. We find that it amplifies the previous effect: weak magnetic fields can be advected orders of magnitude faster than mass, for dead zones with a large vertical extension. The ratio of advection to diffusion, determining the maximum inclination of the field at the surface of the disc, is however not much affected. Finally, we study the effect of a non-turbulent layer at the surface of the disc, which has been suggested as a way to reduce the diffusion of the magnetic flux. We find that the reduction of the diffusion requires the conducting layer to extend below the height at which the magnetic pressure equals the thermal pressure. As a consequence, if the absence of turbulence is caused by the large-scale magnetic field, the highly conducting layer is inefficient at reducing the diffusion.