An optimal scale separation for a dynamo experiment

TL;DR

This paper investigates the optimal scale separation in dynamo experiments, demonstrating that there is a specific scale ratio that minimizes the power required for dynamo action, supported by multiple analytical methods.

Contribution

It identifies the existence of an optimal scale separation for dynamo efficiency using different analytical approaches, including subharmonic solutions and revisiting previous numerical results.

Findings

Optimal scale separation minimizes the power for dynamo action.

Multiple methods agree on the optimal scale ratio.

Results align with previous numerical studies.

Abstract

Scale separation between the flow and the magnetic field is a common feature of natural dynamos. It has also been used in the Karlsruhe sodium experiment in which the scale of the magnetic field is roughly 7 times larger than the scale of the flow [R. Stieglitz and U. M\"uller, Phys. Fluids 13, 561 (2001)]. Recently, Fauve & P\'etr\'elis ["Peyresq lectures on nonlinear phenomena", ed. J. Sepulchre, World Scientific, 1 (2003)] have shown that the power needed to reach the dynamo threshold in a dynamo experiment increases with the scale separation in the limit of large scale separation. With a more elaborate method based on subharmonic solutions [F. Plunian and K.-H. R\"adler, Geophys. Astrophys. Fluid Dynamics 96, 115 (2002)], we show, for the Roberts flow, the existence of an optimal scale separation for which this power is minimum. Previous results obtained by Tilgner [Phys. Lett. A 226, 75 (1997)] with a completely different numerical method are also reconsidered here. Again, we find an optimal scale separation in terms of minimum power for dynamo action. In addition we find that this scale separation compares very well with the one derived from the subharmonic solutions method.