Optimal lengthscale for a turbulent dynamo

Abstract

We demonstrate that there is an optimal forcing length scale for low Prandtl number dynamo flows, that can significantly reduce the required energy injection rate. The investigation is based on simulations of the induction equation in a periodic box of size 2π L. The flows considered are turbulent ABC flows forced at different forcing wavenumbers kf simulated using a subgrid turbulent model. The critical magnetic Reynolds number RmcT decreases as the forcing wavenumber kf increases from the smallest allowed kmin=1/L. At large kf on the other hand, RmcT increases with the forcing wavenumber as RmcT kf in agreement with mean-field scaling prediction. At kf L 4 an optimal wavenumber is reached where RmcT obtains its minimum value. At this optimal wavenumber RmcT is smaller by more than a factor of ten than the case forced in kf=1. This leads to a reduction of the energy injection rate by three orders of magnitude when compared to the case that the system is forced in the largest scales and thus provides a new strategy for the design of a fully turbulent experimental dynamo.