Mean field dynamo action in shearing flows. II: fluctuating kinetic helicity with zero mean

Abstract

Here we explore the role of temporal fluctuations in kinetic helicity on the generation of large-scale magnetic fields in presence of a background linear shear flow. Key techniques involved here are same as in our earlier work [][hereafter paper~I]JS20, where we have used the renovating flow based model with shearing waves. Both, the velocity and the helicity fields, are treated as stochastic variables with finite correlation times, τ and τh, respectively. Growing solutions are obtained when τh > τ, even when this time-scale separation, characterised by m=τh/τ, remains below the threshold for causing the turbulent diffusion to turn negative. In regimes when turbulent diffusion remains positive, and τ is on the order of eddy turnover time T, the axisymmetric modes display non-monotonic behaviour with shear rate S: both, the growth rate γ and the wavenumber k corresponding to the fastest growing mode, first increase, reach a maximum and then decrease with |S|, with k being always smaller than eddy-wavenumber, thus boosting growth of magnetic fields at large length scales. The cycle period P cyc of growing dynamo wave is inversely proportional to |S| at small shear, exactly as in the fixed kinetic helicity case of paper~I. This dependence becomes shallower at larger shear. Interestingly enough, various curves corresponding to different choices of m collapse on top of each other in a plot of m P cyc with |S|.