Depletion of Nonlinearity in Magnetohydrodynamic Turbulence: Insights from Analysis and Simulations

Abstract

We build on recent developments in the study of fluid turbulence [Gibbon et al. Nonlinearity 27, 2605 (2014)] to define suitably scaled, order-m moments, Dm, of ω= ω j, where ω and j are, respectively, the vorticity and current density in three-dimensional magnetohydrodynamics (MHD). We show by mathematical analysis, for unit magnetic Prandtl number PM, how these moments can be used to identify three possible regimes for solutions of the MHD equations; these regimes are specified by inequalities for Dm and D1. We then compare our mathematical results with those from our direct numerical simulations (DNSs) and thus demonstrate that 3D MHD turbulence is like its fluid-turbulence counterpart insofar as all solutions, which we have investigated, remain in only one of these regimes; this regime has depleted nonlinearity. We examine the implications of our results for the exponents q that characterize the power-law dependences of the energy spectra E(k) on the wave number k, in the inertial range of scales. We also comment on (a) the generalization of our results to the case PM ≠ 1 and (b) the relation between Dm and the order-m moments of gradients of hydrodynamic fields, which are used in characterizing intermittency in turbulent flows.