Turbulent regimes in collisions of 3D Alfv\'en-wave packets
Abstract
Using 3D gyrofluid simulations, we revisit the problem of Alfven-wave (AW) collisions as building blocks of the Alfvenic cascade and their interplay with magnetic reconnection at magnetohydrodynamic (MHD) scales. Depending on the large-scale nonlinearity parameter 0 (the ratio between AW linear propagation time and nonlinear turnover time), different regimes are observed. For strong nonlinearities (01), turbulence is consistent with a dynamically aligned, critically balanced cascade--fluctuations exhibit a scale-dependent alignment θk k-1/4, a k-3/2 spectrum and k\| k1/2 spectral anisotropy. At weaker nonlinearities (small 0), a spectral break marking the transition between a large-scale weak regime and a small-scale k-11/5 tearing-mediated range emerges, implying that dynamic alignment occurs also for weak nonlinearities. At 0<1 the alignment angle θk shows a stronger scale dependence than in the 01 regime, i.e. θk k-1/2 at 00.5, and θk k-1 at 00.1. Dynamic alignment in the weak regime also modifies the large-scale spectrum, scaling roughly as k-3/2 for 00.5 and as k-1 for 00.1. A phenomenological theory of dynamically aligned turbulence at weak nonlinearities that can explain these spectra and the transition to the tearing-mediated regime is provided; at small 0, the strong scale dependence of the alignment angle combines with the increased lifetime of turbulent eddies to allow tearing to onset and mediate the cascade at scales that can be larger than those predicted for a critically balanced cascade by several orders of magnitude. Such a transition to tearing-mediated turbulence may even supplant the usual weak-to-strong transition.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.