Inertial-Range Suppression and Ponderomotive Density Cavitation in Broadband Sub-Alfv\'enic Turbulence under Plasma Sheet Boundary Layer Conditions
Abstract
Kinetic Alfv\'en waves (KAWs) are among the most pervasive electromagnetic fluctuations in magnetized astrophysical plasmas, from Earth's magnetosphere to galaxy clusters. Their ponderomotive coupling to compressive density fluctuations is poorly understood in the broadband turbulent regime. We present two-dimensional pseudospectral simulations of the modified nonlinear Schr\"odinger--magnetosonic (MNLS--MS) system governing KAW envelopes, initialized with a broadband power-law spectrum (|(k)|2 k-5/6) spanning many interacting modes, at β 0.1--0.3 representative of plasma sheet boundary layer (PSBL) conditions. A fourth-order Runge--Kutta scheme on a 256× 256 grid integrates the system to t = 40 (normalized), with total energy conserved to within 0.085\% in the undamped run; a damped run with dissipation loses 4\% of the magnetic energy over the same interval. The nonlinearity parameter NL ≈ 0.25 confirms broadband sub-Alfv\'enic turbulence throughout. Magnetic field intensity and plasma density develop spatially intermittent, filamentary structures within the first few wave periods, consistent with ponderomotive density cavitation and plasma expulsion from wave-intense regions. The magnetic energy spectra show inertial-range suppression, with a rapid transition from injection (k < 0.3) to dissipation without an extended power-law cascade, in agreement with the moderate magnetic Reynolds number (Rm 250--370) of the simulation and the observationally constrained range for PSBL turbulence. These results provide numerical evidence that broadband KAW turbulence self-organizes into coherent density structures at kinetic scales, and that the spectral character of such turbulence is governed primarily by moderate-Reynolds-number constraints rather than by the wave physics alone.
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.