Plasma Dynamics Under Universal 1/E^2 Suppression: Magnetohydrodynamics, Transport, and Confinement

Dustyn Stanley

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Abstract

This work extends the universal 1/E^2 suppression framework to magnetically confined plasmas, demonstrating how energy-dependent coherence decay governs magnetohydrodynamic (MHD) turbulence, anomalous transport, and Brillouin flow stability. We derive modified geometric phase accumulations, predict suppression of turbulent transport via entropic constraints, and propose novel confinement strategies based on coherence threshold engineering. The theory is validated against experimental results from tokamaks and plasma rotation experiments while making testable predictions for ITER scenarios.

Version published to 10.31219/osf.io/t2b73_v1 on OSF Preprints
May 1, 2025

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