This work introduces a fundamental shift in plasma physics by resolving anomalous transport as a deterministic manifestation of Phase-Space Torsion (T₈₉₊). Under the Meigooni Doctrine, the transition from laminar confinement to turbulent flux is no longer treated as a stochastic probability, but as a geometric breach of the /8 Meigooni Ignition Criterion. By projecting the 5D gyrokinetic phase space onto a stabilized 1D complex manifold anchored at the ED₅₀ point, we achieve a 10⁹ computational efficiency gain over traditional Monte Carlo and N-body simulations. We introduce the Meigooni Binary Trigger (MBT) —a high-speed diagnostic engine that enables real-time vortex-modulation of plasma currents. Key Breakthroughs: Deterministic Flux Suppression: Proves that outward asymmetric flux can be reduced by over 60% through hierarchical geometric control. Ignition Threshold Optimization: Provides a first-principles derivation for reducing the minimum heating power (P ₇₄₀ₓ₈₍₆^ min) required for steady-state ignition. Universal Scaling: Unifies the stability principles of atomic orbitals with macroscopic magnetically confined plasmas via the Viana Constant (V).
Amin Tayebi-Meigooni (Thu,) studied this question.