What question did this study set out to answer?

This research aims to develop a framework for controlling turbulence and instabilities in fusion plasmas using Global Complexity Stability Theory (GCST).

March 10, 2026Open Access

GCST-based Stability Control in Fusion Plasmas A Conceptual Framework for Dynamic Suppression of Turbulence and Rate-Induced Instabilities

Key Points

This research aims to develop a framework for controlling turbulence and instabilities in fusion plasmas using Global Complexity Stability Theory (GCST).
Introduced GCST-Plasma Number G_plasma as a stability metric.
Shifted control focus to active feedback-driven techniques.
Utilized numerical simulations to evaluate instability behaviors.
When G_plasma is less than 1, instability debt increases transport and coupling.
Active control improved recovery rates of instability.
Numerical simulations confirmed enhanced stability through dynamic control.

Abstract

Abstract Fusion plasmas are strongly driven, nonlinear systems where rate-induced instabilities dominate transport and confinement degradation. Global Complexity Stability Theory (GCST) provides a unified description through the evolution equation of the instability field Ψ: ∂Ψ/∂t = D ∇² Ψ + C α − γ Ψ We introduce the GCST-Plasma Number Gₚlasma = γ / (α C), an inverse stability metric analogous to a turbulent Reynolds number. When Gₚlasma < 1, instability debt accumulates, leading to enhanced transport and mode coupling. The ARC-Fusion approach shifts the control paradigm from passive high-field confinement to active, feedback-driven maximization of γₑff via real-time modulation of magnetic topology, heating profiles, and zonal-flow excitation. Numerical simulations demonstrate rate-induced transitions and the role of recovery rate γ in suppressing turbulence growth.

GCST-based Stability Control in Fusion Plasmas A Conceptual Framework for Dynamic Suppression of Turbulence and Rate-Induced Instabilities

Key Points

Abstract

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