Litcius/Paper detail

Transport barrier onset and edge turbulence shortfall in fusion plasmas

G. Dif‐Pradalier, Ph. Ghendrih, Y. Sarazin, E. Caschera, F. Clairet, Y. Camenen, Peter Donnel, X. Garbet, V. Grandgirard, Yann Munschy, L. Vermare, Fabien Widmer

2022Communications Physics42 citationsDOIOpen Access PDF

Abstract

Abstract Magnetic confinement fusion offers the promise of sustainable and safe energy production on Earth. Advanced experimental scenarios exploit the fascinating yet uncommon ability of confined plasmas to bifurcate into states of enhanced performance upon application of additional free energy sources. Self-regulation of small-scale turbulent eddies is essential to accessing these improved regimes. However, after several decades, basic principles for these bifurcations are still largely debated and clarifications from first principles lacking. We show here, computed from the primitive kinetic equations, establishment of a state of improved confinement through self-organisation of plasma microturbulence. Our results highlight the critical role of the interface between plasma and material boundaries and demonstrate the importance of propagation of turbulence activity beyond regions of convective drive. These observations strongly suggest a paradigm shift where the magnetised plasma at the onset of enhanced performance self-organises into a globally critical state, ‘nonlocally’ controlled by fluxes of turbulence activity.

Topics & Concepts

TurbulencePlasmaPhysicsAdvectionEnhanced Data Rates for GSM EvolutionFusionMagnetic confinement fusionStatistical physicsMechanicsComputer scienceNuclear physicsQuantum mechanicsTokamakTelecommunicationsLinguisticsPhilosophyMagnetic confinement fusion researchLaser-Plasma Interactions and DiagnosticsSolar and Space Plasma Dynamics