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Gyrokinetic understanding of the edge pedestal transport driven by resonant magnetic perturbations in a realistic divertor geometry

R. Hager, C. S. Chang, N. M. Ferraro, R. Nazikian

2020Physics of Plasmas24 citationsDOIOpen Access PDF

Abstract

Self-consistent simulations of neoclassical and electrostatic turbulent transport in a DIII-D H-mode edge plasma under resonant magnetic perturbations (RMPs) have been performed using the global total-f gyrokinetic particle-in-cell code x-point gyrokinetic code (XGC), in order to study density pump-out and electron heat confinement. The RMP field is imported from the extended magneto-hydrodynamics code M3D-C1, taking into account the linear two-fluid plasma response. With both neoclassical and turbulence physics considered together, the XGC simulation reproduces two key features of experimentally observed edge transport under RMPs: increased radial particle transport in the pedestal region that is sufficient to account for the experimental pump-out rate and suppression of the electron heat flux in the steepest part of the edge pedestal. In the simulation, the density fluctuation amplitude of modes moving in the electron diamagnetic direction increases due to interaction with RMPs in the pedestal shoulder and outward, while the electron temperature fluctuation amplitude decreases.

Topics & Concepts

PhysicsPedestalDivertorGyrokineticsTurbulenceResonant magnetic perturbationsMagnetic fieldElectron temperaturePlasmaAmplitudeElectronHeat fluxComputational physicsAtomic physicsDiamagnetismEnhanced Data Rates for GSM EvolutionMagnetic fluxElectron densityStellaratorMagnetohydrodynamicsFlux tubeMechanicsQuantum electrodynamicsMagnetic confinement fusionFlux (metallurgy)Heat transferCondensed matter physicsField (mathematics)Classical mechanicsTemperature gradientMagnetic confinement fusion researchIonosphere and magnetosphere dynamicsDust and Plasma Wave Phenomena
Gyrokinetic understanding of the edge pedestal transport driven by resonant magnetic perturbations in a realistic divertor geometry | Litcius