Gyrokinetic simulation of low-n Alfvenic modes in tokamak HL-2A plasmas

The turbulence characteristics of plasmas with internal transport barriers in the HL-2A tokamak are analyzed by means of linear gyrokinetic simulations. It is found that turbulence is dominated by the ion temperature gradient (ITG) mode together with large-scale modes characterized by high-frequency electromagnetic fluctuation, which are destabilized by the steep ion temperature gradient in the weak magnetic shear regime. Comparison with solutions of analytical dispersion relations shows that their linear features match well with the beta-induced Alfven eigenmode branch of the shear Alfvenic spectrum. It is further clarified that the large population of fast ions in these plasmas plays a stabilization role through the dilution mechanism in high-n ITG mode regimes.

Gyrokinetic simulation of low-n Alfvenic modes in tokamak HL-2A plasmas

How accurate are flux-tube (local) gyrokinetic codes in modeling energetic particle effects on core turbulence?

Pedestal evolution physics in low triangularity JET tokamak discharges with ITER-like wall

How accurate are flux-tube (local) gyrokinetic codes in modeling energetic particle effects on core turbulence?

Pedestal evolution physics in low triangularity JET tokamak discharges with ITER-like wall