Gyrokinetic simulations of DIII-D near-edge L-mode plasmas

We present gyrokinetic simulations with the GENE code addressing the near-edge region of an L-mode discharge in the DIII-D tokamak. At radial position $\rho=0.80$, we find that radial ion transport is nonlinearly quenched by a strong poloidal zonal flow with a clear Dimits shift. Simulations with the ion temperature gradient increased by $\sim40\%$ above the nominal value give electron and ion heat fluxes that are in simultaneous agreement with the experiment. This gradient increase is within the uncertainty of the Charge Exchange Recombination (CER) diagnostic measurements at the $1.6 \sigma$ level. Multi-scale simulations are carried out with realistic mass ratio and geometry for the first time in the near-edge. These suggest that highly unstable ion temperature gradient driven modes of the flux-matched ion-scale simulations strongly suppress electron-scale transport, such that ion-scale simulations are sufficient at this location. At radial position $\rho=0.90$, simulations reproduce the total experimentally inferred heat flux with the inclusion of $\mathbf{E} \times \mathbf{B}$ shear effects and with an increase in the electron temperature gradient by $\sim 25\%$. This gradient increase is compatible with the experimental uncertainty in the measured electron temperature via Thomson scattering. These results are consistent with previous findings that gyrokinetic simulations are able to reproduce the experimental heat fluxes of near-edge L-mode plasmas by varying input parameters within their experimental uncertainties.