Simulation Analysis of Carbon Deposition Profile in the Closed Helical Divertor Configuration in the Large Helical Device

Abstract: Recent long pulse plasma discharges in the Large Helical Device have been interrupted by radiation collapse induced by large amounts of dusts released from a closed divertor region. Traces of exfoliation of carbon-rich mixed material deposition layers were found in the divertor region after the experimental campaigns, indicating that the thickly accumulated deposited layers were exfoliated and broken into dusts. Simulation of the density profiles of carbon deposition in the divertor region by EMC3-EIRENE reaso… Show more

“…A three‐dimensional model for the impurity transport simulation for R ax = 3.60 m is shown in Figure . The model includes the peripheral plasma (ergodic layer), the divertor legs, the vacuum vessel, the helical coil cans, and the divertor components for one‐half of the helical coil pitch angle (18° in toroidal direction) . The typical width of the grid cells in the model is less than 10 mm, but it depends on the radial and poloidal positions of the cells.…”

Investigation of dust shielding effect of intrinsic ergodic magnetic field line structures in the peripheral plasma in the large helical device

“…A three‐dimensional model for the impurity transport simulation for R ax = 3.60 m is shown in Figure . The model includes the peripheral plasma (ergodic layer), the divertor legs, the vacuum vessel, the helical coil cans, and the divertor components for one‐half of the helical coil pitch angle (18° in toroidal direction) . The typical width of the grid cells in the model is less than 10 mm, but it depends on the radial and poloidal positions of the cells.…”

Investigation of dust shielding effect of intrinsic ergodic magnetic field line structures in the peripheral plasma in the large helical device

Simulation of impurity transport in the peripheral plasma due to the emission of dust in long pulse discharges on the Large Helical Device

Boron transport simulation using the ERO2.0 code for real-time wall conditioning in the large helical device