Abstract
SOLPS-ITER simulations performed for QDT = 10, PSOL = 100 MW burning plasmas on ITER extend the existing database to high values of separatrix averaged neon impurity concentration (⟨cNe⟩ ≈ 6%) and divertor neutral pressure (⟨pdiv⟩ > 25 Pa) in order to determine the heat flux mitigation capability of these scenarios and whether strongly detached states are accessible. In the existing database of ITER simulations, the level of detachment was limited to cases where the integral ion flux to the outer target was greater than 80% of the value at rollover, with the impurity radiation localized near the target. With the possibility of narrow heat flux channels and increased deposited power due to tile shaping, it is important to explore operation at a higher degree of detachment. Two series of simulations were explored to extend the database of SOLPS simulations. By increasing the deuterium and neon puff rates proportionally, the peak divertor energy flux (q⊥,max) is decreased from 5 to 3 MW m−2 while ⟨pdiv⟩ increased from 11 to 27 Pa. By increasing only the neon puff, q⊥, max can be reduced to <1MW m−2 while ⟨pdiv⟩ is maintained at $\sim 11$ Pa. As the neon puff level is increased, the position of the impurity radiation peak is shifted towards the X-point. At the highest neon puff levels with steady-state solutions, the electron temperature is reduced below 1 eV across 50 cm of each divertor target. The new cases extend previously observed tight relationships in power and momentum loss factors to low electron temperature improving their utility for highly detached regimes.
