Investigating the influence of divertor baffles on nitrogen-seeded detachment in TCV with SOLPS-ITER simulations and TCV experiments

Abstract

Plasma edge simulation with the SOLPS-ITER code are performed to study the influence of divertor baffles on nitrogen-seeded detachment in L-mode TCV discharges. Simulations of nitrogen seeding with baffles is found to yield lower target temperatures and heat fluxes than in baffle-only and seeding-only simulations. The neutral compression increases with both baffles and seeding, but due to different mechanism according to the proposed neutral transport model. The nitrogen retention, defined as the divertor-to-main chamber nitrogen density ratio, increases with the seeding rate if baffled. Baffled nitrogen retentions are lower than the unbaffled retentions at low seeding levels and are higher at high seeding levels. The baffled carbon retentions are always above the unbaffled retentions due to increased target particle flux and sputtering by baffling. Baffles also relocate more impurity radiations from the main chamber region into the divertor. The predicted trends of target parameters, radiation and neutral distributions are well supported by TCV experiments, though discrepancies in absolute values remain. The simulations generally yield a colder and denser divertor, consistent with previous SOLPS-ITER simulations of Ohmically heated L-modes in TCV. The comparison of simulation and experiment, together with the proposed neutral transport model, suggest the necessity of sufficient baffling in future TCV divertor upgrade, and a combination of baffling and seeding to facilitate the access to detachment