DIII-D: Closing the Gaps to Future Fusion Reactors

The DIII-D program is pursuing an ambitious plan to close critical design gaps to a Fusion Pilot Plant (FPP), including integrating performance and exhaust solutions, addressing plasma interacting material and technology issues, and resolving a high fusion gain path to ITER and a pulsed FPP. Increasing the ECH power will furnish low-torque electron heating and profile control, while new reactor-relevant solutions for efficient off-axis current drive will be pioneered byhigh-field-side LHCD, helicon waves and top launch ECCD to enable FPP steady-state scenarios. A series of closed, modular divertors will allow the exploration of innovative plasma solutions for combined core and plasma exhaust in high opacity/low collisionality regimes made possible by stronger shaping to maximize the pedestal pressure and density along with a BT rise to 2.5T and 20 gyrotrons to access reactor physics regimes. A dedicated material interaction test stationwill help close gaps in compatible fusion materials. The control and mitigation of plasma transients will be addressed through a passive runaway electron dissipation coil and installing novel techniques for disruption mitigation (EM launch, hyper-velocity tungsten pellets). An exciting option for a negative triangularity path is being assessed.