Design of inertial fusion implosions reaching the burning plasma regime

In a burning plasma state(1-7), alpha particles from deuterium-tritium fusion reactions redeposit their energy and are the dominant source of heating. This state has recently been achieved at the US National Ignition Facility(0) using indirect-drive inertial-confinement fusion. Our experiments use a laser-generated radiation-filled cavity (a hohlraum) to spherically implode capsules containing deuterium and tritium fuel in a central hot spot where the fusion reactions occur. We have developed more efficient hohlraums to implode larger fusion targets compared with previous experiments(9,10). This delivered more energy to the hot spot, whereas other parameters were optimized to maintain the high pressures required for inertial-confinement fusion. We also report improvements in implosion symmetry control by moving energy between the laser beams(11-16) and designing advanced hohlraum geometry(17) that allows for these larger implosions to be driven at the present laser energy and power capability of the National Ignition Facility. These design changes resulted in fusion powers of 1.5 petawatts, greater than the input power of the laser, and 170 kJ of fusion energy(18,19). Radiation hydrodynamics simulations(20,21) show energy deposition by alpha particles as the dominant term in the hot-spot energy balance, indicative of a burning plasma state.

Automated summary

Burning plasma state has been achieved at the US National Ignition Facility using indirect-drive inertial-confinement fusion. More efficient hohlraums and improved symmetry control have allowed for effective heating by alpha particles from fuel fusion reactions. This is significant for the progress of inertial-confinement fusion.