Improving hot-spot pressure for ignition in high-adiabat Inertial Confinement Fusion implosion

Abstract

A novel capsule target design to improve the hot-spot pressure in the high-adiabat implosion for inertial confinement fusion is proposed, where a layer of comparatively high-density material is used as a pusher between the fuel and the ablator. This design is based on our theoretical finding of the stagnation scaling laws, which indicates that the hot spot pressure can be improved by increasing the kinetic energy density d Vimp2/2 (d is the shell density when the maximum shell velocity is reached, Vimp is the implosion velocity.) of the shell. The proposed design uses the high density pusher to enhance the shell density d so that the hot spot pressure is improved. Radio-hydrodynamic simulations show that the hot spot pressure of the design reaches the requirement for ignition even driven by a very high-adiabat short-duration two-shock pulse. The design is hopeful to simultaneously overcome the two major obstacles to achieving ignition--ablative instability and laser-plasma instability.