Hybrid-drive pressure suppressing implosion instabilities and offering nonstagnation hotspot ignition with low convergence ratio for high-gain inertial fusion

Abstract

In laser-drive ICF, hybrid drive (HD) combined direct drive (DD) and indirect drive (ID) offers a smoothed HD pressure PHD, far higher than the ablation pressure in ID and DD, to suppress hydrodynamic instabilities. In this letter, simulations of a new robust HD ignition target show that maximal HD pressure as high as PHD 650 Mbar driven by a novel "bulldozer" effect is achieved, resulting in nonstagnation hotspot ignition at the convergence ratio Cr 23, and finally, fusion energy gain 10 in total laser energy = 1.42 MJ. Two-dimensional simulations have confirmed that hydrodynamic instabilities are suppressed. A well-fitted scale of maximal HD pressure PHD (Mbar)= BEDD1/4 Tr is found from simulations of different targets and laser energies as long as Tr> 160 eV, where B is the constant depending on ablator materials, EDD in kJ is DD laser energy and Tr in 100 eV is radiation temperature depending on ID laser energy EID. PHD≥ 450 Mbar is requested for hotspot ignition. This scale from "bulldozer" effect is also available as EDD is reduced to kJ. Experiments have verified PHD about 3.5 times radiation ablation pressure for CH ablator using EID=43 kJ (Tr 200 eV) and EDD=3.6 kJ, also shown that both backscattering fraction and hot-electron energy fraction for DD laser intensity 1.8 × 1015 w· cm-2 are about a third of the traditional DD laser-plasma interaction