Three-Dimensional Hot-Spot Reconstruction in Inertial Fusion Implosions

Three-dimensional effects play a crucial role during the hot-spot formation in inertial fusion implosions. A technique for 3-D hot-spot reconstruction from experimental observables is presented. Using the diagonalization of the velocity-variance matrix in apparent ion temperatures (T_i), the effective asymmetry of both isotropic and anisotropic flows is shown to be governed by the direction of the maximum eigenvalue. A good agreement between the effective-flow axis and the hot-spot flow vector for implosions with large T_i asymmetries is observed. The effective-flow axis is used to diagnose the interaction between even and odd Legendre modes. Using the analytic L = 1 areal-density (rR) model, the 3-D variation of rR is shown to be a function of the dot product between the line of sight and the hot-spot flow vectors. A perturbation-theory approach is derived to reconstruct the 3-D hot-spot emission profile using spherical-harmonic modes. The radial dependence of modal amplitudes is represented by a power series. This method is applied to reconstruct a 3-D hot-spot emission profile using x-ray images at different views.