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Abstract
The mechanisms of laser imprint reduction on a surface of a planar foil performed using an underdense foam are presented. The consequences on the Rayleigh–Taylor instability growth at the ablation front when the foil is accelerated are studied. The analysis is based on numerical simulations using a chain of codes: the electromagnetic paraxial code Parax provides the modifications of the intensity perturbation spectrum while the laser beam is crossing the foam. Two-dimensional axially symmetric simulations with the radiation hydrodynamic code CHIC describe the foam expansion and the foil dynamics. Finally, the perturbed flow calculations and the instability growth are investigated with the two-dimensional CHIC version in the planar geometry by using the initial and smoothed perturbation spectra. The dominant role of temporal laser smoothing during the time of foam crossing by the laser beam is demonstrated. Applications to the direct drive targets for inertial confinement fusion are discussed.
Highlights
It is known since several years [14, 15] that the laser beam propagation through a plasma with the electron density ne much lower than the critical density nc = 0 meω02/e2 is accompanied by a loss of both spatial and temporal coherence of the laser beam7
The role of parametric instabilities in the laser beam smoothing by an underdense plasma has been confirmed in numerical simulations with the electromagnetic paraxial code Parax [23]
Based on numerical simulations and theoretical considerations, the present work is dedicated to the modelling of the modification of the laser intensity distribution in an underdense plasma and its effect on the hydrodynamic evolution of a plastic foil placed at the rear side of the foam
Summary
The simulations of the plasma-induced laser-beam smoothing have been performed with the massively parallel code Parax [17, 23, 31] that describes the laser beam propagation in the paraxial approximation in three spatial directions. The aim was to characterize the foam plasma effect on the laser intensity distribution
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