Self-consistent growth rate of the Rayleigh–Taylor instability in an ablatively accelerating plasma
- 1 December 1985
- journal article
- Published by AIP Publishing in Physics of Fluids
- Vol. 28 (12), 3676-3682
- https://doi.org/10.1063/1.865099
Abstract
The linear stability of an ablating plasma is investigated as an eigenvalue problem by assuming the plasma to be at the stationary state. For various structures of the ablating plasma, the growth rate is found to be expressed well in the form γ=α(kg)1/2 −βkVa, where α=0.9, β≂3–4, and Va is the flow velocity across the ablation front, and is found to agree well with recent two‐dimensional simulations in a classical transport regime. Short‐wavelength lasers inducing enhanced mass ablation are suggested to be advantageous to stable implosion because of the ablative stabilization.Keywords
This publication has 18 references indexed in Scilit:
- Vortex shedding due to laser ablationPhysics of Fluids, 1984
- Slab model for Rayleigh–Taylor stabilization by vortex shedding, compressibility, thermal conduction, and ablationPhysics of Fluids, 1984
- Rayleigh–Taylor instability in an inhomogeneous ablatively accelerated fluidPhysics of Fluids, 1983
- Self-consistent eigenvalue analysis of Rayleigh–Taylor instability in an ablating plasmaPhysics of Fluids, 1983
- Analytic theory of ablation layer instabilityPhysics of Fluids, 1983
- Nonlinear aspects of hydrodynamic instabilities in laser ablationApplied Physics Letters, 1982
- Nonlinear effects of multifrequency hydrodynamic instabilities on ablatively accelerated thin shellsPhysics of Fluids, 1982
- Nonlinear Evolution of Ablation-Driven Rayleigh-Taylor InstabilityPhysical Review Letters, 1981
- Fluid instabifities of a uniformly imploding ablatively driven shellJournal of Plasma Physics, 1980
- Flame Propagation and Overdense Heating in a Laser Created PlasmaPhysics of Fluids, 1971