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- Title
Three-dimensional multimode RayleighTaylor and RichtmyerMeshkov instabilities at all density ratios.
- Authors
D. KARTOON; D. ORON; L. ARAZI
- Abstract
The three-dimensional (3D) turbulent mixing zone (TMZ) evolution under RayleighTaylor and RichtmyerMeshkov conditions was studied using two approaches. First, an extensive numerical study was made, investigating the growth of a random 3D perturbation in a wide range of density ratios. Following that, a new 3D statistical model was developed, similar to the previously developed two-dimensional (2D) statistical model, assuming binary interactions between bubbles that are growing at a 3D asymptotic velocity. Confirmation of the theoretical model was gained by detailed comparison of the bubble size distribution to the numerical simulations, enabled by a new analysis scheme that was applied to the 3D simulations. In addition, the results for the growth rate of the 3D bubble front obtained from the theoretical model show very good agreement with both the experimental and the 3D simulation results. A simple 3D dragbuoyancy model is also presented and compared with the results of the simulations and the experiments with good agreement. Its extension to the spike-front evolution, made by assuming the spikes' motion is governed by the single-mode evolution determined by the dominant bubbles, is in good agreement with the experiments and the 3D simulations. The good agreement between the 3D theoretical models, the 3D numerical simulations, and the experimental results, together with the clear differences between the 2D and the 3D results, suggest that the discrepancies between the experiments and the previously developed models are due to geometrical effects.
- Subjects
TURBULENCE; MIXING; HYDRODYNAMICS; FLUID dynamics; QUANTUM perturbations
- Publication
Laser & Particle Beams, 2003, Vol 21, Issue 3, p327
- ISSN
0263-0346
- Publication type
Article
- DOI
10.1017/s0263034603213069