Capsule design for the National Ignition Facility

Dittrich, Thomas; Haan, S. W.; Marinak, M. M.; Hinkel, D. E.; Pollaine, S. M.; McEachern, R.; Cook, Robert; Roberts, Christopher C.; Wilson, D. C.; Bradley, P. A.; Varnum, W. S.

doi:10.1017/s0263034699172070

Cited by 16 publications

(8 citation statements)

References 6 publications

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“…When the initial perturbation is evaluated only on modes with l > 10 (modes with smaller l are weakly affected by RTI) we see (frame (b)) that the 50% degradation threshold decreases to σ rms 1-1.5 µm. These results are qualitatively analogous to those published by several other groups [2,3,[13][14][15]21]. Frames (c) and (d) show that decreased yield for increased initial perturbation is associated with delayed ignition, lower fusion power, and longer (but less effective) burn.…”

Section: Multi-mode Perturbationssupporting

confidence: 88%

Converging geometry Rayleigh–Taylor instability and central ignition of inertial confinement fusion targets

Atzeni

Schiavi

Temporal

2004

Plasma Phys. Control. Fusion

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The Rayleigh-Taylor instability (RTI) of the inner surface of an inertial confinement fusion shell is studied through high-resolution two-dimensional numerical simulations. The instability is seeded by a mass displacement introduced in the simulations at the end of the implosion coasting stage. Analysis of single-mode, small-amplitude perturbations confirms that ablation caused by electron conduction and fusion alpha-particles causes significant growth reduction of all modes and stabilization of high-l modes. Different measures of the instability are discussed and compared with modified Takabelike expressions. Large-amplitude multi-mode simulations are performed to study the effects of RTI on ignition and burn. RTI perturbations reduce the size of the central hot spot and delay ignition. For a few different perturbation spectra the dependence of fusion yield on the initial perturbation root mean square amplitude is studied.

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Section: Multi-mode Perturbationssupporting

confidence: 88%

Converging geometry Rayleigh–Taylor instability and central ignition of inertial confinement fusion targets

Atzeni

Schiavi

Temporal

2004

Plasma Phys. Control. Fusion

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“…The above gelatin ring experiments help shed light on feedthrough and subsequent growth at the inner surface of single-shell capsules like the ones planned for NIF 8,41 . Another class of capsules involves double-shell designs 8,42 where an inner capsule containing the fuel gas is imploded after colliding with an outer shell.…”

Section: Numerical Simulationsmentioning

confidence: 91%

Rayleigh-Taylor and Richtmyer-Meshkov instabilities and mixing in stratified cylindrical shells

2005

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We study the linear stability of an arbitrary number N of cylindrical concentric shells undergoing a radial implosion or explosion.We derive the evolution equation for the perturbation i η at interface i; it is coupled to the two adjacent interfaces via η i ±1 . For N=2, where there is only one interface, we verify Bell's conjecture as to the form of the evolution equation for arbitrary ρ 1 and ρ 2 , the fluid densities on either side of the interface. We obtain several analytic solutions for the N=2 and 3 cases.We discuss freeze-out, a phenomenon that can occur in all three geometries (planar, cylindrical, or spherical), and "critical modes" that are stable for any implosion or explosion history and occur only in cylindrical or spherical geometries. We present numerical simulations of possible gelatin-ring experiments illustrating perturbation feedthrough from one interface to another. We also develop a simple model for the evolution of turbulent mix in cylindrical geometry and define a geometrical factor G as the ratio h cylindrical / h planar between cylindrical and planar mixing layers. We find that G is a decreasing function of o R R / , implying that in our model h cylindrical evolves faster (slower) than h planar during an implosion (explosion).

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“…Lagrangian, radiation-hydrodynamics codes that are widely used to design ICF target capsules Haan et al, 1995;Dittrich et al, 1999;Peterson et al, 2002! numerical simulations~Marinak et al, 1996!…”

Section: Introductionmentioning

confidence: 99%

The k-L turbulence model for describing buoyancy-driven fluid instabilities

Chiravalle

2006

Laser Part. Beams

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The k-L turbulence model, where k is the turbulent kinetic energy and L represents the turbulent eddy scale length, is a two-equation turbulence model that has been proposed to simulate turbulence induced by Rayleigh-Taylor~RT! and Richtmyer Meshkov~RM! instabilities, which play an important role in the implosions of inertial confinement fusioñ ICF! capsule targets. There are three free parameters in the k-L model, and in this paper, I calibrate them independently by comparing with RT and RM data from the linear electric motor~LEM! experiments together with classical Kelvin-Helmoholtz~KH! data. To perform this calibration, I numerically solved the equations of one-dimensional~1D! Lagrangian hydrodynamics, in a manner similar to that of contemporary ICF codes, together with the k-L turbulence model. With the three free parameters determined, I show that the k-L model is successful in describing both shear-driven and buoyancy-driven instabilities, capturing the experimentally observed separation between bubbles and spikes at high Atwood number for the RT case, as well as the temporal mix width recorded in RM shock tube experiments.

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Capsule design for the National Ignition Facility

Cited by 16 publications

References 6 publications

Converging geometry Rayleigh–Taylor instability and central ignition of inertial confinement fusion targets

Converging geometry Rayleigh–Taylor instability and central ignition of inertial confinement fusion targets

Rayleigh-Taylor and Richtmyer-Meshkov instabilities and mixing in stratified cylindrical shells

The k-L turbulence model for describing buoyancy-driven fluid instabilities

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