Numerical simulations of the ablative Rayleigh-Taylor instability in planar inertial-confinement-fusion targets using the FastRad3D code

Bates, Jason W.; Schmitt, A. J.; Karasik, M.; Zalesak, S. T.

doi:10.1063/1.4967944

Cited by 21 publications

(5 citation statements)

References 79 publications

(108 reference statements)

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“…The Richtmyer-Meshkov instability [48,56] occurs when a shock wave interacts with a non-planar contact discontinuity. This is a key feature of many shockdriven phenomenon, as for example Inertial Confinement Fusion experiments (refer for instance to [4]). In some cases, this can provoke the fragmentation of the contact discontinuity, leading to what is called microjetting [23].…”

Section: Introductionmentioning

confidence: 97%

Surface tension for compressible fluids in ALE framework

Corot

Hoch

Labourasse

2020

Journal of Computational Physics

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Section: Introductionmentioning

confidence: 97%

Surface tension for compressible fluids in ALE framework

Corot

Hoch

Labourasse

2020

Journal of Computational Physics

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“…In this section, we quantify the effects as predicted by simulation codes. Figure 1 a shows the time evolution of the ablation pressure applied to a 2.6 mm diameter solid plastic sphere from a one-dimensional simulation using the FASTRAD3D radiation hydrocode [3] for four laser wavelengths ranging from 527 nm (frequency-doubled Nd : glass) to 193 nm. The laser rays in the one-dimensional simulation are incident in parallel with an intensity distribution given by a fifth-order super-Gaussian and an initial radius of approximately 95% of the initial pellet radius, and are refractively traced through the spherical plasma.…”

Section: Laser Target Interaction With An Argon Fluoride Drivermentioning

confidence: 99%

Direct drive with the argon fluoride laser as a path to high fusion gain with sub-megajoule laser energy

Obenschain

Schmitt

Bates

et al. 2020

Phil. Trans. R. Soc. A.

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Argon fluoride (ArF) is currently the shortest wavelength laser that can credibly scale to the energy and power required for high gain inertial fusion. ArF's deep ultraviolet light and capability to provide much wider bandwidth than other contemporary inertial confinement fusion (ICF) laser drivers would drastically improve the laser target coupling efficiency and enable substantially higher pressures to drive an implosion. Our radiation hydrodynamics simulations indicate gains greater than 100 are feasible with a sub-megajoule ArF driver. Our laser kinetics simulations indicate that the electron beam-pumped ArF laser can have intrinsic efficiencies of more than 16%, versus about 12% for the next most efficient krypton fluoride excimer laser. We expect at least 10% ‘wall plug' efficiency for delivering ArF light to target should be achievable using solid-state pulsed power and efficient electron beam transport to the laser gas that was demonstrated with the U.S. Naval Research Laboratory's Electra facility. These advantages could enable the development of modest size and lower cost fusion power plant modules. This would drastically change the present view on inertial fusion energy as being too expensive and the power plant size too large. This article is part of a discussion meeting issue ‘Prospects for high gain inertial fusion energy (part 1)'.

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“…In order to investigate the formation circumstances of RT instability, there is no doubt that it is an urgent need to fabricate nanostructures with modulated and controllable dimensions, which can simulate defects on a target surface, so as to analyze the ICF experiments. Most explorations regarding this subject focus on flat targets, where the evolution somewhat differs from a converging geometry [11][12][13]. For example, a hollow thin-walled microsphere around 1 mm in diameter is always regarded as a target ball.…”

Section: Introductionmentioning

confidence: 99%

Study of machining indentations over the entire surface of a target ball using the force modulation approach

Wang¹,

Geng²,

Guo³

et al. 2021

Int. J. Extrem. Manuf.

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A modified five-axis cutting system using a force control cutting strategy was to machine indentations in different annuli on the entire surface of a target ball. The relationship between the cutting depths and the applied load as well as the microsphere rotation speed were studied experimentally to reveal the micromachining mechanism. In particular, aligning the rotating center of the high precision spindle with the microsphere center is essential for guaranteeing the machining accuracy of indentations. The distance between adjacent indentations on the same annulus and the vertical distance between adjacent annuli were determined by the rotating speed of the micro-ball and the controllable movement of the high-precision stage, respectively. In order to verify the feasibility and effect of the proposed cutting strategy, indentations with constant and expected depths were conducted on the entire surface of a hollow thin-walled micro-ball with a diameter of 1 mm. The results imply that this machining methodology has the potential to provide the target ball with desired modulated defects for simulating the inertial confinement fusion implosion experiment.

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Numerical simulations of the ablative Rayleigh-Taylor instability in planar inertial-confinement-fusion targets using the FastRad3D code

Cited by 21 publications

References 79 publications

Surface tension for compressible fluids in ALE framework

Surface tension for compressible fluids in ALE framework

Direct drive with the argon fluoride laser as a path to high fusion gain with sub-megajoule laser energy

Study of machining indentations over the entire surface of a target ball using the force modulation approach

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