Detailed implosion modeling of deuterium-tritium layered experiments on the National Ignition Facility

More than two dozen inertial confinement fusion ignition experiments with cryogenic deuterium-tritium layers have now been performed on the National Ignition Facility (NIF) [G. H. Miller , Opt. Eng. 443, 2841 (2004)]. Each of these yields a wealth of data including neutron yield, neutron down-scatte...

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Veröffentlicht in:	Physics of plasmas 2013-05, Vol.20 (5)
Hauptverfasser:	Clark, D S, Hinkel, DE, Eder, D C, Jones, O S, Haan, S W, Hammel, BA, Marinak, M M, Milovich, J L, Robey, H F, Suter, L J
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Schlagworte:	70 PLASMA PHYSICS AND FUSION TECHNOLOGY CAPSULES Computer simulation COMPUTERIZED SIMULATION CRYOGENICS D-T OPERATION ELECTRON TEMPERATURE H CODES HYDRODYNAMICS Ignition Implosions INERTIAL CONFINEMENT ION TEMPERATURE LAYERS PLASMA DIAGNOSTICS PLASMA INSTABILITY PLASMA SIMULATION Plasmas Simulation THERMONUCLEAR IGNITION THERMONUCLEAR REACTORS Three dimensional THREE-DIMENSIONAL CALCULATIONS TWO-DIMENSIONAL CALCULATIONS US NATIONAL IGNITION FACILITY X RADIATION
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description	More than two dozen inertial confinement fusion ignition experiments with cryogenic deuterium-tritium layers have now been performed on the National Ignition Facility (NIF) [G. H. Miller , Opt. Eng. 443, 2841 (2004)]. Each of these yields a wealth of data including neutron yield, neutron down-scatter fraction, burn-averaged ion temperature, x-ray image shape and size, primary and down-scattered neutron image shape and size, etc. Compared to 2-D radiation-hydrodynamics simulations modeling both the hohlraum and the capsule implosion, however, the measured capsule yield is usually lower by a factor of 5 to 10, and the ion temperature varies from simulations, while most other observables are well matched between experiment and simulation. In an effort to understand this discrepancy, we perform detailed post-shot simulations of a subset of NIF implosion experiments. Using two-dimensional HYDRA simulations [M. M. Marinak, , Phys. Plasmas 8, 2275 (2001).] of the capsule only, these simulations represent as accurately as possible the conditions of a given experiment, including the as-shot capsule metrology, capsule surface roughness, and ice layer defects as seeds for the growth of hydrodynamic instabilities. The radiation drive used in these capsule-only simulations can be tuned to reproduce quite well the measured implosion timing, kinematics, and low-mode asymmetry. In order to simulate the experiments as accurately as possible, a limited number of fully three-dimensional implosion simulations are also being performed. Despite detailed efforts to incorporate all of the effects known and believed to be important in determining implosion performance, substantial yield discrepancies remain between experiment and simulation. Some possible alternate scenarios and effects that could resolve this discrepancy are discussed.
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H. Miller , Opt. Eng. 443, 2841 (2004)]. Each of these yields a wealth of data including neutron yield, neutron down-scatter fraction, burn-averaged ion temperature, x-ray image shape and size, primary and down-scattered neutron image shape and size, etc. Compared to 2-D radiation-hydrodynamics simulations modeling both the hohlraum and the capsule implosion, however, the measured capsule yield is usually lower by a factor of 5 to 10, and the ion temperature varies from simulations, while most other observables are well matched between experiment and simulation. In an effort to understand this discrepancy, we perform detailed post-shot simulations of a subset of NIF implosion experiments. Using two-dimensional HYDRA simulations [M. M. Marinak, , Phys. 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H. Miller , Opt. Eng. 443, 2841 (2004)]. Each of these yields a wealth of data including neutron yield, neutron down-scatter fraction, burn-averaged ion temperature, x-ray image shape and size, primary and down-scattered neutron image shape and size, etc. Compared to 2-D radiation-hydrodynamics simulations modeling both the hohlraum and the capsule implosion, however, the measured capsule yield is usually lower by a factor of 5 to 10, and the ion temperature varies from simulations, while most other observables are well matched between experiment and simulation. In an effort to understand this discrepancy, we perform detailed post-shot simulations of a subset of NIF implosion experiments. Using two-dimensional HYDRA simulations [M. M. Marinak, , Phys. Plasmas 8, 2275 (2001).] of the capsule only, these simulations represent as accurately as possible the conditions of a given experiment, including the as-shot capsule metrology, capsule surface roughness, and ice layer defects as seeds for the growth of hydrodynamic instabilities. The radiation drive used in these capsule-only simulations can be tuned to reproduce quite well the measured implosion timing, kinematics, and low-mode asymmetry. In order to simulate the experiments as accurately as possible, a limited number of fully three-dimensional implosion simulations are also being performed. Despite detailed efforts to incorporate all of the effects known and believed to be important in determining implosion performance, substantial yield discrepancies remain between experiment and simulation. 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subjects	70 PLASMA PHYSICS AND FUSION TECHNOLOGY CAPSULES Computer simulation COMPUTERIZED SIMULATION CRYOGENICS D-T OPERATION ELECTRON TEMPERATURE H CODES HYDRODYNAMICS Ignition Implosions INERTIAL CONFINEMENT ION TEMPERATURE LAYERS PLASMA DIAGNOSTICS PLASMA INSTABILITY PLASMA SIMULATION Plasmas Simulation THERMONUCLEAR IGNITION THERMONUCLEAR REACTORS Three dimensional THREE-DIMENSIONAL CALCULATIONS TWO-DIMENSIONAL CALCULATIONS US NATIONAL IGNITION FACILITY X RADIATION
title	Detailed implosion modeling of deuterium-tritium layered experiments on the National Ignition Facility
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