Your search keyword '"Robey, H. F."' showing total 11 results

1. Reduced instability growth with high-adiabat high-foot implosions at the National Ignition Facility.

Author

Casey DT, Smalyuk VA, Raman KS, Peterson JL, Berzak Hopkins L, Callahan DA, Clark DS, Dewald EL, Dittrich TR, Haan SW, Hinkel DE, Hoover D, Hurricane OA, Kroll JJ, Landen OL, Moore AS, Nikroo A, Park HS, Remington BA, Robey HF, Rygg JR, Salmonson JD, Tommasini R, and Widmann K

Subjects

Models, Chemical, Deuterium chemistry, Hydrodynamics, Nuclear Fusion, Tritium chemistry

Abstract

Hydrodynamic instabilities are a major obstacle in the quest to achieve ignition as they cause preexisting capsule defects to grow and ultimately quench the fusion burn in experiments at the National Ignition Facility. Unstable growth at the ablation front has been dramatically reduced in implosions with "high-foot" drives as measured using x-ray radiography of modulations at the most dangerous wavelengths (Legendre mode numbers of 30-90). These growth reductions have helped to improve the performance of layered DT implosions reported by O. A. Hurricane et al. [Nature (London) 506, 343 (2014)], when compared to previous "low-foot" experiments, demonstrating the value of stabilizing ablation-front growth and providing directions for future ignition designs.

Published

2014

2. Mechanisms of shape transfer and preheating in indirect-drive double shell collisions.

Author

Loomis, E. N., Robey, H. F., Haines, B. M., Morrow, T., Montgomery, D. S., Wilson, D. C., Xu, H., Millot, M., Celliers, P., Sacks, R., Sauppe, J. P., Quintana, T., Heinbockel, C., Kroll, J., Randolph, B., Fierro, F., Wilson, C., Daughton, W., Merritt, E., and Finnegan, S. M.

Subjects

*INERTIAL confinement fusion, *TRITIUM, *KINETIC energy, *ENERGY conversion, *FOAM, *ENERGY transfer, *HARD X-rays, *MODE shapes

Abstract

Implosions of Hohlraum-driven double shell targets as an alternative inertial confinement fusion concept are underway at the National Ignition Facility. The double shell system relies on a series of energy transfer processes starting from thermal x-ray absorption by the outer shell, followed by collisional transfer of kinetic energy to a heavy metal inner shell, and finally, conversion to the internal energy of the deuterium-tritium fuel. During each of these energy transfer stages, low-mode asymmetries can act to reduce the ideal transfer efficiency degrading double shell performance. Mechanisms, such as hard x-ray preheat from the Hohlraum, not only decrease the efficiency of kinetic energy transfer but may also be a source of low-mode asymmetry. In this article, we evaluate the shape transfer processes through the time of shell collision using two-dimensional integrated Hohlraum and capsule computations. We find that the dominant mode of the shape transfer is well described using a "radial impulse" model from the shape of the foam pressure reservoir. To evaluate the importance of preheat on inner shell shape, we also report on first measurements of Au L-shell preheat asymmetry in a double shell with a tungsten pusher. These measurements showed a 65% higher preheat velocity at the pole of the capsule relative to the equator. We also found that the experiments provided rigorous constraints by which to test the Hohlraum model settings that impact the amount and symmetry of Au L-shell preheat via the plasma conditions inside the outer cone Au bubble. [ABSTRACT FROM AUTHOR]

Published

2022

3. A polar direct drive liquid deuterium–tritium wetted foam target concept for inertial confinement fusion.

Author

Olson, R. E., Schmitt, M. J., Haines, B. M., Kemp, G. E., Yeamans, C. B., Blue, B. E., Schmidt, D. W., Haid, A., Farrell, M., Bradley, P. A., Robey, H. F., and Leeper, R. J.

Subjects

INERTIAL confinement fusion, FOAM, TRITIUM, LIQUIDS

Abstract

We propose a new approach to inertial confinement fusion (ICF) that could potentially lead to ignition and propagating thermonuclear burn at the National Ignition Facility (NIF). The proposal is based upon a combination of two concepts, referred to as polar direct drive and liquid deuterium–tritium wetted foam capsules. With this new concept, 2D radiation hydrodynamic simulations indicate that ICF ignition and propagating thermonuclear burn are possible with the laser power and energy capabilities available today on the NIF. [ABSTRACT FROM AUTHOR]

Published

2021

4. Constraining computational modeling of indirect drive double shell capsule implosions using experiments.

Author

Haines, Brian M., Sauppe, J. P., Keiter, P. A., Loomis, E. N., Morrow, T., Montgomery, D. S., Kuettner, L., Patterson, B. M., Quintana, T. E., Field, J., Millot, M., Celliers, P., Wilson, D. C., Robey, H. F., Sacks, R. F., Stark, D. J., Krauland, C., and Rubery, M.

Subjects

INERTIAL confinement fusion, RAYLEIGH-Taylor instability, TRITIUM, DEUTERIUM, RADIOGRAPHY, PHYSICS

Abstract

Double shell capsule implosions are an alternative approach to achieving alpha heating on the National Ignition Facility. Current machining techniques construct the outer shell as two hemispheres that are glued together, and the deuterium and tritium (DT) liquid inside the inner shell will be injected by a fill tube. These features introduce asymmetries and jetting that may disrupt the confinement of the DT fuel if not carefully controlled. Simulations indicate that in order to achieve high yields in the laboratory, these features as well as susceptibility to the Rayleigh–Taylor instability (RTI) must be mitigated. Due to uncertainties in computational models and the expense of using the best physics models at adequate resolution in three dimensions, our computational modeling must be constrained by experiments. We report on the results of recent hydrogrowth radiography and dual-axis keyhole experiments with double shell targets that have been used to evaluate our modeling of the outer shell joint as well as the impacts of high-energy x-ray preheat that strongly impacts RTI growth. Our simulations show good agreement with the experimental data and inform several important modeling choices. [ABSTRACT FROM AUTHOR]

Published

2021

5. Experimental results of radiation-driven, layered deuterium-tritium implosions with adiabat-shaped drives at the National Ignition Facility.

Author

Smalyuk, V. A., Robey, H. F., D€oppner, T., Casey, D. T., Clark, D. S., Jones, O. S., Milovich, J. L., Peterson, J. L., Bachmann, B., Baker, K. L., Benedetti, L. R., Hopkins, L. F. Berzak, Bionta, R., Bond, E., Bradley, D. K., Callahan, D. A., Celliers, P. M., Cerjan, C., Chen, K.-C., and Goyon, C.

Subjects

*RADIATION, *DEUTERIUM, *TRITIUM, *NEUTRON emission, *PLASMA instabilities, *MAGNETIC flux compression

Abstract

Radiation-driven, layered deuterium-tritium (DT) implosions were carried out using 3-shock and 4-shock “adiabat-shaped” drives and plastic ablators on the National Ignition Facility (NIF) [E. M. Campbell et al., AIP Conf. Proc. 429, 3 (1998)]. The purpose of these shots was to gain further understanding on the relative performance of the low-foot implosions of the National Ignition Campaign [M. J. Edwards et al., Phys. Plasmas 20, 070501 (2013)] versus the subsequent high-foot implosions [T. Döppner et al., Phys. Rev. Lett. 115, 055001 (2015)]. The neutron yield performance in the experiment with the 4-shock adiabat-shaped drive was improved by factors ∼3 to ∼10, compared to five companion low-foot shots despite large low-mode asymmetries of DT fuel, while measured compression was similar to its low-foot companions. This indicated that the dominant degradation source for low-foot implosions was ablation-front instability growth, since adiabat shaping significantly stabilized this growth. For the experiment with the low-power 3-shock adiabat-shaped drive, the DT fuel compression was significantly increased, by ∼25% to ∼36%, compared to its companion high-foot implosions. The neutron yield increased by ∼20%, lower than the increase of ∼50% estimated from one-dimensional scaling, suggesting the importance of residual instabilities and asymmetries. For the experiment with the high-power, 3-shock adiabat-shaped drive, the DT fuel compression was slightly increased by ∼14% compared to its companion high-foot experiments. However, the compression was reduced compared to the lower-power 3-shock adiabat-shaped drive, correlated with the increase of hot electrons that hypothetically can be responsible for reduced compression in high-power adiabat-shaped experiments as well as in high-foot experiments. The total neutron yield in the high-power 3-shock adiabat-shaped shot N150416 was 8.5 × 1015 ± 0.2 × 1015, with the fuel areal density of 0.90 ± 0.07 g/cm2, corresponding to the ignition threshold factor parameter IFTX (calculated without alpha heating) of 0.34 ± 0.03 and the yield amplification due to the alpha heating of 2.4 ± 0.2. The performance parameters were among the highest of all shots on NIF and the closest to ignition at this time, based on the IFTX metric. The follow-up experiments were proposed to continue testing physics hypotheses, to measure implosion reproducibility, and to improve quantitative understanding on present implosion results. [ABSTRACT FROM AUTHOR]

Published

2016

6. First results of radiation-driven, layered deuterium-tritium implosions with a 3-shock adiabat-shaped drive at the National Ignition Facility.

Author

Smalyuk, V. A., Robey, H. F., Döppner, T., Jones, O. S., Milovich, J. L., Bachmann, B., Baker, K. L., Hopkins, L. F. Berzak, Bond, E., Callahan, D. A., Casey, D. T., Celliers, P. M., Cerjan, C., Clark, D. S., Dixit, S. N., Edwards, M. J., Giraldez, E., Haan, S. W., Hamza, A. V., and Hohenberger, M.

Subjects

*DEUTERIUM, *TRITIUM, *ADIABATIC flow, *MATERIAL plasticity, *ENERGY density

Abstract

Radiation-driven, layered deuterium-tritium plastic capsule implosions were carried out using a new, 3-shock "adiabat-shaped" drive on the National Ignition Facility. The purpose of adiabat shaping is to use a stronger first shock, reducing hydrodynamic instability growth in the ablator. The shock can decay before reaching the deuterium-tritium fuel leaving it on a low adiabat and allowing higher fuel compression. The fuel areal density was improved by ~25% with this new drive compared to similar "high-foot" implosions, while neutron yield was improved by more than 4 times, compared to "low-foot" implosions driven at the same compression and implosion velocity. [ABSTRACT FROM AUTHOR]

Published

2015

7. Measurement of High-Pressure Shock Waves in Cryogenic Deuterium-Tritium Ice Layered Capsule Implosions on NIF.

Author

Robey, H. F., Moody, J. D., Celliers, P. M., Ross, J. S., Ralph, J., Le Pape, S., Berzak Hopkins, L., Parham, T., Sater, J., Mapoles, E. R., Holunga, D. M., Walters, C. F., Haid, B. J., Kozioziemski, B. J., Dylla-Spears, R. J., Krauter, K. G., Frieders, G., Ross, G., Bowers, M. W., and Strozzi, D. J.

Subjects

*SHOCK waves measurement, *CRYOGENICS, *DEUTERIUM, *TRITIUM, *ENTROPY

Abstract

The first measurements of multiple, high-pressure shock waves in cryogenic deuterium-tritium (DT) ice layered capsule implosions on the National Ignition Facility have been performed. The strength and relative timing of these shocks must be adjusted to very high precision in order to keep the DT fuel entropy low and compressibility high. All previous measurements of shock timing in inertial confinement fusion implosions [T. R. Boehly et al., Phys. Rev. Lett. 106 195005 (2011), H. F. Robey et al., Phys. Rev. Lett. 108 215004 (2012)] have been performed in surrogate targets, where the solid DT ice shell and central DT gas regions were replaced with a continuous liquid deuterium (D2) fill. This report presents the first experimental validation of the assumptions underlying this surrogate technique. [ABSTRACT FROM AUTHOR]

Published

2013

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

Author

Clark, D. S., Hinkel, D. E., Eder, D. C., Jones, O. S., Haan, S. W., Hammel, B. A., Marinak, M. M., Milovich, J. L., Robey, H. F., Suter, L. J., and Town, R. P. J.

Subjects

DEUTERIUM compounds, TRITIUM, HYDRODYNAMICS, ION temperature, NEUTRON scattering, SURFACE roughness, PHYSICS experiments, SIMULATION methods & models

Abstract

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 et al., 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, et al., 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. [ABSTRACT FROM AUTHOR]

Published

2013

9. Shock timing experiments on the National Ignition Facility: Initial results and comparison with simulation.

Author

Robey, H. F., Boehly, T. R., Celliers, P. M., Eggert, J. H., Hicks, D., Smith, R. F., Collins, R., Bowers, M. W., Krauter, K. G., Datte, P. S., Munro, D. H., Milovich, J. L., Jones, O. S., Michel, P. A., Thomas, C. A., Olson, R. E., Pollaine, S., Town, R. P. J., Haan, S., and Callahan, D.

Subjects

*DEUTERIUM, *TRITIUM, *SHOCK waves, *NUCLEAR fusion, *COMPUTER simulation, *FUEL, *PLASMA gases

Abstract

Capsule implosions on the National Ignition Facility (NIF) [Lindl et al., Phys. Plasmas 11, 339 (2004)] are underway with the goal of compressing deuterium-tritium (DT) fuel to a sufficiently high areal density (ρR) to sustain a self-propagating burn wave required for fusion power gain greater than unity. These implosions are driven with a carefully tailored sequence of four shock waves that must be timed to very high precision in order to keep the DT fuel on a low adiabat. Initial experiments to measure the strength and relative timing of these shocks have been conducted on NIF in a specially designed surrogate target platform known as the keyhole target. This target geometry and the associated diagnostics are described in detail. The initial data are presented and compared with numerical simulations. As the primary goal of these experiments is to assess and minimize the adiabat in related DT implosions, a methodology is described for quantifying the adiabat from the shock velocity measurements. Results are contrasted between early experiments that exhibited very poor shock timing and subsequent experiments where a modified target geometry demonstrated significant improvement. [ABSTRACT FROM AUTHOR]

Published

2012

10. High-Adiabat High-Foot Inertial Confinement Fusion Implosion Experiments on the National Ignition Facility.

Author

Park, H.-S., Hurricane, O. A., Callahan, D. A., Casey, D. T., Dewald, E. L., Dittrich, T. R., Döppner, T., Hinkel, D. E., Berzak Hopkins, L. F., Le Pape, S., Ma, T., Patel, P. K., Remington, B. A., Robey, H. F., Salmonson, J. D., and Kline, J. L.

Subjects

*INERTIAL confinement fusion, *DEUTERIUM, *TRITIUM, *EXPERIMENTS, *SIMULATION methods & models

Abstract

This Letter reports on a series of high-adiabat implosions of cryogenic layered deuterium-tritium (DT) capsules indirectly driven by a "high-foot" laser drive pulse at the National Ignition Facility. High-foot implosions have high ablation velocities and large density gradient scale lengths and are more resistant to ablation-front Rayleigh-Taylor instability induced mixing of ablator material into the DT hot spot. Indeed, the observed hot spot mix in these implosions was low and the measured neutron yields were typically 50% (or higher) of the yields predicted by simulation. On one high performing shot (N130812), 1.7 MJ of laser energy at a peak power of 350 TW was used to obtain a peak hohlraum radiation temperature of ~300 eV. The resulting experimental neutron yield was (2.4±0.05)×1015 DT, the fuel ρR was (0.86±0.063) g/cm², and the measured Tion was (4.2±0.16) keV, corresponding to 8 kJ of fusion yield, with ~1/3 of the yield caused by self-heating of the fuel by a particles emitted in the initial reactions. The generalized Lawson criteria, an ignition metric, was 0.43 and the neutron yield was ~70% of the value predicted by simulations that include α-particle self-heating. [ABSTRACT FROM AUTHOR]

Published

2014

11. Assembly of High-Areal-Density Deuterium-Tritium Fuel from Indirectly Driven Cryogenic Implosions.

Author

Mackinnon, A. J., Kline, J. L., Dixit, S. N., Glenzer, S. H., Edwards, M. J., Callahan, D. A., Meezan, N. B., Haan, S. W., Kilkenny, J. D., Döppner, T., Farley, D. R., Moody, J. D., Ralph, J. E., MacGowan, B. J., Landen, O. L., Robey, H. F., Boehly, T. R., Celliers, P. M., Eggert, J. H., and Krauter, K.

Subjects

*TRITIUM, *CRYOGENIC liquids, *LASER beams, *NEUTRONS, *PARAMETER estimation, *TOTAL energy systems (On-site electric power production), *TEMPERATURE measurements

Abstract

The National Ignition Facility has been used to compress deuterium-tritium to an average areal density of ∼1.0 ± 0 .1 gem-2, which is 67% of the ignition requirement. These conditions were obtained using 192 laser beams with total energy of 1-1.6 MJ and peak power up to 420 TW to create a hohlraum drive with a shaped power profile, peaking at a soft x-ray radiation temperature of 275-300 eV. This pulse delivered a series of shocks that compressed a capsule containing cryogenic deuterium-tritium to a radius of 25-35 &mgr;m. Neutron images of the implosion were used to estimate a fuel density of 500-800 g cm-3. [ABSTRACT FROM AUTHOR]

Published

2012