Your search keyword '"Daniel Casey"' showing total 58 results

1. Interpolating individual line-of-sight neutron spectrometer measurements onto the 'sky' at the National Ignition Facility (NIF)

Author

Gary Grim, Daniel Casey, E. P. Hartouni, D. H. Munro, A. L. Kritcher, David Schlossberg, Alex Zylstra, B. J. MacGowan, Mark Eckart, J. Jeet, A. S. Moore, K. D. Hahn, Shaun Kerr, Maria Gatu-Johnson, and R. M. Bionta

Subjects

Physics, Line-of-sight, Spectrometer, Sky, media_common.quotation_subject, Implosion, Neutron, National Ignition Facility, Instrumentation, Inertial confinement fusion, Interpolation, Computational physics, media_common

Abstract

Nuclear diagnostics provide measurements of inertial confinement fusion implosions used as metrics of performance for the shot. The interpretation of these measurements for shots with low mode asymmetries requires a way of combining the data to produce a "sky map" where the individual line-of-sight values are used to interpolate to other positions in the sky. These interpolations can provide information regarding the orientation of the low mode asymmetries. We describe the interpolation method, associated uncertainties, and correlations between different metrics, e.g., Tion, down scatter ratio, and hot-spot velocity direction. This work is also related to recently reported studies [H. G. Rinderknecht et al., Phys. Rev. Lett. 124, 145002 (2020) and K. M. Woo et al., Phys. Plasmas 27, 062702 (2020)] of low mode asymmetries. We report an analysis that makes use of a newly commissioned line of sight, a scheme for incorporating multiple neutron spectrum measurement types, and recent work on the sources of implosion asymmetry to provide a more complete picture of implosion performance.

Published

2021

2. Evidence of Three-Dimensional Asymmetries Seeded by High-Density Carbon-Ablator Nonuniformity in Experiments at the National Ignition Facility

Author

S. Le Pape, David Schlossberg, J. D. Sater, Kevin Baker, Jürgen Biener, Harry Robey, C. R. Weber, Daniel Casey, C. Kong, S. W. Haan, A. L. Kritcher, Jose Milovich, K. Sequoia, Michael Farrell, Alex Zylstra, Omar Hurricane, R. M. Bionta, M. Bruhn, Steven Ross, Ryan Nora, A. Nikroo, Michael Stadermann, B. J. MacGowan, H. Huang, K. D. Hahn, A. S. Moore, Christoph Wild, Neal Rice, Debra Callahan, Matthias Hohenberger, Tilo Döppner, Otto Landen, and Christopher Young

Subjects

Materials science, Shell (structure), General Physics and Astronomy, Implosion, Hot spot (veterinary medicine), Kinetic energy, Computational physics, law.invention, Ignition system, Physics::Plasma Physics, law, Area density, National Ignition Facility, Inertial confinement fusion

Abstract

Inertial confinement fusion implosions must achieve high in-flight shell velocity, sufficient energy coupling between the hot spot and imploding shell, and high areal density (ρR=∫ρdr) at stagnation. Asymmetries in ρR degrade the coupling of shell kinetic energy to the hot spot and reduce the confinement of that energy. We present the first evidence that nonuniformity in the ablator shell thickness (∼0.5% of the total thickness) in high-density carbon experiments is a significant cause for observed 3D ρR asymmetries at the National Ignition Facility. These shell-thickness nonuniformities have significantly impacted some recent experiments leading to ρR asymmetries on the order of ∼25% of the average ρR and hot spot velocities of ∼100 km/s. This work reveals the origin of a significant implosion performance degradation in ignition experiments and places stringent new requirements on capsule thickness metrology and symmetry.

Published

2021

3. Record Energetics for an Inertial Fusion Implosion at NIF

Author

David C. Clark, Debra Callahan, Alex Zylstra, A. L. Kritcher, Joseph Ralph, Otto Landen, M. J. Edwards, A. Nikroo, Tilo Döppner, T. Braun, M. Schoff, Kevin Baker, Christopher Young, K Clark, Denise Hinkel, Omar Hurricane, Christoph Wild, David Strozzi, Michael Stadermann, C. R. Weber, Neal Rice, P. K. Patel, Matthias Hohenberger, C. Kong, Daniel Casey, R. Tommasini, Laurent Divol, Arthur Pak, and Richard Town

Subjects

Physics, Work (thermodynamics), Internal energy, Nuclear engineering, General Physics and Astronomy, Implosion, Figure of merit, Plasma, National Ignition Facility, Kinetic energy, Inertial confinement fusion

Abstract

Inertial confinement fusion seeks to create burning plasma conditions in a spherical capsule implosion, which requires efficiently absorbing the driver energy in the capsule, transferring that energy into kinetic energy of the imploding DT fuel and then into internal energy of the fuel at stagnation. We report new implosions conducted on the National Ignition Facility (NIF) with several improvements on recent work [Phys. Rev. Lett. 120, 245003 (2018)PRLTAO0031-900710.1103/PhysRevLett.120.245003; Phys. Rev. E 102, 023210 (2020)PRESCM2470-004510.1103/PhysRevE.102.023210]: larger capsules, thicker fuel layers to mitigate fuel-ablator mix, and new symmetry control via cross-beam energy transfer; at modest velocities, these experiments achieve record values for the implosion energetics figures of merit as well as fusion yield for a NIF experiment.

Published

2021

4. Density determination of the thermonuclear fuel region in inertial confinement fusion implosions

Author

Frank E. Merrill, Steven H. Batha, K. McGlinchey, Doug Wilson, David N. Fittinghoff, Petr Volegov, Jeremy Chittenden, Christopher Danly, Brian Appelbe, Daniel Casey, Aidan Crilly, Carl Wilde, V. Geppert-Kleinrath, Engineering & Physical Science Research Council (EPSRC), Lawrence Livermore National Laboratory, and AWE Plc

Subjects

Thermonuclear fusion, Nuclear Theory, Inelastic collision, General Physics and Astronomy, Implosion, 02 engineering and technology, 01 natural sciences, 09 Engineering, Physics, Applied, Physics::Plasma Physics, 0103 physical sciences, Nuclear fusion, Neutron, Nuclear Experiment, Inertial confinement fusion, 01 Mathematical Sciences, Applied Physics, 010302 applied physics, Physics, Science & Technology, 02 Physical Sciences, Neutron imaging, Detector, 021001 nanoscience & nanotechnology, Computational physics, Physical Sciences, 0210 nano-technology

Abstract

Understanding of the thermonuclear burn in an inertial confinement fusion implosion requires knowledge of the local deuterium–tritium (DT) fuel density. Neutron imaging of the core now provides this previously unavailable information. Two types of neutron images are required. The first is an image of the primary 14-MeV neutrons produced by the D + T fusion reaction. The second is an image of the 14-MeV neutrons that leave the implosion hot spot and are downscattered to lower energy by elastic and inelastic collisions in the fuel. These neutrons are measured by gating the detector to record the 6–12 MeV neutrons. Using the reconstructed primary image as a nonuniform source, a set of linear equations is derived that describes the contribution of each voxel of the DT fuel region to a pixel in the downscattered image. Using the measured intensity of the 14-MeV neutrons and downscattered images, the set of equations is solved for the density distribution in the fuel region. The method is validated against test problems and simulations of high-yield implosions. The calculated DT density distribution from one experiment is presented.Understanding of the thermonuclear burn in an inertial confinement fusion implosion requires knowledge of the local deuterium–tritium (DT) fuel density. Neutron imaging of the core now provides this previously unavailable information. Two types of neutron images are required. The first is an image of the primary 14-MeV neutrons produced by the D + T fusion reaction. The second is an image of the 14-MeV neutrons that leave the implosion hot spot and are downscattered to lower energy by elastic and inelastic collisions in the fuel. These neutrons are measured by gating the detector to record the 6–12 MeV neutrons. Using the reconstructed primary image as a nonuniform source, a set of linear equations is derived that describes the contribution of each voxel of the DT fuel region to a pixel in the downscattered image. Using the measured intensity of the 14-MeV neutrons and downscattered images, the set of equat...

Published

2020

5. Azimuthal Drive Asymmetry in Inertial Confinement Fusion Implosions on the National Ignition Facility

Author

Otto Landen, B. J. MacGowan, R. M. Bionta, Omar Hurricane, Robert Hatarik, Daniel Casey, E. P. Hartouni, Hans G. Rinderknecht, and P. K. Patel

Subjects

Physics, media_common.quotation_subject, General Physics and Astronomy, Implosion, Radiation, 01 natural sciences, Asymmetry, Nuclear physics, Amplitude, Physics::Plasma Physics, Hohlraum, 0103 physical sciences, Neutron, 010306 general physics, National Ignition Facility, Inertial confinement fusion, media_common

Abstract

Data from nuclear diagnostics present correlated signatures of azimuthal implosion asymmetry in recent indirect-drive inertial confinement fusion (ICF) implosion campaigns performed at the National Ignition Facility (NIF). The mean hot-spot velocity, inferred from the Doppler shift of 14 MeV neutrons produced by deuterium-tritium (DT) fusion, is systematically directed toward one azimuthal half of the NIF target chamber, centered on $\ensuremath{\phi}\ensuremath{\approx}70\ifmmode^\circ\else\textdegree\fi{}$. Areal density ($\ensuremath{\rho}R$) asymmetry of the converged DT fuel, inferred from nuclear activation diagnostics, presents a minimum $\ensuremath{\rho}R$ in the same direction as the hot-spot velocity and with $\mathrm{\ensuremath{\Delta}}\ensuremath{\rho}R$ amplitude correlated with velocity magnitude. These two correlated observations, which are seen in all recent campaigns with cryogenic layers of DT fuel, are a known signature of asymmetry in the fuel convergence, implying a systematic azimuthal drive asymmetry across a wide range of shot and target configurations. The direction of the implied radiation asymmetry is observed to cluster toward the hohlraum diagnostic windows. This low-mode asymmetry degrades hot-spot conditions at peak convergence and limits implosion performance and yield.

Published

2019

6. Thermonuclear reactions probed at stellar-core conditions with laser-based inertial-confinement fusion

Author

L. F. Berzak Hopkins, Johan Frenje, T. Kohut, Carl R. Brune, Laurent Divol, Daniel Sayre, J. Pino, T. G. Parham, Gary Grim, Laura Robin Benedetti, Robert Tipton, Jay D. Salmonson, J. A. Caggiano, Bruce Remington, James McNaney, C. R. Weber, Daniel Casey, Arthur Pak, Shahab Khan, Robert Hatarik, V. A. Smalyuk, George A. Kyrala, D. P. McNabb, Tammy Ma, Steve MacLaren, Maria Gatu-Johnson, D. Dearborn, Sebastien LePape, Brian Spears, D. M. Holunga, C. B. Yeamans, M. Chiarappa-Zucca, N. Izumi, and Nathan Meezan

Subjects

Nuclear reaction, Physics, Fusion, Thermonuclear fusion, General Physics and Astronomy, Implosion, Laser, 01 natural sciences, 010305 fluids & plasmas, law.invention, Nuclear physics, Stars, Physics::Plasma Physics, law, Phase (matter), 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, 010306 general physics, Inertial confinement fusion, Astrophysics::Galaxy Astrophysics

Abstract

Nuclear reactions taking place in stars are not straightforward to study in laboratories on Earth. Now, inertial-confinement fusion implosion experiments are reported that mimic the conditions for the hydrogen-burning phase in main-sequence stars.

Published

2017

7. Hotspot parameter scaling with velocity and yield for high-adiabat layered implosions at the National Ignition Facility

Author

Ryan Nora, Marius Millot, C. R. Weber, Daniel Casey, Peter M. Celliers, Nobuhiko Izumi, R. M. Bionta, A. L. Kritcher, Robert Hatarik, Benjamin Bachmann, Tammy Ma, D. T. Woods, Clement Goyon, Omar Hurricane, K. D. Meaney, C. Wilde, S. Khan, Kevin Baker, David Strozzi, George A. Kyrala, C. B. Yeamans, Jose Milovich, Matthias Hohenberger, Otto Landen, David N. Fittinghoff, David Turnbull, David C. Clark, M. Gatu Johnson, Laura Robin Benedetti, Debra Callahan, Sabrina Nagel, C. A. Thomas, Richard Berger, Brian Spears, P. K. Patel, and Petr Volegov

Subjects

Physics, Fusion, Extrapolation, Implosion, Mechanics, 01 natural sciences, Power law, 010305 fluids & plasmas, law.invention, Ignition system, Physics::Plasma Physics, law, 0103 physical sciences, Hotspot (geology), 010306 general physics, National Ignition Facility, Scaling

Abstract

This paper presents a study on hotspot parameters in indirect-drive, inertially confined fusion implosions as they proceed through the self-heating regime. The implosions with increasing nuclear yield reach the burning-plasma regime, hotspot ignition, and finally propagating burn and ignition. These implosions span a wide range of alpha heating from a yield amplification of 1.7-2.5. We show that the hotspot parameters are explicitly dependent on both yield and velocity and that by fitting to both of these quantities the hotspot parameters can be fit with a single power law in velocity. The yield scaling also enables the hotspot parameters extrapolation to higher yields. This is important as various degradation mechanisms can occur on a given implosion at fixed implosion velocity which can have a large impact on both yield and the hotspot parameters. The yield scaling also enables the experimental dependence of the hotspot parameters on yield amplification to be determined. The implosions reported have resulted in the highest yield (1.73×10^{16}±2.6%), yield amplification, pressure, and implosion velocity yet reported at the National Ignition Facility.

Published

2019

8. Three-dimensional diagnostics and measurements of inertial confinement fusion plasmas

Author

R. M. Bionta, K. D. Hahn, E. P. Hartouni, Daniel Casey, V. Geppert-Kleinrath, David Schlossberg, Shaun Kerr, Alastair Moore, Mark Eckart, Gary Grim, J. Jeet, David N. Fittinghoff, A. J. Mackinnon, and Petr Volegov

Subjects

010302 applied physics, Physics, Drift velocity, media_common.quotation_subject, Implosion, Plasma, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, Computational physics, 0103 physical sciences, Electron temperature, Neutron, National Ignition Facility, Instrumentation, Inertial confinement fusion, media_common

Abstract

Recent inertial confinement fusion measurements have highlighted the importance of 3D asymmetry effects on implosion performance. One prominent example is the bulk drift velocity of the deuterium–tritium plasma undergoing fusion (“hotspot”), vHS. Upgrades to the National Ignition Facility neutron time-of-flight diagnostics now provide vHS to better than 1 part in 104 and enable cross correlations with other measurements. This work presents the impact of vHS on the neutron yield, downscatter ratio, apparent ion temperature, electron temperature, and 2D x-ray emission. The necessary improvements to diagnostic suites to take these measurements are also detailed. The benefits of using cross-diagnostic analysis to test hotspot models and theory are discussed, and cross-shot trends are shown.

Published

2021

9. Three dimensional low-mode areal-density non-uniformities in indirect-drive implosions at the National Ignition Facility

Author

J. L. Peterson, J. E. Field, David Schlossberg, D. H. Munro, B. J. MacGowan, Michael Kruse, David N. Fittinghoff, Alex Zylstra, V. A. Smalyuk, Daniel Casey, E. P. Hartouni, Jose Milovich, A. L. Kritcher, Christopher Young, A. S. Moore, R. M. Bionta, Carl Wilde, K. D. Hahn, Brian Spears, V. Geppert-Kleinrath, Johan Frenje, Jim Gaffney, Kelli Humbird, Omar Hurricane, Maria Gatu-Johnson, Ryan Nora, Daniel S. Clark, Debra Callahan, Petr Volegov, and Otto Landen

Subjects

Physics, Coupling, Neutron transport, media_common.quotation_subject, Shell (structure), Implosion, Condensed Matter Physics, Kinetic energy, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, Computational physics, 0103 physical sciences, 010306 general physics, National Ignition Facility, Inertial confinement fusion, media_common

Abstract

To achieve hotspot ignition, an inertial confinement fusion implosion must achieve high hotspot pressure that is inertially confined by a dense shell of DT fuel. This requires a symmetric implosion having high in-flight shell velocity and high areal density at stagnation. The size of the driver and scale of the capsule required can be minimized by maintaining a high efficiency of energy coupling from the imploding shell to the hotspot. Significant 3D low mode asymmetries, however, are commonly observed in indirect-drive implosions and reduce the coupling of shell kinetic energy to the hotspot. To better quantify the magnitudes and impacts of shell density asymmetries, we have developed new analysis techniques and analytic models [Hurricane et al., Phys. Plasmas 27(6), 062704 (2020)]. To build confidence in the underlying data, we have also developed an analytic neutron transport model to cross-compare two independent measurements of asymmetry, which shows excellent agreement across shots for mode-1 (l = 1). This work also demonstrates that asymmetry can introduce potential sampling bias into down-scattered ratio measurements causing the solid-angle-average and uncertainty-weighted-average down-scattered ratios to differ significantly. Diagnosing asymmetries beyond mode-1 (l > 1) presents significant challenges. Using new diagnostic instruments and analysis techniques, however, evidence of significant Legendre mode P2 (l = 2, m = 0) and additional 3D asymmetries (l > 1, m ≠ 0) are beginning to emerge from the high precision activation diagnostic data (real-time nuclear activation detectors) and down-scattered neutron imaging data.

Published

2021

10. Fuel convergence sensitivity in indirect drive implosions

Author

Omar Hurricane, K. D. Meaney, Peter M. Celliers, B. J. MacGowan, N. Gharibyan, Marius Millot, S. W. Haan, Jose Milovich, Steve MacLaren, J. D. Lindl, P. T. Springer, E. P. Hartouni, Gary Grim, V. N. Goncharov, David N. Fittinghoff, P. K. Patel, M. J. Edwards, Daniel Casey, Petr Volegov, H. S. Robey, and Otto Landen

Subjects

Physics, Implosion, Mechanics, Condensed Matter Physics, 01 natural sciences, Aspect ratio (image), 010305 fluids & plasmas, Shock (mechanics), law.invention, Ignition system, Physics::Plasma Physics, law, 0103 physical sciences, Compressibility, 010306 general physics, National Ignition Facility, Scaling, Inertial confinement fusion

Abstract

In inertial confinement fusion experiments at the National Ignition Facility, a spherical shell of deuterium–tritium fuel is imploded in an attempt to reach the conditions needed for fusion, self-heating, and eventual ignition. Since theory and simulations indicate that ignition efficacy in 1D improves with increasing imploded fuel convergence ratio, it is useful to understand the sensitivity of the scale-invariant fuel convergence on all measurable or inferable 1D parameters. In this paper, we develop a simple isobaric and isentropic compression scaling model incorporating sensitivity to the in-flight adiabat inferred from shock strengths, to measured implosion velocity, and to known initial ablator and fuel aspect ratio and mass ratio. The model is first benchmarked to 1D implosion simulations spanning a variety of relevant implosion designs. We then use the model to compare compressibility trends across all existing indirect-drive layered implosion data from the facility spanning three ablators [CH, carbon (C), and Be], for which in-flight fuel adiabats varied from 1.6 to 5 by varying the number of drive shocks from 2 to 4, peak implosion velocities varied by 1.4×, capsule radii by 50%, and initial fuel aspect ratios by 1.4×. We find that the strength of the first shock is the dominant contributor setting the maximum fuel convergence. We also observe additional sensitivities to successive shock strengths and fuel aspect ratios that improve the agreement between the expected and measured compression for carbon and Be designs with adiabats above 3. A principal finding is that the adiabat 2.5 C-shell designs exhibit less convergence than CH-shell designs of similar inferred in-flight adiabat.

Published

2021

11. A second order yield-temperature relation for accurate inference of burn-averaged quantities in multi-species plasmas

Author

H. Sio, M. Gatu Johnson, Patrick Adrian, R. D. Petrasso, Fredrick Seguin, Owen Mannion, Graeme Sutcliffe, Arijit Bose, Johan Frenje, H. G. Rinderknecht, Neel Kabadi, Brandon Lahmann, Daniel Casey, and Alex Zylstra

Subjects

Physics, Time evolution, Implosion, Decoupling (cosmology), Plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Ion, Computational physics, Amplitude, Physics::Plasma Physics, Yield (chemistry), 0103 physical sciences, Thermal, 010306 general physics

Abstract

Measured yields and ion temperatures inferred from the fusion product energy spectra can be used as metrics for the performance of an ICF implosion. This can be used to infer species separation, thermal decoupling, flows, or other effects that can cause the inferred ion temperatures to deviate from the true underlying thermal temperature and the yield ratio to deviate from the expected value. Direct inference of the impact of these effects on observed temperatures and yields can be difficult to uncover due to the underlying dependence on the shape and time evolution of the temperature and density profiles of the fusing plasma. Due to differences in the temperature dependence of the reactivities, different fusion products are emitted from different regions and times within the implosion. In order to properly account for this, a second-order analytical expression relating the apparent temperatures and yield ratios is developed. This expression can be coupled to models of yield and/or temperature altering effects to infer their burn-averaged impact on an implosion. The second-order expression shows significant improvement over lower-order expressions in synthetic data studies. Demonstrations of its applications to synthetic data coupled with models of ion thermal decoupling and radial flows are presented. In the case of thermal decoupling, both first and second-order expressions show reasonable levels of accuracy. To consistently infer the amplitude of radial flow with a

Published

2021

12. Low mode implosion symmetry sensitivity in low gas-fill NIF cylindrical hohlraums

Author

Laurent Divol, W. W. Hsing, Daniel Casey, A. L. Kritcher, Hui Chen, Nobuhiko Izumi, Marilyn Schneider, J. D. Moody, M. D. Rosen, Nathan Meezan, James Ross, M. J. Edwards, Matthias Hohenberger, Otto Landen, D. T. Woods, and Debra Callahan

Subjects

Physics, business.industry, media_common.quotation_subject, Implosion, Plasma, Radius, Condensed Matter Physics, Laser, 01 natural sciences, Asymmetry, Symmetry (physics), 010305 fluids & plasmas, law.invention, Optics, Physics::Plasma Physics, Hohlraum, law, 0103 physical sciences, 010306 general physics, business, National Ignition Facility, media_common

Abstract

Achieving an efficient capsule implosion in National Ignition Facility indirect-drive target experiments requires symmetric hohlraum x-ray drive for the duration of the laser pulse. This is commonly achieved using two-sided two-cone laser irradiation of cylindrical hohlraums that, in principle, can zero the time average of all spherical harmonic asymmetry modes

Published

2021

13. A direct-drive exploding-pusher implosion as the first step in development of a monoenergetic charged-particle backlighting platform at the National Ignition Facility

Author

Siegfried Glenzer, Laura Robin Benedetti, Bruce Remington, Alex Zylstra, Nelson M. Hoffman, Matthias Hohenberger, J. Pino, M. J. Edwards, J. D. Moody, J. A. Delettrez, Michael Rosenberg, M. D. Rosen, M. Gatu Johnson, Claudio Bellei, Michael J. Moran, A. J. Mackinnon, J. D. Lindl, P. B. Radha, P. W. McKenty, George A. Kyrala, Abbas Nikroo, V. Yu. Glebov, Scott Wilks, Hans W. Herrmann, C. Waugh, J. R. Rygg, D. H. Edgell, James McNaney, Daniel Casey, Hong Sio, J. P. Knauer, Riccardo Betti, C. K. Li, Andrew MacPhee, Johan Frenje, Fredrick Seguin, Damien Hicks, R. D. Petrasso, H.-S. Park, R. J. Leeper, N. Sinenian, Sebastien LePape, Peter Amendt, S. M. Glenn, Tammy Ma, R. E. Olson, R. Zacharias, J. D. Kilkenny, R. M. Bionta, F. J. Marshall, Valeri Goncharov, Nathan Meezan, J. R. Kimbrough, Harry Robey, L. F. Berzak Hopkins, Laurent Divol, T. C. Sangster, Hans Rinderknecht, and Otto Landen

Subjects

Physics, Nuclear and High Energy Physics, Range (particle radiation), Radiation, Proton, Nuclear Theory, Implosion, Warm dense matter, 01 natural sciences, Charged particle, 010305 fluids & plasmas, Nuclear physics, Physics::Plasma Physics, 0103 physical sciences, Stopping power (particle radiation), Nuclear Experiment, 010306 general physics, National Ignition Facility, Inertial confinement fusion

Abstract

A thin-glass-shell, D3He-filled exploding-pusher inertial confinement fusion implosion at the National Ignition Facility (NIF) has been demonstrated as a proton source that serves as a promising first step toward development of a monoenergetic proton, alpha, and triton backlighting platform at the NIF. Among the key measurements, the D3He-proton emission on this experiment (shot N121128) has been well-characterized spectrally, temporally, and in terms of emission isotropy, revealing a highly monoenergetic ( Δ E / E ∼ 4 % ) and isotropic source (~3% proton fluence variation and ~0.5% proton energy variation). On a similar shot (N130129, with D2 fill), the DD-proton spectrum has been obtained as well, illustrating that monoenergetic protons of multiple energies may be utilized in a single experiment. These results, and experiments on OMEGA, point toward future steps in the development of a precision, monoenergetic proton, alpha, and triton source that can readily be implemented at the NIF for backlighting a broad range of high energy density physics (HEDP) experiments in which fields and flows are manifest, and also utilized for studies of stopping power in warm dense matter and in classical plasmas.

Published

2016

14. Integrated performance of large HDC-capsule implosions on the National Ignition Facility

Author

S. Le Pape, Brandon Woodworth, K. Sequoia, James Sevier, C. Kong, Otto Landen, Petr Volegov, Jürgen Biener, Michael Stadermann, Alex Zylstra, Laurent Divol, C. R. Weber, Daniel Casey, M. Schoff, Matthias Hohenberger, H. Huang, Neal Rice, A. L. Kritcher, Kevin Baker, Daniel S. Clark, Debra Callahan, Harry Robey, Tilo Döppner, Jose Milovich, Omar Hurricane, David Strozzi, Denise Hinkel, Benjamin Bachmann, Christoph Wild, Arthur Pak, V. Geppert-Kleinrath, C. A. Thomas, A. Nikroo, and Richard Berger

Subjects

Physics, Yield (engineering), Amplitude, Hohlraum, Implosion, Radius, Radiation, Condensed Matter Physics, National Ignition Facility, Symmetry (physics), Computational physics

Abstract

We report on eight, indirect-drive, deuterium–tritium-layered, inertial-confinement-fusion experiments at the National Ignition Facility to determine the largest capsule that can be driven symmetrically without relying on cross-beam energy transfer or advanced Hohlraum designs. Targets with inner radii of up to 1050 μm exhibited controllable P2 symmetry, while larger capsules suffered from diminished equatorial drive. Reducing the Hohlraum gas-fill-density from 0.45 mg/cm3 to 0.3 mg/cm3 did not result in a favorable shift of P2 amplitude as observed in preceding tuning experiments. Reducing the laser-entrance-hole diameter from 4 mm to 3.64 mm decreased polar radiation losses as expected, resulting in an oblate symmetry. The experiments exhibited the expected performance benefit from increased experimental scale, with yields at a fixed implosion velocity roughly following the predicted 1D dependence. With an inner radius of 1050 μm and a case-to-capsule-ratio of 3.0, experiment N181104 is the lowest implosion-velocity experiment to exceed a total neutron yield of 1016.

Published

2020

15. Principal factors in performance of indirect-drive laser fusion experiments

Author

David C. Clark, M. Gatu Johnson, E. M. Campbell, Petr Volegov, Richard Berger, G. A. Kyrala, P. K. Patel, Gary Grim, Robert Hatarik, David N. Fittinghoff, C. B. Yeamans, Sabrina Nagel, Ryan Nora, Matthias Hohenberger, Peter M. Celliers, Daniel Casey, Marius Millot, Max Tabak, D. T. Woods, Darwin Ho, Benjamin Bachmann, A. L. Kritcher, Brian Spears, Laura Robin Benedetti, A. Nikroo, Jose Milovich, Tammy Ma, Shahab Khan, S. M. Finnegan, C. A. Thomas, David Strozzi, Kevin Baker, Nobuhiko Izumi, and R. M. Bionta

Subjects

Physics, Fusion, Scale (ratio), Implosion, Condensed Matter Physics, Laser, 01 natural sciences, Symmetry (physics), 010305 fluids & plasmas, Computational physics, law.invention, Pulse (physics), law, 0103 physical sciences, 010306 general physics, Inertial confinement fusion, Energy (signal processing)

Abstract

Progress in inertial confinement fusion depends on the accurate interpretation of experiments that are complex and difficult to explain with simulations. Results could depend on small changes in the laser pulse or target or physics that are not fully understood or characterized. In this paper, we discuss an x-ray-driven platform [Baker et al., Phys. Rev. Lett. 121, 135001 (2018)] with fewer sources of degradation and find the fusion yield can be described as a physically motivated function of laser energy, target scale, and implosion symmetry. This platform and analysis could enable a more experimental approach to the study and optimization of implosion physics.

Published

2020

16. Measurement of hydrodynamic instability growth during the deceleration of an inertial confinement fusion implosion

Author

Daniel S. Clark, N. Alfonso, Louisa Pickworth, Alex Zylstra, Arthur Pak, Laura Robin Benedetti, Andrew MacPhee, M. Ratledge, A. L. Kritcher, Shahab Khan, Harry Robey, Michael Stadermann, Suhas Bhandarkar, E. P. Hartouni, C. R. Weber, Daniel Casey, Nobuhiko Izumi, S. Le Pape, S. Diaz, O.N. Landen, L. Berzak-Hopkins, B. A. Hammel, C. F. Walters, S. C. Johnson, V. A. Smalyuk, and Brandon Lahmann

Subjects

Physics, Nuclear and High Energy Physics, Radiation, Design of experiments, Perturbation (astronomy), Implosion, Mechanics, 01 natural sciences, Instability, 010305 fluids & plasmas, Fuel gas, Physics::Plasma Physics, Hohlraum, 0103 physical sciences, 010306 general physics, National Ignition Facility, Inertial confinement fusion

Abstract

This paper presents an exploration of potential mitigation methods for the gas fuel fill tube in Inertial Confinement Fusion (ICF) implosions at the National Ignition Facility (NIF), and the impact of hydrodynamic growth seeded from other target imperfections using a specialized low convergence implosion experiment. Enhanced x-ray self- emission of this experiment design allows the impact of hydrodynamic growth through the deceleration phase of the implosion to be examined. Experiments are presented comparing the perturbation visible during the implosion deceleration that are seeded by the fill tube, through varying the initial geometry in otherwise similar implosions. We further extend the experiment to explore the impact of isolated high atomic number 'dots' of 5 and 20 µm diameter. These isolated dots are compared in two different ‘High Density Carbon’ ablator designs in a gold hohlraum. The experiment series finds a correlation to number of high frequency self-emission features observed in deceleration and degradation in total Deuterium-Deuterium neutron yield.

Published

2020

17. Yield and compression trends and reproducibility at NIF*

Author

A. L. Kritcher, Tilo Doeppner, Peter M. Celliers, Joseph Ralph, Steve MacLaren, Otto Landen, B. M. Van Wonterghem, J. D. Lindl, L. F. Berzak Hopkins, K. D. Meaney, Steven T. Yang, C.A. Thomas, Omar Hurricane, James Ross, C. R. Weber, Daniel Casey, Alex Zylstra, Denise Hinkel, P. K. Patel, J. M. Dinicola, J. D. Moody, M. J. Edwards, Debra Callahan, Louisa Pickworth, V. A. Smalyuk, E. P. Hartouni, J. Park, B. J. MacGowan, Matthias Hohenberger, S. Lepape, Marius Millot, Kevin Baker, and Harry Robey

Subjects

Nuclear and High Energy Physics, Reproducibility, Radiation, Materials science, Yield (engineering), Implosion, Hot spot (veterinary medicine), Mechanics, Compression (physics), 01 natural sciences, 010305 fluids & plasmas, Shock (mechanics), 0103 physical sciences, Neutron, Sensitivity (control systems), 010306 general physics

Abstract

The yield and fuel compression trends for the NIF indirect-drive cryogenically-layered DT implosions is empirically examined across all ablators (CH, C and Be) and design in-flight adiabats between 1.5 and 3. Higher compression is observed for a lower design adiabat. Within a design adiabat, compression increases for shorter coast implosions but only if have optimized shock timing. The sensitivity of compression to coast time appears less for higher adiabat designs. Across all designs and ablators, the best DT neutron yields follow the same 1D theoretical curve versus peak velocity, but only if normalize by capsule scale rather than fuel mass and thickness. Shots with reduced yields can be explained by having long coast time, high hot spot mix or know capsule imperfections. Repeat “Standard Candle” shock timing and gas implosions, and DT layered implosions normalized for scale and velocity, reveal adequate reproducibility in shock timing, implosion drive symmetry, compression and yield for the majority of shots. The level of reproducibility is also consistent with known uncertainties and imperfections in initial laser and capsule parameters and outputs. We thus conclude there is no evidence of a significant random unknown variable in these NIF implosions. The scaled yield reproducibility is such that the effect of design improvements increasing yield on any given shot by at least 40% can be deemed statistically significant.

Published

2020

18. View factor estimation of hot spot velocities in inertial confinement fusion implosions at the National Ignition Facility

Author

Debra Callahan, Christopher Young, Daniel Casey, P. K. Patel, Nathan Meezan, Ryan Nora, Laurent Masse, B. J. MacGowan, and Otto Landen

Subjects

Physics, business.industry, media_common.quotation_subject, Mode (statistics), Implosion, Hot spot (veterinary medicine), Condensed Matter Physics, 01 natural sciences, Asymmetry, View factor, 010305 fluids & plasmas, Optics, Physics::Plasma Physics, Hohlraum, 0103 physical sciences, 010306 general physics, business, National Ignition Facility, Inertial confinement fusion, media_common

Abstract

Inertial confinement fusion (ICF) experiments at the National Ignition Facility suffer from asymmetries in the x-ray drive, which degrade capsule performance compared to expectations for a symmetric one-dimensional implosion. Mode 1, or pole-to-pole, drive asymmetry can reduce confinement and implosion efficiency, driving a bulk motion of the hot spot that is detectable by neutron diagnostics. Understanding and removing sources of mode 1 asymmetry in ICF implosions is important for improving performance, and the three-dimensional nature of the problem makes high-resolution radiation-hydrodynamic modeling extremely computationally expensive. This work describes a reduced order view factor model that calculates the drive asymmetry induced by beam-to-beam variations in laser delivery and Hohlraum diagnostic windows along the equator. The capsule response is estimated by coupling to a Green's function that relates final hot spot velocity to the applied time-varying mode 1 asymmetry. The model makes several predictions about the impact of mode 1 drivers such as laser delivery and target misalignment and achieves good agreement in both the magnitude and the vector direction for several shots in three families of high-performance platforms. However, notable discrepancies suggest that other potential sources of mode 1 asymmetry not captured by the model are also at play.

Published

2020

19. A simple model to scope out parameter space for indirect drive designs on NIF

Author

A. L. Kritcher, Debra Callahan, Omar Hurricane, Denise Hinkel, Alex Zylstra, Daniel Casey, M. D. Rosen, Christopher Young, Yekaterina Opachich, James Ross, Michael Rubery, and H. F. Robey

Subjects

Physics, Implosion, Pulse duration, Parameter space, Condensed Matter Physics, Laser, 01 natural sciences, 010305 fluids & plasmas, Computational physics, law.invention, Hohlraum, law, 0103 physical sciences, Laser power scaling, 010306 general physics, National Ignition Facility, Inertial confinement fusion

Abstract

We present a simple model to scope out parameter space for indirect-drive, inertial confinement fusion designs for the National Ignition Facility laser. Because the parameter space is large, simple models can be used to identify regions of parameter space for further study with more sophisticated models and experiments. We include a model for Hohlraum radiation drive and symmetry—both based on empirical scalings from the data. The model for radiation drive is based on assuming that the high atomic number (Z) Hohlraum wall dominates the energy balance during the high power, peak of the pulse ( ≳300 TW). We find that the time-dependent radiation drive flux can be described by the running integral of the laser energy divided by the Hohlraum area multiplied by constant slopes in two distinct time periods. The first period is when the laser power rises rapidly, so the radiation temperature increases due to changes in laser power and wall albedo. The second period is during peak power—here, the laser power is typically held constant—so, the radiation temperature increases only due to changes in the wall albedo. This model is applied to several NIF designs with different Hohlraum sizes, laser pulse length durations, and peak powers and energies. Drive and symmetry models can be combined to find regions of parameter space that have high capsule absorbed energy while maintaining a symmetric implosion. We propose a new metric for evaluating designs based on minimizing the radius at which the maximum implosion kinetic energy is achieved.

Published

2020

20. An analytic asymmetric-piston model for the impact of mode-1 shell asymmetry on ICF implosions

Author

J. L. Peterson, Otto Landen, Kelli Humbird, Michael Kruse, P. K. Patel, Jim Gaffney, Brian Spears, J. E. Field, Omar Hurricane, A. L. Kritcher, Daniel Casey, and Ryan Nora

Subjects

Physics, Inertial frame of reference, media_common.quotation_subject, Shell (structure), Mode (statistics), Implosion, Mechanics, Condensed Matter Physics, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, law.invention, Piston, Physics::Plasma Physics, law, 0103 physical sciences, 010306 general physics, National Ignition Facility, Stagnation pressure, media_common

Abstract

For many years, low mode asymmetry in inertially confined fusion (ICF) implosions has been recognized as a potential performance limiting factor, but analysis has been limited to using simulations and searching for data correlations. Herein, an analytically solvable model based upon the simple picture of an asymmetric piston is presented. Asymmetry of the shell driving the implosion, as opposed to asymmetry in the hot-spot, is key to the model. The model provides a unifying framework for the action of mode-1 shell asymmetry and the resulting connections between various diagnostic signatures. A key variable in the model is the shell asymmetry fraction, f, which is related to the areal density variation of the shell surrounding the hot-spot. It is shown that f is simply related to the observed hot-spot mode-1 velocity and to the concept of residual energy in an implosion. The model presented in this paper yields explicit expressions for the hot-spot diameter, stagnation pressure, hot-spot energy, inertial confinement-time, Lawson parameter, hot-spot temperature, and fusion yield under the action of mode-1 asymmetry. Agreement is found between the theory scalings when compared to ICF implosion data from the National Ignition Facility and to large ensembles of detailed simulations, making the theory a useful tool for interpreting data. The theory provides a basis for setting tolerable limits on asymmetry.

Published

2020

21. Symmetric fielding of the largest diamond capsule implosions on the NIF

Author

Marius Millot, Neal Rice, T. Braun, Jose Milovich, Debra Callahan, A. L. Kritcher, Brandon Woodworth, Matthias Hohenberger, Alex Zylstra, B. Bachmann, Kevin Baker, Omar Hurricane, Denise Hinkel, Laurent Divol, Harry Robey, David Strozzi, David C. Clark, Jürgen Biener, Tilo Döppner, C. R. Weber, J. Edwards, Derek Mariscal, Michael Stadermann, Daniel Casey, C. A. Thomas, C. Kong, Christoph Wild, James Sevier, A. Nikroo, S. Le Pape, Suhas Bhandarkar, and Arthur Pak

Subjects

Physics, business.industry, Implosion, Diamond, Radius, engineering.material, Condensed Matter Physics, 01 natural sciences, Symmetry (physics), 010305 fluids & plasmas, Radiation flux, Optics, Physics::Plasma Physics, Hohlraum, 0103 physical sciences, engineering, 010306 general physics, National Ignition Facility, business, Beam (structure)

Abstract

We present results for the largest diamond capsule implosions driven symmetrically on the National Ignition Facility (NIF) (inner radius of ∼1050 μm) without the use of cross beam transfer in cylindrical Hohlraums. We show that the methodology of designing Hohlraum parameters in a semi-empirical way using an extensive database resulted in a round implosion. In addition, we show that the radiation flux symmetry is well controlled during the foot of the pulse and that swings in P2 symmetry between the inflight dense shell and hot spot are within ±4 μm and that swings around peak compression are also within the symmetry specification of ±4 μm. We observed a stronger dependence of symmetry on the capsule scale than previously observed and also observed enhanced inner beam propagation for experiments using a gas fill density of 0.3 mg/cm3 and 1000 μm inner radius capsules. We have observed sufficient symmetry and mass remaining at near full NIF power and energy, up to 480 TW and 1.9 MJ, with little laser–plasma interactions (low laser backscattered light) and predict that this design could support extended NIF energy of up to 2.1 MJ.

Published

2020

22. Modeling the 3-D structure of ignition experiments at the NIF

Author

Brian Spears, J. E. Field, Ryan Nora, Daniel Casey, Michael Kruse, P. K. Patel, and Derek Mariscal

Subjects

Physics, Adaptive sampling, media_common.quotation_subject, Implosion, Observable, Mechanics, Parameter space, Condensed Matter Physics, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, law.invention, Ignition system, law, 0103 physical sciences, 010306 general physics, National Ignition Facility, Inertial confinement fusion, media_common

Abstract

This work details a model used to infer the 3-D structure of the stagnated hot-spot and shell of inertial confinement fusion implosion experiments at the National Ignition Facility. The model assumes that 3-D low-mode drive perturbations can account for the majority of stagnation asymmetries experimentally observed. It uses an adaptive sampling algorithm to navigate the 24-D input parameter space to find a 3-D x-ray flux asymmetry whose application to an otherwise symmetric implosion results in a consistent match between synthetic and experimental diagnostic observables. The model is applied to a series of experiments and is able to achieve a consistent match for over 41 different observables, providing a high-fidelity reconstruction of the stagnation hot-spot and shell profile.

Published

2020

23. Fuel gain exceeding unity in an inertially confined fusion implosion

Author

L. F. Berzak Hopkins, E. L. Dewald, Bruce Remington, S. Le Pape, D. A. Callahan, T. Ma, R. Tommasini, P. T. Springer, H.-S. Park, Omar Hurricane, Tilo Döppner, Art Pak, T. R. Dittrich, Daniel Casey, Jose Milovich, C. J. Cerjan, Jay D. Salmonson, D. E. Hinkel, P. M. Celliers, P. K. Patel, John Kline, and Andrew MacPhee

Subjects

Physics, Fusion, Multidisciplinary, business.industry, Nuclear engineering, Implosion, Nanotechnology, Fusion power, law.invention, Ignition system, Physics::Plasma Physics, Fusion ignition, law, Alternative energy, Nuclear fusion, Physics::Chemical Physics, business, National Ignition Facility

Abstract

Ignition is needed to make fusion energy a viable alternative energy source, but has yet to be achieved. A key step on the way to ignition is to have the energy generated through fusion reactions in an inertially confined fusion plasma exceed the amount of energy deposited into the deuterium-tritium fusion fuel and hotspot during the implosion process, resulting in a fuel gain greater than unity. Here we report the achievement of fusion fuel gains exceeding unity on the US National Ignition Facility using a 'high-foot' implosion method, which is a manipulation of the laser pulse shape in a way that reduces instability in the implosion. These experiments show an order-of-magnitude improvement in yield performance over past deuterium-tritium implosion experiments. We also see a significant contribution to the yield from α-particle self-heating and evidence for the 'bootstrapping' required to accelerate the deuterium-tritium fusion burn to eventually 'run away' and ignite.

Published

2014

24. Development of a krypton-doped gas symmetry capsule platform for x-ray spectroscopy of implosion cores on the NIF

Author

Michael Rosenberg, Arthur Pak, H. Chen, Howard A. Scott, Brian Spears, Ryan Nora, Hyun-Kyung Chung, Hong Sio, M. A. Barrios, B. A. Hammel, Leonard Jarrott, L. F. Berzak Hopkins, Shahab Khan, Brandon Lahmann, P. K. Patel, Susan Regan, Tammy Ma, C. R. Weber, Daniel Casey, and Marilyn Schneider

Subjects

X-ray spectroscopy, Materials science, Krypton, Implosion, chemistry.chemical_element, 01 natural sciences, 010305 fluids & plasmas, chemistry, 0103 physical sciences, Plasma diagnostics, Emission spectrum, Atomic physics, 010306 general physics, National Ignition Facility, Spectroscopy, Instrumentation, Inertial confinement fusion

Abstract

The electron temperature at stagnation of an ICF implosion can be measured from the emission spectrum of high-energy x-rays that pass through the cold material surrounding the hot stagnating core. Here we describe a platform developed on the National Ignition Facility where trace levels of a mid-Z dopant (krypton) are added to the fuel gas of a symcap (symmetry surrogate) implosion to allow for the use of x-ray spectroscopy of the krypton line emission.

Published

2016

25. Maintaining low-mode symmetry control with extended pulse shapes for lower-adiabat Bigfoot implosions on the National Ignition Facility

Author

Brian Spears, Otto Landen, Laura Robin Benedetti, N. Izumi, Shahab Khan, Cliff Thomas, Tammy Ma, Kevin Baker, Omar Hurricane, Derek Mariscal, Arthur Pak, Matthias Hohenberger, Daniel Casey, Debra Callahan, and Sabrina Nagel

Subjects

Physics, Hydrodynamic stability, media_common.quotation_subject, Implosion, Mechanics, Condensed Matter Physics, 01 natural sciences, Asymmetry, Symmetry (physics), 010305 fluids & plasmas, Pulse (physics), Hohlraum, 0103 physical sciences, 010306 general physics, National Ignition Facility, Inertial confinement fusion, media_common

Abstract

The Bigfoot approach to indirect-drive inertial confinement fusion has been developed as a compromise trading high convergence and areal densities for high implosion velocities, large adiabats, and hydrodynamic stability. Shape control and predictability are maintained by using relatively short laser pulses and merging the shocks within the deuterium-tritium-ice layer. These design choices ultimately limit the theoretically achievable performance, and one strategy to increase the 1D performance is to reduce the shell adiabat by extending the pulse shape. However, this can result in the loss of low-mode symmetry control, as the hohlraum “bubble,” the high-Z material launched by the outer-cone beams during the early part of the laser pulse, has more time to expand and will eventually intercept inner-cone beams preventing them from reaching the hohlraum waist, thus losing an equatorial capsule drive. Experiments were performed to study the shape control and predictability with extended pulse shapes in Bigfoot implosions, reducing the adiabat from nominally α ∼ 4 to α ∼ 3 and otherwise very similar experimental parameters. The implosion shape was measured both in-flight and at stagnation, with near-round implosions and low levels of P2 asymmetry throughout, indicating a maintained symmetry control with extended pulse shapes.

Published

2019

26. Approaching a burning plasma on the NIF

Author

Omar Hurricane, P. T. Springer, Laurent Masse, Kevin Baker, Alex Zylstra, Joseph Ralph, Daniel Casey, P. K. Patel, Debra Callahan, Petr Volegov, Tilo Döppner, Andrea Kritcher, C. Jarrott, Steve MacLaren, Arthur Pak, L. F. Berzak Hopkins, Laurent Divol, S. Le Pape, Denise Hinkel, Cliff Thomas, and Matthias Hohenberger

Subjects

Physics, Plasma heating, media_common.quotation_subject, Implosion, Plasma, Mechanics, Condensed Matter Physics, Asymmetry, law.invention, Ignition system, Physics::Plasma Physics, law, Astrophysics::Solar and Stellar Astrophysics, Area density, National Ignition Facility, Inertial confinement fusion, media_common

Abstract

The locus of National Ignition Facility (NIF) inertial confinement fusion (ICF) implosion data, in hot-spot burn-average areal density (ρR) and Brysk temperature (T) space, is shown and illustrates that several implosions are nearing a burning plasma state, where α-heating is the dominant source of plasma heating. A formula for diagnosing a burning plasma using measured/inferred data from ICF implosion experiments is given with the underlying derivation. Plotting ICF implosion performance against inferred hot-spot energy illustrates the key need to maximize the delivery of energy to an implosion hot-spot. A very compact analytical equation for α-heating is given, which shows that fundamentally, α-heating provides a discrete “boost” to pVγ of an implosion hot-spot. It is then shown numerically that the analytical expression for the amplification of pVγ is simply related to yield amplification and to other more famous metrics used for inferring yield amplification in experiments. Interestingly, the argument of the pVγ boost equation appears to provide a fundamental ignition condition that implicitly includes the effects of asymmetry, and it also exposes the origin of why there is uncertainty in defining single ignition criteria. The resulting analysis of NIF implosion data indicates that an increase in burn-average hot-spot temperature will be needed in order to ignite, and the strategy being pursued to achieve this goal is outlined.

Published

2019

27. Three-dimensional modeling and hydrodynamic scaling of National Ignition Facility implosions

Author

D. H. Munro, Laurent Masse, Joseph Koning, Harry Robey, Jose Milovich, A. L. Kritcher, O. S. Jones, Christopher Schroeder, Mehul Patel, M. J. Edwards, Arthur Pak, M. M. Marinak, P. K. Patel, S. M. Sepke, C. R. Weber, Daniel Casey, Daniel S. Clark, Darwin Ho, and B. A. Hammel

Subjects

Physics, business.industry, Extrapolation, Implosion, Dimensional modeling, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Ignition system, Experience base, Physics::Plasma Physics, law, 0103 physical sciences, Aerospace engineering, 010306 general physics, National Ignition Facility, business, Scaling, Inertial confinement fusion

Abstract

The goal of an inertially confined, igniting plasma on the National Ignition Facility (NIF) [M. L. Spaeth, Fusion Sci. Technol. 69, 25 (2016)] remains elusive. However, there is a growing understanding of the factors that appear to be limiting current implosion performance. And with this understanding, the question naturally arises: What conditions will ultimately be required to achieve ignition, either by continuing to improve the quality of current implosions, or by hydrodynamically scaling those implosions to larger driver energies on some future facility? Given the complexity of NIF implosions, answering this question must rely heavily on sophisticated numerical simulations. In particular, those simulations must respect the three-dimensionality of real NIF implosions and also resolve the wide range of scales for the many perturbation sources that degrade them. This prospectus article reviews the current state of detailed modeling of NIF implosions, the scaling to ignition from recent experiments that that modeling implies, and areas for future improvements in modeling technique that could increase understanding and further enhance predictive capabilities. Given the uncertainties inherent in any extrapolation, particularly for a process as nonlinear as ignition, there will be no definitive answer on the requirements for ignition until it is actually demonstrated experimentally. However, with continuing improvements in modeling technique and a growing experience base from NIF, the requirements for ignition are becoming clearer.

Published

2019

28. Stimulated backscatter of laser light from BigFoot hohlraums on the National Ignition Facility

Author

Clement Goyon, J. Park, Jose Milovich, David Strozzi, Cliff Thomas, Thomas Chapman, Shahab Khan, M. A. Belyaev, A. B Langdon, Matthias Hohenberger, Nuno Lemos, Richard Berger, Kevin Baker, and Daniel Casey

Subjects

Physics, business.industry, Physics::Optics, Implosion, Condensed Matter Physics, Laser, law.invention, Ignition system, LASNEX, Optics, Physics::Plasma Physics, Hohlraum, law, Laser power scaling, National Ignition Facility, business, Inertial confinement fusion

Abstract

The high implosion velocity, high adiabat BigFoot design [Casey et al., Phys. Plasmas 25, 056308 (2018)] has produced the highest neutron yield to date in an ignition hohlraum on the National Ignition Facility. It has used up to 500 TW of peak power and nearly 2 MJ of laser energy in pulses up to 8 ns in duration, with the goal of fielding controlled implosions with high coupled energy, which can suppress deleterious hydrodynamic instabilities. However, when the laser pulse exceeds 6 ns with the laser energy greater than 1.6 MJ, stimulated Brillouin scattering (SBS) reaches levels that may damage optical components in the laser. Pending development of techniques to reduce SBS, limitation of laser power, and energy to avoid damage prevents the full exploitation of this approach to ignition. In this manuscript, we present three-dimensional simulations that match the experimentally measured SBS energy, in particular, reproducing quantitatively the time in the pulse when maximum backscatter occurs, and its magnitude across ∼10 BigFoot experiments. The demonstrated robustness of the modeling, which combines LASNEX and pF3D simulations, motivates us to explore and recommend several feasible SBS mitigation strategies: modified laser pointing, different laser frequencies for each cone of beams, increased laser bandwidth on all or some of the cones, and materials with a mixture of light and heavy atoms lining the inside of the hohlraum walls.

Published

2019

29. Laboratory astrophysical collisionless shock experiments on Omega and NIF

Author

Anatoly Spitkovsky, C.C. Kuranz, C. Plechaty, R. D. Petrasso, D. D. Ryutov, M. C. Levy, C. K. Li, Hideaki Takabe, Nathan Kugland, Dustin Froula, R. P. Drake, James Ross, Youichi Sakawa, Jena Meinecke, Gennady Fiksel, Taichi Morita, Channing Huntington, Daniel Casey, Gianluca Gregori, Frederico Fiuza, Hye-Sook Park, Bruce Remington, and Alex Zylstra

Subjects

Electromagnetic field, Physics, History, Magnetic energy, Thomson scattering, Implosion, Plasma, Electron, 01 natural sciences, Electromagnetic radiation, 010305 fluids & plasmas, Computer Science Applications, Education, Magnetic field, Physics::Plasma Physics, 0103 physical sciences, Atomic physics, 010306 general physics

Abstract

We are performing scaled astrophysics experiments on Omega and on NIF. Laser driven counter-streaming interpenetrating supersonic plasma flows can be studied to understand astrophysical electromagnetic plasma phenomena in a controlled laboratory setting. In our Omega experiments, the counter-streaming flow plasma state is measured using Thomson scattering diagnostics, demonstrating the plasma flows are indeed super-sonic and in the collisionless regime. We observe a surprising additional electron and ion heating from ion drag force in the double flow experiments that are attributed to the ion drag force and electrostatic instabilities. [1] A proton probe is used to image the electric and magnetic fields. We observe unexpected large, stable and reproducible electromagnetic field structures that arise in the counter-streaming flows [2]. The Biermann battery magnetic field generated near the target plane, advected along the flows, and recompressed near the midplane explains the cause of such self-organizing field structures [3]. A D3He implosion proton probe image showed very clear filamentary structures; three-dimensional Particle-In-Cell simulations and simulated proton radiography images indicate that these filamentary structures are generated by Weibel instabilities and that the magnetization level (ratio of magnetic energy over kinetic energy in the system) is ∼0.01 [4]. These findings have very high astrophysical relevance and significant implications. We expect to observe true collisionless shock formation when we use >100 kJ laser energy on NIF.

Published

2016

30. Review of hydro-instability experiments with alternate capsule supports in indirect-drive implosions on the National Ignition Facility

Author

Daniel S. Clark, Harry Robey, Andrew MacPhee, S. C. Johnson, K. C. Chen, V. A. Smalyuk, Jose Milovich, C. L. Alday, J. E. Field, J. Crippen, S. Diaz, Otto Landen, D. Steich, David Martinez, Peter Amendt, Louisa Pickworth, M. Havre, J. P. Cortez, Michael Farrell, C. R. Weber, Daniel Casey, J. Jaquez, X. Lepro-Chavez, S. W. Haan, C. Heinbockel, A. Nikroo, Sergei O. Kucheyev, Michael Stadermann, W. W. Hsing, B. A. Hammel, A. V. Hamza, Chantel Aracne-Ruddle, K. Kangas, Neal Rice, T. Bunn, J. R. Bigelow, S. Felker, and Jeremy Kroll

Subjects

Physics, Cantilever, Implosion, Mechanics, Condensed Matter Physics, 01 natural sciences, Instability, Rod, 010305 fluids & plasmas, 0103 physical sciences, 010306 general physics, National Ignition Facility, Contact area, Inertial confinement fusion, Magnetic levitation

Abstract

Hydrodynamic instability growth of capsule support membranes (or “tents”) has been recognized as one of the major contributors to the performance degradation in high-compression plastic capsule implosions at the National Ignition Facility (NIF) [E. M. Campbell et al., AIP Conf. Proc. 429, 3 (1998)]. The capsules were supported by tents because the nominal 10-μm diameter fill tubes were not strong enough to support capsules by themselves in indirect-drive implosions on NIF. After it was recognized that the tents had a significant impact of implosion's stability, new alternative support methods were investigated. While some of these methods completely eliminated tent, other concepts still used tents, but concentrated on mitigating their impact. The tent-less methods included “fishing pole” reinforced fill tubes, cantilevered fill tubes, and thin-wire “tetra cage” supports. In the “fishing pole” concept, a 10-μm fill tube was inserted inside 30-μm fill tube for extra support with the connection point located 300 μm away from the capsule surface. The cantilevered fill tubes were supported by 12-μm thick SiC rods, offset by up to 300 μm from the capsule surfaces. In the “tetra-cage” concept, 2.5-μm thick wires (carbon nanotube yarns) were used to support a capsule. Other concepts used “polar tents” and a “foam-shell” to mitigate the effects of the tents. The “polar tents” had significantly reduced contact area between the tents and the capsule compared to the nominal tents. In the “foam-shell” concept, a 200-μm thick, 30 mg/cc SiO2 foam layer was used to offset the tents away from the capsule surface in an attempt to mitigate their effects. These concepts were investigated in x-ray radiography experiments and compared with perturbations from standard tent support. The measured perturbations in the “fishing pole,” cantilevered fill tube, and “tetra-cage” concepts compared favorably with (were smaller than) nominal tent perturbations and were recommended for further testing for feasibility in layered DT implosions. The “polar tents” were tested in layered DT implosions with a relatively-stable “high-foot” drive showing an improvement in neutron yield in one experiment compared to companion implosions with nominal tents. This article reviews and summarizes recent experiments on these alternate capsule support concepts. In addition, the concept of magnetic levitation is also discussed.

Published

2018

31. Exploring the limits of case-to-capsule ratio, pulse length, and picket energy for symmetric hohlraum drive on the National Ignition Facility Laser

Author

E. L. Dewald, Debra Callahan, Kevin Baker, Laurent Divol, A. L. Kritcher, Denise Hinkel, Cliff Thomas, Omar Hurricane, Alex Zylstra, Tammy Ma, Steve MacLaren, Nathan Meezan, Tilo Döppner, Sabrina Nagel, Thomas Chapman, N. Izumi, Jay D. Salmonson, Matthias Hohenberger, Eric Loomis, L. F. Berzak Hopkins, Laura Robin Benedetti, Joseph Ralph, Otto Landen, Shahab Khan, Steven H. Batha, Leonard Jarrott, Laurent Masse, Daniel Casey, C. Czajka, Sebastien LePape, John Kline, Derek Mariscal, S. A. Yi, D. T. Woods, Arthur Pak, and George A. Kyrala

Subjects

Physics, business.industry, media_common.quotation_subject, Implosion, Radius, Condensed Matter Physics, Laser, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, law.invention, Ignition system, Optics, Physics::Plasma Physics, Hohlraum, law, 0103 physical sciences, 010306 general physics, National Ignition Facility, business, Inertial confinement fusion, media_common

Abstract

We present a data-based model for low mode asymmetry in low gas-fill hohlraum experiments on the National Ignition Facility {NIF [Moses et al., Fusion Sci. Technol. 69, 1 (2016)]} laser. This model is based on the hypothesis that the asymmetry in these low fill hohlraums is dominated by the hydrodynamics of the expanding, low density, high-Z (gold or uranium) “bubble,” which occurs where the intense outer cone laser beams hit the high-Z hohlraum wall. We developed a simple model which states that the implosion symmetry becomes more oblate as the high-Z bubble size becomes large compared to the hohlraum radius or the capsule size becomes large compared to the hohlraum radius. This simple model captures the trends that we see in data that span much of the parameter space of interest for NIF ignition experiments. We are now using this model as a constraint on new designs for experiments on the NIF.

Published

2018

32. Demonstration of High Performance in Layered Deuterium-Tritium Capsule Implosions in Uranium Hohlraums at the National Ignition Facility

Author

Denise Hinkel, S. Le Pape, H. Streckert, Hans W. Herrmann, David N. Fittinghoff, D. K. Bradley, Robert Hatarik, Klaus Widmann, P. T. Springer, George A. Kyrala, Harry Robey, D. A. Callahan, Daniel Sayre, C. B. Yeamans, M. Havre, E. L. Dewald, Alan S. Wan, T. Ma, S. W. Haan, Joseph Ralph, Otto Landen, Peter M. Celliers, R. Tommasini, Gary Grim, Petr Volegov, P. K. Patel, Michael Schneider, Nobuhiko Izumi, Jay D. Salmonson, Alastair Moore, J. A. Caggiano, Bruce Remington, E. J. Bond, Abbas Nikroo, Johan Frenje, H.-S. Park, Omar Hurricane, Andrea Kritcher, Carl Wilde, Frank E. Merrill, Daniel Casey, M. J. Edwards, Tilo Döppner, Art Pak, J. P. Knauer, T. R. Dittrich, L. F. Berzak Hopkins, D. H. Edgell, John Kline, Andrew MacPhee, J. A. Church, David Turnbull, M. Gatu Johnson, John Moody, S. N. Dixit, Laura Robin Benedetti, Richard Town, and Shahab Khan

Subjects

Materials science, Nuclear engineering, General Physics and Astronomy, Implosion, chemistry.chemical_element, Nova (laser), Fusion power, Uranium, law.invention, Nuclear physics, Ignition system, chemistry, Hohlraum, law, Depleted uranium, National Ignition Facility

Abstract

We report on the first layered deuterium-tritium (DT) capsule implosions indirectly driven by a "high-foot" laser pulse that were fielded in depleted uranium hohlraums at the National Ignition Facility. Recently, high-foot implosions have demonstrated improved resistance to ablation-front Rayleigh-Taylor instability induced mixing of ablator material into the DT hot spot [Hurricane et al., Nature (London) 506, 343 (2014)]. Uranium hohlraums provide a higher albedo and thus an increased drive equivalent to an additional 25 TW laser power at the peak of the drive compared to standard gold hohlraums leading to higher implosion velocity. Additionally, we observe an improved hot-spot shape closer to round which indicates enhanced drive from the waist. In contrast to findings in the National Ignition Campaign, now all of our highest performing experiments have been done in uranium hohlraums and achieved total yields approaching 10^{16} neutrons where more than 50% of the yield was due to additional heating of alpha particles stopping in the DT fuel.

Published

2015

33. Improved Performance of High Areal Density Indirect Drive Implosions at the National Ignition Facility using a Four-Shock Adiabat Shaped Drive

Author

Petr Volegov, C. J. Cerjan, Benjamin Bachmann, Daniel S. Clark, Debra Callahan, Johan Frenje, Tammy Ma, D. Hoover, C. B. Yeamans, Sabrina Nagel, H.-S. Park, S. W. Haan, Brian Spears, Frank E. Merrill, Kevin Baker, N. Izumi, K. N. LaFortune, Otto Landen, C. C. Widmayer, Abbas Nikroo, M. J. Edwards, Robert Hatarik, Tilo Döppner, Harry Robey, P. K. Patel, C. R. Weber, Daniel Casey, Laura Robin Benedetti, V. A. Smalyuk, Arthur Pak, Andrew MacPhee, Jose Milovich, E. J. Bond, D. N. Fittinghoff, S. Khan, M. Gatu Johnson, J. L. Peterson, Daniel Sayre, B. J. MacGowan, and Gary Grim

Subjects

Ignition system, Improved performance, Materials science, law, Nuclear engineering, General Physics and Astronomy, Implosion, Area density, National Ignition Facility, Instability, Shock (mechanics), law.invention

Abstract

Hydrodynamic instabilities can cause capsule defects and other perturbations to grow and degrade implosion performance in ignition experiments at the National Ignition Facility (NIF). Here, we show the first experimental demonstration that a strong unsupported first shock in indirect drive implosions at the NIF reduces ablation front instability growth leading to a 3 to 10 times higher yield with fuel ρR>1 g/cm(2). This work shows the importance of ablation front instability growth during the National Ignition Campaign and may provide a path to improved performance at the high compression necessary for ignition.

Published

2015

34. Getting Beyond Unity Fusion Fuel Gain in an Inertially Confined Fusion Implosion

Author

J. D. Moody, S. N. Dixit, D. Edgell, John Kline, Laurent Divol, N. Meezan, S. Ross, Darwin Ho, Daniel Casey, Gary Grim, E. L. Dewald, J. P. Knauer, A. L. Kritcher, J. A. Caggiano, Bruce Remington, O. S. Jones, S. W. Haan, P. T. Springer, Tammy Ma, Andrew MacPhee, J.-P. Leidinger, Arthur Pak, Joseph Ralph, Brian Spears, E. J. Bond, Otto Landen, A. J. Mackinnon, George A. Kyrala, Harry Robey, Daniel S. Clark, Debra Callahan, T. R. Dittrich, Laura Robin Benedetti, Michael Schneider, Abbas Nikroo, H-S Park, Frank E. Merrill, Richard Town, Sabrina Nagel, M. A. Barrios Garcia, W. W. Hsing, Carl Wilde, A. S. Moore, Maria Gatu-Johnson, M. J. Edwards, Larry L. Peterson, Petr Volegov, L. F. Berzak Hopkins, S. Le Pape, D. Hoover, Denise Hinkel, Cliff Thomas, R. Rygg, Shabbir A. Khan, David N. Fittinghoff, Peter Amendt, D. K. Bradley, Matthias Hohenberger, Jay D. Salmonson, A. V. Hamza, Tilo Doeppner, R. Tommasini, Johan Frenje, Omar Hurricane, Pierre Michel, V. A. Smalyuk, P. K. Patel, Jose Milovich, Klaus Widmann, R. Haterik, and N. Izumi

Subjects

Ignition system, Fusion, law, Nuclear engineering, Environmental science, Implosion, Nova (laser), Plasma, Fusion power, National Ignition Facility, Inertial confinement fusion, law.invention

Abstract

In this talk, we will discuss the progress towards ignition on the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory (LLNL) in Northern California. We will cover the some of the setbacks encountered during the progress of the research at NIF, but also cover the great advances that have been made including the achievements of greater than unity fusion ‘fuel gain’ and alpha-heating dominated fusion plasmas. The research strategy for the future will also be discussed.

Published

2015

35. Hydro-instability growth of perturbation seeds from alternate capsule-support strategies in indirect-drive implosions on National Ignition Facility

Author

C. R. Weber, Daniel Casey, J. Crippen, V. A. Smalyuk, Jose Milovich, Otto Landen, J. E. Field, Harry Robey, Michael Farrell, A. V. Hamza, Louisa Pickworth, K. C. Chen, S. Felker, Daniel S. Clark, A. Nikroo, Andrew MacPhee, Jeremy Kroll, Neal Rice, Michael Stadermann, S. W. Haan, W. W. Hsing, David Martinez, and B. A. Hammel

Subjects

Physics, Glow discharge, Capsule, Perturbation (astronomy), Implosion, Mechanics, Condensed Matter Physics, 01 natural sciences, Instability, 010305 fluids & plasmas, 0103 physical sciences, Plasma diagnostics, 010306 general physics, National Ignition Facility, Inertial confinement fusion

Abstract

Hydrodynamic instability growth of the capsule support membranes (or “tents”) and fill tubes has been studied in spherical, glow discharge polymer plastic capsule implosions at the National Ignition Facility (NIF) [Campbell et al., AIP Conf. Proc. 429, 3 (1998)]. In NIF implosions, the capsules are supported by tents because the nominal 10-μm thick fill tubes are not strong enough to support capsules by themselves. After it was recognized that the tents had a significant impact of implosion stability, new support methods were investigated, including thicker, 30-μm diameter fill tubes and cantilevered fill tubes, as described in this article. A new “sub-scale” version of the existing x-ray radiography platform was developed for measuring growing capsule perturbations in the acceleration phase of implosions. It was calibrated using hydrodynamic growth measurements of pre-imposed capsule modulations with Legendre modes of 60, 90, 110, and 140 at convergence ratios up to ∼2.4. Subsequent experiments with 3-D ...

Published

2017

36. On the importance of minimizing 'coast-time' in x-ray driven inertially confined fusion implosions

Author

Klaus Widmann, Jay D. Salmonson, H.-S. Park, Omar Hurricane, E. L. Dewald, A. L. Kritcher, Denise Hinkel, A. S. Moore, S. Le Pape, Joseph Ralph, Tammy Ma, Otto Landen, Andrew MacPhee, Debra Callahan, Tilo Döppner, P. K. Patel, P. T. Springer, John Kline, Arthur Pak, Daniel Casey, T. R. Dittrich, and L. F. Berzak Hopkins

Subjects

Physics, Fusion, business.industry, X-ray, Implosion, Condensed Matter Physics, Laser, 01 natural sciences, 010305 fluids & plasmas, Computational physics, law.invention, Optics, law, 0103 physical sciences, Laser power scaling, 010306 general physics, business, Stagnation pressure, Inertial confinement fusion

Abstract

By the time an inertially confined fusion (ICF) implosion has converged a factor of 20, its surface area has shrunk 400 × , making it an inefficient x-ray energy absorber. So, ICF implosions are traditionally designed to have the laser drive shut off at a time, toff, well before bang-time, tBT, for a coast-time of t coast = t B T − t o f f > 1 ns. High-foot implosions on NIF showed a strong dependence of many key ICF performance quantities on reduced coast-time (by extending the duration of laser power after the peak power is first reached), most notably stagnation pressure and fusion yield. Herein we show that the ablation pressure, pabl, which drives high-foot implosions, is essentially triangular in temporal shape, and that reducing tcoast boosts pabl by as much as ∼ 2 × prior to stagnation thus increasing fuel and hot-spot compression and implosion speed. One-dimensional simulations are used to track hydrodynamic characteristics for implosions with various coast-times and various assumed rates of hohl...

Published

2017

37. On krypton-doped capsule implosion experiments at the National Ignition Facility

Author

Brian Spears, P. K. Patel, M. A. Barrios, Marilyn Schneider, Tammy Ma, Otto Landen, Hui Chen, Leonard Jarrott, Ryan Nora, Michael Rosenberg, B. A. Hammel, Howard A. Scott, Daniel Casey, and L. F. Berzak Hopkins

Subjects

Physics, Opacity, Krypton, chemistry.chemical_element, Implosion, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, chemistry, Hohlraum, 0103 physical sciences, Plasma diagnostics, Atomic physics, 010306 general physics, Spectroscopy, National Ignition Facility, Inertial confinement fusion

Abstract

This paper presents the spectroscopic aspects of using Krypton as a dopant in NIF capsule implosions through simulation studies and the first set of NIF experiments. Using a combination of 2D hohlraum and 1D capsule simulations with comprehensive spectroscopic modeling, the calculations focused on the effect of dopant concentration on the implosion, and the impact of gradients in the electron density and temperature to the Kr line features and plasma opacity. Experimental data were obtained from three NIF Kr-dopant experiments, performed with varying Kr dopant concentrations between 0.01% and 0.03%. The implosion performance, hotspot images, and detailed Kr spectral analysis are summarized relative to the predictions. Data show that fuel-dopant spectroscopy can serve as a powerful and viable diagnostic for inertial confinement fusion implosions.

Published

2017

38. Symmetry control of an indirectly driven high-density-carbon implosion at high convergence and high velocity

Author

Nobuhiko Izumi, Andrew MacPhee, H. Huang, L. F. Berzak Hopkins, James Ross, Clement Goyon, J. E. Field, Daniel Sayre, David Turnbull, C. Kong, C. R. Weber, Daniel Casey, William S. Cassata, Peter M. Celliers, Omar Hurricane, Pierre Michel, David Strozzi, W. W. Hsing, A. J. Mackinnon, Otto Landen, Michael Stadermann, J. Crippen, Darwin Ho, S. Le Pape, J. R. Rygg, Laurent Divol, M. J. Edwards, Tilo Döppner, Art Pak, Juergen Biener, S. W. Haan, B. J. MacGowan, B. J. Kozioziemski, David N. Fittinghoff, S. R. Nagel, C. B. Yeamans, Matthias Hohenberger, Benjamin Bachmann, Nathan Meezan, Marius Millot, Neal Rice, A. Nikroo, J. D. Moody, Laura Robin Benedetti, Richard Town, Shahab Khan, C. Choate, Petr Volegov, D. H. Edgell, George A. Kyrala, D. A. Callahan, T. Ma, Suhas Bhandarkar, N. Gharibyan, Robert Hatarik, and E. L. Dewald

Subjects

Physics, media_common.quotation_subject, Implosion, Condensed Matter Physics, 01 natural sciences, Asymmetry, Symmetry (physics), 010305 fluids & plasmas, Computational physics, law.invention, Ignition system, Acceleration, law, Hohlraum, 0103 physical sciences, Plasma diagnostics, Atomic physics, 010306 general physics, National Ignition Facility, media_common

Abstract

We report on the most recent and successful effort at controlling the trajectory and symmetry of a high density carbon implosion at the National Ignition Facility. We use a low gasfill (0.3 mg/cc He) bare depleted uranium hohlraum with around 1 MJ of laser energy to drive a 3-shock-ignition relevant implosion. We assess drive performance and we demonstrate symmetry control at convergence 1, 3–5, 12, and 27 to better than ±5 μm using a succession of experimental platforms. The symmetry control was maintained at a peak fuel velocity of 380 km/s. Overall, implosion symmetry measurements are consistent with the pole-equator symmetry of the X-ray drive on the capsule being better than 5% in the foot of the drive (when shocks are launched) and better than 1% during peak drive (main acceleration phase). This level of residual asymmetry should have little impact on implosion performance.

Published

2017

39. Examining the radiation drive asymmetries present in the high foot series of implosion experiments at the National Ignition Facility

Author

E. L. Dewald, Marius Millot, P. K. Patel, Laurent Divol, George A. Kyrala, Joseph Ralph, Otto Landen, J. D. Moody, Peter M. Celliers, H.-S. Park, Omar Hurricane, Sebastien LePape, Nathan Meezan, Dayne Fratanduono, Harry Robey, L. F. Berzak Hopkins, J. R. Rygg, N. Izumi, J. E. Field, M. J. Edwards, Tilo Döppner, Denise Hinkel, Benjamin Bachmann, Debra Callahan, Daniel Casey, Sabrina Nagel, D. K. Bradley, Arthur Pak, Laura Robin Benedetti, A. L. Kritcher, Richard Town, Shahab Khan, Alastair Moore, Tammy Ma, Jose Milovich, Marilyn Schneider, and W. W. Hsing

Subjects

Physics, Astrophysics::High Energy Astrophysical Phenomena, media_common.quotation_subject, Flux, Implosion, Mechanics, Condensed Matter Physics, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, Shock (mechanics), Nuclear physics, Amplitude, Hohlraum, 0103 physical sciences, 010306 general physics, Stagnation pressure, National Ignition Facility, media_common

Abstract

This paper details and examines the origins of radiation drive asymmetries present during the initial High Foot implosion experiments. Such asymmetries are expected to reduce the stagnation pressure and the resulting yield of these experiments by several times. Analysis of reemission and dual axis shock timing experiments indicates that a flux asymmetry, with a P2/P0 amplitude that varies from −10% to −5%, is present during the first shock of the implosion. This first shock asymmetry can be corrected through adjustments to the laser cone fraction. A thin shell model and more detailed radiation hydrodynamic calculations indicate that an additional negative P2/P0 asymmetry during the second or portions of the third shock is required to reach the observed amount of asymmetry in the shape of the ablator at peak implosion velocity. In conjunction with symmetry data from the x-ray self emission produced at stagnation, these models also indicate that after the initially negative P2/P0 flux asymmetry, the capsule...

Published

2017

40. Improving ICF implosion performance with alternative capsule supports

Author

Andrew MacPhee, J. Crippen, V. A. Smalyuk, Jose Milovich, Peter Amendt, S. M. Sepke, M. Mcinnis, C. Choate, A. Nikroo, J. E. Field, Michael Stadermann, C. R. Weber, Daniel Casey, B. A. Hammel, David Martinez, B. Chang, S. W. Haan, Harry Robey, M. M. Marinak, S. A. Johnson, Daniel S. Clark, Otto Landen, Neal Rice, S. Felker, Suhas Bhandarkar, and Jeremy Kroll

Subjects

Physics, business.industry, Capsule, Implosion, 3d model, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Optics, Hohlraum, 0103 physical sciences, 010306 general physics, Thin membrane, business, National Ignition Facility, Inertial confinement fusion

Abstract

The thin membrane that holds the capsule in-place in the hohlraum is recognized as one of the most significant contributors to reduced performance in indirect drive inertial confinement fusion (ICF) experiments on the National Ignition Facility. This membrane, known as the “tent,” seeds a perturbation that is amplified by Rayleigh-Taylor and can rupture the capsule. A less damaging capsule support mechanism is under development. Possible alternatives include the micron-scale rods spanning the hohlraum width and supporting either the capsule or stiffening the fill-tube, a larger fill-tube to both fill and support the capsule, or a low-density foam layer that protects the capsule from the tent impact. Experiments are testing these support features to measure their imprint on the capsule. These experiments are revealing unexpected aspects about perturbation development in indirect drive ICF, such as the importance of shadows coming from bright spots in the hohlraum. Two dimensional and 3D models are used to ...

Published

2017

41. Observation of a Reflected Shock in an Indirectly Driven Spherical Implosion at the National Ignition Facility

Author

L. F. Berzak Hopkins, A. J. Mackinnon, Laurent Divol, Hans W. Herrmann, Klaus Widmann, Michael Rosenberg, Alex Zylstra, Hans Rinderknecht, Nathan Meezan, R. D. Petrasso, S. Le Pape, Maria Gatu-Johnson, J. D. Kilkenny, Johan Frenje, Tammy Ma, G. Grimm, James McNaney, Daniel Casey, J. P. Knauer, and Arthur Pak

Subjects

Physics, Opacity, Astrophysics::High Energy Astrophysical Phenomena, General Physics and Astronomy, Implosion, Radius, Thermal conduction, Computational physics, Shock (mechanics), Heat flux, Physics::Plasma Physics, Hohlraum, Atomic physics, National Ignition Facility

Abstract

A 200 μm radius hot spot at more than 2 keV temperature, 1 g/cm^{3} density has been achieved on the National Ignition Facility using a near vacuum hohlraum. The implosion exhibits ideal one-dimensional behavior and 99% laser-to-hohlraum coupling. The low opacity of the remaining shell at bang time allows for a measurement of the x-ray emission of the reflected central shock in a deuterium plasma. Comparison with 1D hydrodynamic simulations puts constraints on electron-ion collisions and heat conduction. Results are consistent with classical (Spitzer-Harm) heat flux.

Published

2014

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

Author

H.-S. Park, Omar Hurricane, Daniel Casey, E. L. Dewald, L. F. Berzak Hopkins, John Kline, D. A. Callahan, Bruce Remington, T. Ma, D. E. Hinkel, Tilo Döppner, T. R. Dittrich, S. Le Pape, Jay D. Salmonson, P. K. Patel, and Harry Robey

Subjects

Physics, Hohlraum, General Physics and Astronomy, Implosion, Neutron, Nova (laser), Atomic physics, National Ignition Facility, Inertial confinement fusion, Energy (signal processing), Ion

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 $\ensuremath{\sim}300\text{ }\text{ }\mathrm{eV}$. The resulting experimental neutron yield was $(2.4\ifmmode\pm\else\textpm\fi{}0.05)\ifmmode\times\else\texttimes\fi{}{10}^{15}$ DT, the fuel $\ensuremath{\rho}R$ was $(0.86\ifmmode\pm\else\textpm\fi{}0.063)\text{ }\text{ }\mathrm{g}/{\mathrm{cm}}^{2}$, and the measured ${T}_{\text{ion}}$ was $(4.2\ifmmode\pm\else\textpm\fi{}0.16)\text{ }\text{ }\mathrm{keV}$, corresponding to 8 kJ of fusion yield, with $\ensuremath{\sim}1/3$ of the yield caused by self-heating of the fuel by $\ensuremath{\alpha}$ particles emitted in the initial reactions. The generalized Lawson criteria, an ignition metric, was 0.43 and the neutron yield was $\ensuremath{\sim}70%$ of the value predicted by simulations that include \ensuremath{\alpha}-particle self-heating.

Published

2014

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

Author

J. L. Peterson, N. Gharibyan, R. Tommasini, Tammy Ma, Alastair Moore, E. P. Hartouni, K. C. Chen, Joseph Ralph, Jeremy Kroll, Otto Landen, A. V. Hamza, Mark Eckart, Laura Robin Benedetti, A. Nikroo, David Turnbull, Shahab Khan, M. J. Edwards, Tilo Döppner, S. N. Dixit, R. M. Bionta, D. A. Shaughnessy, George A. Kyrala, N. Izumi, Kevin Baker, Gary Grim, Robert Hatarik, P. K. Patel, A. L. Velikovich, Frank E. Merrill, Harry Robey, C. R. Weber, Johan Frenje, V. A. Smalyuk, Daniel Casey, Jose Milovich, C. J. Cerjan, Omar Hurricane, Daniel S. Clark, Debra Callahan, Daniel Sayre, C. C. Widmayer, Benjamin Bachmann, J. P. Knauer, Michael Farrell, B. J. MacGowan, M. Mauldin, Arthur Pak, L. F. Berzak Hopkins, O. S. Jones, Peter M. Celliers, D. Hoover, Sabrina Nagel, Clement Goyon, Kenneth S. Jancaitis, E. J. Bond, Maria Gatu-Johnson, C. B. Yeamans, M. Havre, Petr Volegov, Matthias Hohenberger, Brian Spears, K. N. LaFortune, S. W. Haan, David N. Fittinghoff, D. K. Bradley, and Andrew MacPhee

Subjects

Physics, Yield (engineering), Implosion, Radiation, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Nuclear physics, Ignition system, Deuterium, law, 0103 physical sciences, Area density, 010306 general physics, National Ignition Facility, Scaling

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. Doppner 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.

Published

2016

44. A novel method to recover DD fusion proton CR-39 data corrupted by fast ablator ions at OMEGA and the National Ignition Facility

Author

R. M. Bionta, David Turnbull, Michael Rosenberg, James Ross, R. D. Petrasso, D. Orozco, V. Yu. Glebov, Alex Zylstra, Graeme Sutcliffe, Johan Frenje, L. M. Milanese, C. K. Li, M. Gatu Johnson, H.-S. Park, J. R. Rygg, Brandon Lahmann, Hong Sio, Fredrick Seguin, Channing Huntington, and Daniel Casey

Subjects

010302 applied physics, Physics, Range (particle radiation), business.industry, Ion track, Detector, Implosion, Plasma, 01 natural sciences, Signal, 010305 fluids & plasmas, Nuclear physics, Optics, 0103 physical sciences, business, National Ignition Facility, Instrumentation, Inertial confinement fusion

Abstract

CR-39 detectors are used routinely in inertial confinement fusion (ICF) experiments as a part of nuclear diagnostics. CR-39 is filtered to stop fast ablator ions which have been accelerated from an ICF implosion due to electric fields caused by laser-plasma interactions. In some experiments, the filtering is insufficient to block these ions and the fusion-product signal tracks are lost in the large background of accelerated ion tracks. A technique for recovering signal in these scenarios has been developed, tested, and implemented successfully. The technique involves removing material from the surface of the CR-39 to a depth beyond the endpoint of the ablator ion tracks. The technique preserves signal magnitude (yield) as well as structure in radiograph images. The technique is effective when signal particle range is at least 10 μm deeper than the necessary bulk material removal.

Published

2016

45. Spatially resolved X-ray emission measurements of the residual velocity during the stagnation phase of inertial confinement fusion implosion experiments

Author

Debra Callahan, J. P. Knauer, Sabrina Nagel, A. L. Kritcher, J. D. Moody, Laura Robin Benedetti, Shahab Khan, Denise Hinkel, Tammy Ma, Arthur Pak, Gary Grim, H.-S. Park, Omar Hurricane, Daniel Sayre, W. W. Hsing, D. C. Eder, Jay D. Salmonson, M. J. Edwards, J. J. Ruby, Tilo Döppner, J. E. Field, Robert Hatarik, Daniel Casey, J. D. Kilkenny, N. Izumi, L. F. Berzak Hopkins, David N. Fittinghoff, D. K. Bradley, Frank E. Merrill, Brian Spears, and P. K. Patel

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Phase (waves), Implosion, Condensed Matter Physics, Residual, 01 natural sciences, Electromagnetic radiation, Displacement (vector), 010305 fluids & plasmas, Computational physics, Radiation flux, Optics, 0103 physical sciences, Plasma diagnostics, 010306 general physics, business, Inertial confinement fusion

Abstract

A technique for measuring residual motion during the stagnation phase of an indirectly driven inertial confinement experiment has been implemented. This method infers a velocity from spatially and temporally resolved images of the X-ray emission from two orthogonal lines of sight. This work investigates the accuracy of recovering spatially resolved velocities from the X-ray emission data. A detailed analytical and numerical modeling of the X-ray emission measurement shows that the accuracy of this method increases as the displacement that results from a residual velocity increase. For the typical experimental configuration, signal-to-noise ratios, and duration of X-ray emission, it is estimated that the fractional error in the inferred velocity rises above 50% as the velocity of emission falls below 24 μm/ns. By inputting measured parameters into this model, error estimates of the residual velocity as inferred from the X-ray emission measurements are now able to be generated for experimental data. Details...

Published

2016

46. Performance of indirectly driven capsule implosions on NIF using adiabat-shaping

Author

Andrew MacPhee, O. S. Jones, Peter M. Celliers, E. J. Bond, S. W. Haan, L. J. Perkins, Daniel Sayre, A. V. Hamza, Brian Spears, C. J. Cerjan, V. A. Smalyuk, Jose Milovich, M. Gatu Johnson, Arthur Pak, M. M. Marinak, P. K. Patel, C. R. Weber, Daniel Casey, C. C. Widmayer, K. N. LaFortune, B. Bachmann, B. A. Hammel, Omar Hurricane, J. A. Caggiano, Mehali Patel, L. F. Berzak Hopkins, Tammy Ma, D. Hoover, Otto Landen, S. M. Sepke, R. Tommasini, E. M. Giraldez, Daniel S. Clark, Debra Callahan, A. Nikroo, S. N. Dixit, M. J. Edwards, Tilo Döppner, C. B. Yeamans, Matthias Hohenberger, Kenneth S. Jancaitis, B. J. MacGowan, Jeremy Kroll, Kevin Baker, Harry Robey, Robert Hatarik, J. L. Peterson, N. Gharibyan, and G.D. Kerbel

Subjects

History, Yield (engineering), Materials science, Nuclear engineering, Implosion, Laser, Compression (physics), Instability, Computer Science Applications, Education, law.invention, Neutron yield, law, National Ignition Facility, Picketing, Simulation

Abstract

A series of indirectly driven capsule implosions has been performed on the National Ignition Facility to assess the relative contributions of ablation-front instability growth vs. fuel compression on implosion performance. Laser pulse shapes for both low and high-foot pulses were modified to vary ablation-front growth & fuel adiabat, separately and controllably. Two principal conclusions are drawn from this study: 1) It is shown that an increase in laser picket energy reduces ablation-front instability growth in low-foot implosions resulting in a substantial (3-10X) increase in neutron yield with no loss of fuel compression. 2.) It is shown that a decrease in laser trough power reduces the fuel adiabat in high-foot implosions results in a significant (36%) increase in fuel compression together with no reduction in neutron yield. These results taken collectively bridge the space between the higher compression low-foot results and the higher yield high-foot results.

Published

2016

47. Hydrodynamic instability measurements in DT-layered ICF capsules using the layered-HGR platform

Author

V. A. Smalyuk, T. Bunn, A. Nikroo, C. R. Weber, Daniel Casey, L. Carlson, B. J. Kozioziemski, Harry Robey, Tilo Döppner, J. D. Sater, Andrew MacPhee, and Rebecca Dylla-Spears

Subjects

History, Materials science, Deuterium, Analytical chemistry, Implosion, Mechanics, National Ignition Facility, Instability, Computer Science Applications, Education

Abstract

The first measurements of hydrodynamic instability growth at the fuel-ablator interface in an ICF implosion are reported. Previous instability measurements on the National Ignition Facility have used plastic capsules to measure ablation front Rayleigh-Taylor growth with the Hydro.-Growth Radiography (HGR) platform. These capsules substituted an additional thickness of plastic ablator material in place of the cryogenic layer of Deuterium- Tritium (DT) fuel. The present experiments are the first to include a DT ice layer, which enables measurements of the instability growth occurring at the fuel-ablator interface. Instability growth at the fuel-ablator interface is seeded differently in two independent NIF experiments. In the first case, a perturbation on the outside of the capsule feeds through and grows on the interface. Comparisons to an implosion without a fuel layer produce a measure of the fuel's modulation. In the second case, a modulation was directly machined on the inner ablator before the fuel layer was added. The measurement of growth in these two scenarios are compared to 2D rad-hydro modeling.

Published

2016

48. Simulations of fill tube effects on the implosion of high-foot NIF ignition capsules

Author

Tilo Doeppner, B. A. Hammel, David C. Clark, Debra Callahan, E. L. Dewald, George B. Zimmerman, A. L. Kritcher, P. T. Springer, Tammy Ma, Bruce Remington, L. Berzak-Hopkins, H.-S. Park, Omar Hurricane, John Kline, Denise Hinkel, B. J. Kozioziemski, T. G. Parham, T. R. Dittrich, C. R. Weber, S. W. Haan, Daniel Casey, J. A. Harte, Jay D. Salmonson, A. Nikroo, P. K. Patel, and Arthur Pak

Subjects

History, Materials science, business.industry, Mechanical engineering, Implosion, engineering.material, 01 natural sciences, 010305 fluids & plasmas, Computer Science Applications, Education, law.invention, Ignition system, Optics, Coating, law, 0103 physical sciences, engineering, Laser power scaling, 010306 general physics, business, Glass tube

Abstract

Encouraging results have been obtained using a strong first shock during the implosion of carbon-based ablator ignition capsules. These "high-foot" implosion results show that capsule performance deviates from 1D expectations as laser power and energy are increased. A possible cause of this deviation is the disruption of the hot spot by jets originating in the capsule fill tube. Nominally, a 10 μm outside diameter glass (SiO2) fill tube is used in these implosions. Simulations indicate that a thin coating of Au on this glass tube may lessen the hotspot disruption. These results and other mitigation strategies will be presented.

Published

2016

49. Performance of indirectly driven capsule implosions on the National Ignition Facility using adiabat-shaping

Author

M. J. Edwards, Tilo Döppner, O. S. Jones, Omar Hurricane, B. A. Hammel, Peter M. Celliers, C. J. Cerjan, Daniel S. Clark, Debra Callahan, S. M. Sepke, Brian Spears, E. J. Bond, Tammy Ma, Jeremy Kroll, C. B. Yeamans, Matthias Hohenberger, C. R. Weber, Daniel Casey, M. Gatu Johnson, K. N. LaFortune, C. C. Widmayer, Otto Landen, B. J. MacGowan, J. A. Caggiano, Daniel Sayre, Kenneth S. Jancaitis, S. W. Haan, V. A. Smalyuk, Benjamin Bachmann, Jose Milovich, Mehul Patel, G.D. Kerbel, Kevin Baker, A. Nikroo, Arthur Pak, Robert Hatarik, Harry Robey, J. L. Peterson, L. F. Berzak Hopkins, D. Hoover, N. Gharibyan, M. M. Marinak, P. K. Patel, A. V. Hamza, E. M. Giraldez, S. N. Dixit, Andrew MacPhee, R. Tommasini, and L. J. Perkins

Subjects

Physics, Nuclear engineering, Implosion, Condensed Matter Physics, Laser, 01 natural sciences, Instability, 010305 fluids & plasmas, law.invention, Neutron yield, law, 0103 physical sciences, Neutron, Laser power scaling, 010306 general physics, National Ignition Facility, Inertial confinement fusion

Abstract

A series of indirectly driven capsule implosions has been performed on the National Ignition Facility to assess the relative contributions of ablation-front instability growth vs. fuel compression on implosion performance. Laser pulse shapes for both low and high-foot pulses were modified to vary ablation-front growth and fuel adiabat, separately and controllably. Three principal conclusions are drawn from this study: (1) It is shown that reducing ablation-front instability growth in low-foot implosions results in a substantial (3-10X) increase in neutron yield with no loss of fuel compression. (2) It is shown that reducing the fuel adiabat in high-foot implosions results in a significant (36%) increase in fuel compression together with a small (10%) increase in neutron yield. (3) Increased electron preheat at higher laser power in high-foot implosions, however, appears to offset the gain in compression achieved by adiabat-shaping at lower power. These results taken collectively bridge the space between the higher compression low-foot results and the higher yield high-foot results.

Published

2016

50. Hydrodynamic growth and mix experiments at National Ignition Facility

Author

Otto Landen, J. Edwards, Robert Tipton, J. Pino, M. Mintz, J. D. Kilkenny, V. A. Smalyuk, J. P. Knauer, D. Rowley, C. B. Yeamans, W. W. Hsing, Kumar Raman, Daniel S. Clark, T. G. Parham, Gary Grim, S. V. Weber, John Kline, Abbas Nikroo, James McNaney, Daniel Casey, B. A. Hammel, J. A. Caggiano, Bruce Remington, Harry Robey, A. V. Hamza, H.-S. Park, Omar Hurricane, C. J. Cerjan, and S. W. Haan

Subjects

Tritium illumination, History, Yield (engineering), Materials science, Nuclear engineering, Implosion, 01 natural sciences, Instability, 010305 fluids & plasmas, Computer Science Applications, Education, Nuclear physics, Acceleration, Physics::Plasma Physics, 0103 physical sciences, Surface roughness, Nuclear fusion, 010306 general physics, National Ignition Facility

Abstract

Hydrodynamic growth and its effects on implosion performance and mix were studied at the National Ignition Facility (NIF). Spherical shells with pre-imposed 2D modulations were used to measure Rayleigh-Taylor (RT) instability growth in the acceleration phase of implosions using in-flight x-ray radiography. In addition, implosion performance and mix have been studied at peak compression using plastic shells filled with tritium gas and imbedding localized CD diagnostic layer in various locations in the ablator. Neutron yield and ion temperature of the DT fusion reactions were used as a measure of shell-gas mix, while neutron yield of the TT fusion reaction was used as a measure of implosion performance. The results have indicated that the low-mode hydrodynamic instabilities due to surface roughness were the primary culprits to yield degradation, with atomic ablator-gas mix playing a secondary role.

Published

2016